WO2003106676A1 - Probes for identifying microorganism and identification method using the same - Google Patents

Abstract

It is intended to provide specific probes for detecting and identifying a microorganism and a detection and/or identification method using the same. Probes for detecting and identifying one or more microorganisms which are harmful in the fields of medicines, foods, etc. such as Actinobacillus actinomycetemcomitans, Acinetobacter calcoaceticus or Haemophilus influenzae, comprising 20 to 100 bp base sequence(s) in the V1, V2 and/or V3 regions of the 16S rRNA of the microorganism to be identified or a complementary sequence thereof. A method of detecting and/or identifying a microorganism with the use of one or more probes as described above.

Description

 Description Microbe identification probe and identification method using the same

 The present invention relates to a specific probe for detecting and identifying microorganisms, particularly harmful bacteria in the fields of medicine and food, and a method for detecting and / or detecting the same using the same. Background art

The detection of bacteria described in Table 1 is important for various medical and public health purposes, and the following two methods are known for detection.

Microorganism Microorganism name Microorganism number

ID

 01 Actinobacillus actinomycetemcomitans ATCC 29522

02 Acinetobacter calcoaceticus ATCC 23055

03 Haemophilus influenzae ATCC 33391

04 Stenotrophomonas maltophilia ATCC 13637

05 Proteus mirabilis ATCC 29906

06 Streptococcus pneumoniae ATCC 33400

07 Pseudomonas aeruginosa ATCC 27853

08 Citrobacter freundii ATCC 8090

09 Veillonella parvula ATCC 10790

10 Providencia stuartii ATCC 49809

1 1 Neisseria gonorrhoeae ATCC 49226

12 Streptococcus agalactiae ATCC 13813

13 organella morganii ATCC 25830

14 Bacteroides fragilis ATCC 25285

15 Staphylococcus hominis ATCC 27844

16 Staphylococcus wameri ATCC 27836

17 Staphylococcus haemolyticus ATCC 29970

18 Enterobacter cloacae ATCC 13047

19 Enterobacter aerogenes ATCC 13048

20 Staphylococcus epidermidis ATCC 14990

21 Streptococcus constellatus ATCC 27823

22 Serratia marcescens ATCC 8100

23 Streptococcus anginosus ATCC 33397

24 Escherichia coli ATCC 1 1775

25 Klebsiella pneumoniae ATCC 13883

26 Enterococcus faecalis ATCC 19433

27 Enterococcus faecium ATCC 19434

28 Streptococcus sanguis ATCC 10556

29 Streptococcus mitis ATCC 49456

30 Streptococcus intermedius ATCC 27335

31 Listeria monocytogenes ATCC 15313

32 Clostridium perfringens ATCC 13124

33 Corynebacterium aquatium IFO 15710

34 Streptococcus oralis ATCC 35037

35 Staphylococcus aureus ATCC 12600

36 Neisseria meningitidis IID 854

37 Campylobacter fetus ATCC 27374

38 Enterococcus gallinarum ATCC 49573

39 Enterococcus casseliflavus ATCC 25788

40 Aeromonas hydrophila ATCC 7966

41 Salmonella paratyphi A ATCC 9281

42 Salmonella typhi ATCC 19430

43 Streptococcus equisimilis ATCC 35666

44 Streptococcus canis ATCC 43496

45 Klebsiella oxytoca ATCC 13182

46 Staphylococcus saprophyticus ATCC 15305

47 Pasteurella multocida ATCC 43137

48 Eikenella corrodens ATCC 23834

49 Streptococcus pyogenes ATCC 12344

50 Moraxella catarrhalis ATCC 25238 51 Legionella pneumophila ATCC 33152

52 Mycobacterium tuberculosis ATCC 27294

53 Mycobacterium avium ATCC 25291

54 Mycobacterium intracellulare ATCC 13950

55 Mycobacterium kansasii ATCC 12478

56 Mycobacterium gordonae ATCC 14470 The first method is to use blood agar medium, MacConkey medium (for a stool, SS agar medium, etc.), various confirmation mediums, diagnostics, etc. There is a method of identifying a microorganism using an immune serum for use. However, this method has a problem that the identification takes time.

 As a second method, a method called PCR (polymerase chain reaction), which can perform a rapid test, has been developed and put into practical use. In this PCR method, it is known to use a base sequence of 16S rRNA or 23S rRNA as a probe for identifying bacteria. Bacterial identification probes and identification methods using such ribosome base sequences are described, for example, in Japanese Patent No. 3116353, Japanese Patent No. 3135909, Japanese Patent No. 3030034, Japanese Patent Application No. 2002-17356, and Japanese Patent Application Laid-Open No. 2002-34578. No., etc.

 However, in these applications, the region of 400-500 bases from the 5 'end of the 16S rRNA molecule is an effective region to distinguish between closely related species of the phylogenetically conserved genus, Although it has been reported that a probe having a partial nucleotide sequence of those regions is prepared to detect and identify a specific microorganism, the 16S rRNA nucleotide sequence has low conservation between microorganisms, The VI, V2 and V3 regions having high specificity for a particular species are not individually specified, and a probe is prepared from the nucleotide sequence of the region to efficiently and specifically identify the microorganisms shown in Table 1 of the present invention. No method has been reported for detection and identification. Disclosure of the invention

Therefore, the present invention can quickly and reliably detect harmful microorganisms in the fields of medicine and food, based on the base sequences of the VI, V2 and V3 regions having high specificity for a specific species of 16S rRNA. Another object of the present invention is to provide a probe for detecting and / or identifying a microorganism and a detection and / or identification method using the probe. The present inventors have conducted intensive studies to solve the above problems, and as a result, focused on the base sequences of specific VI, V2 and V3 regions, which are particularly high in species, among 16S rRNA base sequences. However, they have found a probe that can specifically detect and / or identify harmful bacteria in the fields of medicine and food, and have completed the present invention.

 That is, the present invention provides the following 1 to 66.

(1) Actinobacillus actinomycetemcomitans, Actinobacillus actinomycetemcomitans, Acinetobacter calcoaceticus, Haemophilus influenza, Haemophilus ιηι 丄 uenzae, (Stenotrophomonas maltophilia) _s Proteus 'Mirabilis (Proteus mirabilis), Streptococcus' Pneumoniae

(Streptococcus pneumoniae), Pseudomonas aeruginosa, Citrobacterium freundii, Veillonella parvula, Providencia stuarti

(Providencia stuartii), Neisseria gonorrhoeae, Streptococcus agalactiae, Morganella morganii, Bacteros sufferos ) _N Staphylococcus warneri (Staphylococcus warneri), Staphylococcus haemolyticus (Staphylococcus haemolyticus), Enterococcus croca

(Enterobacter cloacae), Enterobacter aerogenes, Staphylococcus epidermidis, Streptococcus * Streptococcus constellatus, Sens. marcescens), Streptococcus anginosus, Escherichia coli

(Escherichia coli), Klebsiella pneumoniae, Enterococcus faecalis (Enterococcus faecalis) Enterococcus faeciura, Streptococcus sandeis

(Streptococcus sanguis), Streptococcus ice (Streptococcus mitis), Streptococcus intermedius, Squirrel Terrier, Listeria monocytogenes, Clostridium perfringens, Corynepacterium 'aquatium

(Corynebacterium aquatium) Streptococcus oralis, Staphylococcus aureus, Neisseria meningitidis, Capyronoctanae, Nanoha, Campylobacter fetus; Enterococcus gallinarumj, Enterococcus' caserifuranocus' (Enterococcus casselif lavus), Aeromonas' Nody drofira '(Aeromonas hydrophila), Sanoremonella' Noraffifi A (Salmonella paratyphi A), Sanoremonera phiphitostiphisti (Shiprepo typhisti strophy spell) equisimilis), Streptococcus canis, Streptococcus canis, Klebsiella oxytoca, Staphylococcus' Staphylococcus saprophyticus ^ Pasteurum munoletusida (Pasteu) rella multocida), Eikenella corrodens, Streptococcus pyogenes

(Streptococcus pyogenes), Mofuxef catarrhal (Moraxella catarrhal is), Legionella-pneumophila (Legionella pneumophila) Myconobacterium-Mycobacterium tuberculosis (Mycobacterium tuberculosis) _N.

(Mycobacterium avium), Mycobacterium intracellulare (Mycobacterium intracellulare, Mycobacterium kansasi i), Mycobacterium gordonae (Mycobacterium gordonae) A probe for detection or identification, 20 to within the VI, V2 and / or V3 region of the 16S rRNA of the microorganism to be detected and Z or identified: from each base sequence of! OObp or its complementary sequence Become a probe.

 (2) The probe according to (1), which is selected from the nucleotide sequences represented by SEQ ID NOs: 1 to 152 or a complementary sequence thereof.

 (3) A probe for detecting and / or identifying Actinobacillus actinomycetemcomitans comprising the nucleotide sequence shown in SEQ ID NO: 1, 2, or 3, or a complementary sequence thereof.

(4) including the nucleotide sequence shown in SEQ ID NO: 4, 5 or 6, or a complementary sequence thereof, Acinetobacta A probe for detecting and / or identifying Calcoaceticus.

(5) A probe for detecting and / or identifying Hemophilus influenzae, comprising the nucleotide sequence of SEQ ID NO: 7, 8 or 9, or a complementary sequence thereof.

 (6) A probe for detecting and / or identifying or identifying Stenotrophomonas maltophilia, comprising the nucleotide sequence shown in SEQ ID NO: 10, 11, or 12, or a complementary sequence thereof.

 (7) A probe comprising the nucleotide sequence of SEQ ID NO: 13, 14, or 15, or a complementary sequence thereof, for detecting and / or identifying Proteus mirabilis.

 (8) A probe for detecting and Z or identifying Streptococcus pneumoniae, comprising the nucleotide sequence shown in SEQ ID NO: 16, 17, or 18, or a complementary sequence thereof.

 (9) A probe for detecting and / or identifying Pseudomonas aeruginosa, comprising the nucleotide sequence shown in SEQ ID NO: 19, 20, or 21, or a complementary sequence thereof.

 (10) A probe for detecting and / or identifying Citrobacter frendi, comprising the nucleotide sequence shown in SEQ ID NO: 22, 23 or 24, or a complementary sequence thereof.

 (11) A probe comprising the base sequence shown in SEQ ID NO: 25, 26 or 27, or a complementary sequence thereof, for detecting, identifying, or identifying Bayonella parvula.

 (12) A probe for detecting, identifying, or identifying Providence's stuarty, comprising the nucleotide sequence shown in SEQ ID NO: 28, 29 or 30, or its complementary sequence.

 (13) A probe for detecting and / or identifying Neisseria gonorrhoeae, comprising the nucleotide sequence shown in SEQ ID NO: 31, 32 or 33, or a complementary sequence thereof.

 (14) A probe for detecting and / or identifying Streptococcus agaratache, comprising the nucleotide sequence shown in SEQ ID NO: 34, 35 or 36, or a complementary sequence thereof.

 (15) A probe comprising the nucleotide sequence of SEQ ID NO: 37, 38 or 39, or a complementary sequence thereof, for detecting, detecting, or identifying Morganella 'morganii.

 (16) A probe for detecting, detecting, or identifying Pacteroides fragilis, comprising the nucleotide sequence of SEQ ID NO: 40, 41 or 42, or a complementary sequence thereof.

(17) A probe for detecting, Z or identifying Staphylococcus hominis, comprising the nucleotide sequence shown in SEQ ID NO: 43, 44 or 45, or a complementary sequence thereof. (18) A probe comprising the nucleotide sequence of SEQ ID NO: 46, 47 or 48, or a complementary sequence thereof, for detecting, identifying, or identifying Staphylococcus perneri.

 (19) A probe comprising the nucleotide sequence of SEQ ID NO: 49, 50 or 51, or a complementary sequence thereof, for detecting and / or identifying or identifying Staphylococcus hemolyticus.

 (20) A probe comprising the nucleotide sequence of SEQ ID NO: 52, 23 or 53, or a complementary sequence thereof, for detecting and / or identifying Enterobacter.

 (21) A probe comprising the nucleotide sequence of SEQ ID NO: 54, 55, or 56, or a complement thereof, for detecting and / or identifying Enterobacter aerogenes.

 (22) A probe for detecting and / or identifying Staphylococcus epidermidis comprising the nucleotide sequence shown in SEQ ID NO: 57, 58 or 59, or a complementary sequence thereof.

(23) SEQ ID NO: 60, 61 or 62 nucleotide sequence shown in, or including a sequence complementary thereto, Streptococcus. Con Suterata scan detection and Roh or flop π- Bed for identifying ₀

 (24) A probe for detecting and / or identifying Serratia marcescens, comprising the nucleotide sequence shown in SEQ ID NO: 63, 23 or 64, or a complementary sequence thereof.

 (25) A probe for detecting, detecting, or identifying Streptococcus anginosus comprising the nucleotide sequence of SEQ ID NO: 65, 66, or 67, or a complementary sequence thereof.

 (26) A probe for detecting and / or identifying Escherichia coli, comprising the base sequence shown in SEQ ID NO: 68, 69 or 70, or a complementary sequence thereof.

 (27) A probe comprising the nucleotide sequence of SEQ ID NO: 54, 71 or 72, or a complementary sequence thereof, for detecting, detecting, or identifying Klebsiella pneumoniae.

 (28) A probe comprising the nucleotide sequence of SEQ ID NO: 73, 74, or 75, or a complementary sequence thereof, for detecting, identifying, or identifying Enterococcus faecalis.

 (29) A probe comprising the nucleotide sequence of SEQ ID NO: 76, 77, or 78, or a complementary sequence thereof, for detecting and / or identifying Enterococcus phenezim.

(30) Including the nucleotide sequence of SEQ ID NO: 79, 80 or 81, or the complementary sequence thereof A probe for detecting, identifying, or identifying Streptococcus sundaices.

(31) A probe comprising the nucleotide sequence of SEQ ID NO: 82, 83 or 18, or a complementary sequence thereof, for detecting and identifying or identifying Streptococcus mitosis.

 (32) A probe for detecting and / or identifying or identifying Streptococcus intermedius, comprising the nucleotide sequence of SEQ ID NO: 60, 84 or 67, or a complementary sequence thereof.

 (33) A probe for detecting and / or identifying Listeria monocytogenes, comprising the nucleotide sequence shown in SEQ ID NO: 85, 86 or 87, or a complementary sequence thereof.

 (34) A probe for detecting, detecting, or identifying Clostridium perfringens, comprising the nucleotide sequence of SEQ ID NO: 88, 89 or 90, or a complement thereof.

 (35) A probe for detecting, detecting, or identifying Corynepacteria aquatium, comprising the base sequence shown in SEQ ID NO: 91, 92 or 93, or a complementary sequence thereof.

 (36) A probe comprising the nucleotide sequence of SEQ ID NO: 94, 95, or 18, or a complementary sequence thereof, for detecting and Z or identifying Streptococcus' oralis.

 (37) A probe comprising the nucleotide sequence of SEQ ID NO: 96, 97 or 98, or a complementary sequence thereof, for detecting and / or identifying Staphylococcus aureus.

 (38) A probe for detecting, detecting, or identifying Neisseria meningitidis comprising the nucleotide sequence of SEQ ID NO: 99, 100 or 101, or a complementary sequence thereof.

 (39) A probe comprising the nucleotide sequence of SEQ ID NO: 102, 103 or 104, or a complementary sequence thereof, for detecting and / or identifying Campi pacter fetus.

 (40) A probe comprising the nucleotide sequence of SEQ ID NO: 105, 106 or 107, or a complementary sequence thereof, for detecting and / or identifying Enterococcus' galinalum.

 (41) A probe for detecting and / or identifying an Enterococcus.

(42) A probe for detecting and / or identifying Aeromonas' hydrofila, comprising the nucleotide sequence shown in SEQ ID NO: 110, 111 or 112, or a complementary sequence thereof. (43) A probe comprising the nucleotide sequence of SEQ ID NO: 113, 114 or 53, or a sequence complementary thereto, for detecting and Z or identifying or identifying Salmonella paratifi A.

 (44) A probe for detecting and / or identifying Salmonella typhi, comprising the nucleotide sequence of SEQ ID NO: 115, 114, or 53, or a complementary sequence thereof.

(45) a probe for detecting and Z or identifying Streptococcus ethicimiris, comprising the nucleotide sequence shown in SEQ ID NO: 116, 117 or 118, or a complementary sequence thereof; ₀

 (46) A probe comprising the nucleotide sequence of SEQ ID NO: 119, 120 or 121, or a complementary sequence thereof, for detecting and / or identifying S. caesus.

 (47) A probe comprising the nucleotide sequence of SEQ ID NO: 52, 23 or 122, or a complementary sequence thereof, for detecting and / or identifying Klebsiella oxytoca.

 (48) A probe comprising the nucleotide sequence of SEQ ID NO: 46, 123 or 124, or a sequence complementary thereto, for detecting and identifying or identifying Staphylococcus coccus saprofiticus.

 (49) A probe comprising the nucleotide sequence of SEQ ID NO: 125, 126, or 127, or a complementary sequence thereof, for detecting and / or identifying Pasteurella multocida.

 (50) A probe comprising the nucleotide sequence of SEQ ID NO: 128, 129 or 130, or a complementary sequence thereof, for detecting and / or identifying Eikenella corodense.

 (51) A probe for detecting and / or identifying Streptococcus pyogenes, comprising the nucleotide sequence shown in SEQ ID NO: 131, 132 or 133, or a complementary sequence thereof.

 (52) A probe for detecting and Z or identifying Moraxella catarrhalis, comprising the nucleotide sequence of SEQ ID NO: 134, 135 or 136, or a complementary sequence thereof.

 (53) A probe for detecting and / or identifying Legionella 'pneumophila, comprising a nucleotide sequence represented by SEQ ID NO: 137, 138 or 139, or a complementary sequence thereof.

 (54) A probe for detecting, detecting, or identifying Mycobacterium tuberculosis cis, comprising the nucleotide sequence of SEQ ID NO: 140, 141 or 142, or a complementary sequence thereof.

(55) a base sequence represented by SEQ ID NO: 143, 144 or 145, or a complementary sequence thereof; A probe for detecting and / or identifying mycobacterium avium.

(56) A probe for detecting and / or identifying Mycobacterium intracellulare, comprising the nucleotide sequence shown in SEQ ID NO: 146, 147 or 145, or a complementary sequence thereof.

 (57) A probe for detecting and / or identifying Mycobacterium kansasii, comprising the nucleotide sequence of SEQ ID NO: 148, 149 or 145, or a complementary sequence thereof.

 (58) A probe for detecting and / or identifying mycopacterium 'Gordone, comprising the nucleotide sequence of SEQ ID NO: 150, 151 or 152, or a complement thereof.

 (59) Identify the VI, V2, and V3 regions in each microorganism by homology search on the 16S rRNA nucleotide sequences of multiple microorganisms, and identify two or more types of nucleotide sequences in the VI, V2, and V3 regions. A method for designing a probe, comprising determining a mismatched site by comparing microorganisms, determining a region containing the mismatched site and having a base length of 20 to 100 bp.

(60) One or more of the probes according to (1) or (2) is used, characterized by the fact that Actinobacillus actinomycetemcomitans, Acinetopactor '' Norecoaceticus, Hemofuinoles infnolenza, Stenotrophomonas ma Norrethophilia, Proteus 'Miravillis, Streptococcus pneumoniae, Syudomonas enoleginosa, Citrobatata Frendi, Bayonela Pal Pula, Providencia Stuati, Neisseria Gonoloye, Streptogastroe', Streptogastroe's-Mora Fragiris, Staphylococcus hominis, Staphylococcus penorenelli, Staphylococcus. T. Aerogenes, Staphylococcus 'Epidide Midis, Streptococcus' Constellas, Serratia ma / Recessessen, Streptococcus anginosas, Jeselissia Cori, Klebsera eumonie, Enterococcus fjecoscus, Treptococcus sanguis, Streptococcus' Mateis, Streptococcus' Intermedius, Listeria 'Monocytogenes, Clostridium' Perfringens, Corynebacterium aquatium, Streptococcus' Olaris, Staphylococcus 'Apereus, Neisseria Meningitidis, Campylobacter' Fuetas, Enterococcus galinanolem, Enterococcus kaserifuranocus, Elomonas. , Krebsella ォ キ シ 力 ト ト 力 プ ロ カ ス パ ス ス タ ス タ ッ カ プ ロ キ シ パ ス, キ シ フ ク レ ク レ ク レ ス タ ス タ ク レ ク レ ク レ ク レ ク レ ク レ キ シ ク レ キ シ ク レ キ シ ク レ ク レ ク レ ク レ ク レ ク レ ク レChoose from Bacteria, Avime, Mycobacterium, Intracellulare, Mycobacterium kansasii, Mycobacterium gordone 1 or detected and Roh or identification method of a plurality of microorganisms are.

 (61) The method according to (60), which comprises hybridizing both sequences using stringency conditions that do not hybridize when there are four or more mismatches between the microorganism-derived nucleotide sequence and the probe nucleotide sequence. the method of.

 (62) 20 to within the V1, V2 and V3 regions of the 16S rRNA of the microorganism to be identified; base sequence having no more than 3 mismatches with the base sequence of the! OObp base sequence or its complementary sequence Detects two or more microorganisms having the following, and uses at least one probe having a base sequence of 20 to 100 bp in the V1, V2 and V3 regions of a microorganism different from the two or more microorganisms or a complementary sequence thereof. The method according to (60) or (61), further comprising identifying one microorganism among the two or more microorganisms.

 (63) The following steps: (a) a step of preparing a nucleic acid from a microorganism to be identified, (b) a step of hybridizing the nucleic acid with the probe according to claim 1 or 2, and (c) a step (b) )) Detecting the presence or absence of hybridization and identifying the detection signal pattern for each probe, (d) the detection signal pattern obtained in step (c), and the detection signal pattern of the microorganism specified in advance. (6) The method according to (6) or (61), comprising the step of: identifying the type of microorganism to be identified by comparing

 (64) The method according to any one of (60) to (63), wherein the primers shown in SEQ ID NOs: 153 and 154 are used to amplify nucleotides containing the target sequence and then hybridized with a probe.

(65) When amplifying nucleotides containing the target sequence, label them with a fluorescent substance. Performing the method according to any one of (60) to (64).

 (66) The method according to any one of (60) to (65), wherein the method is performed on a DNA chip. This description includes part or all of the contents as disclosed in the description and / or drawings of Japanese Patent Application No. 2002-174564, which is a priority document of the present application. BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is a diagram showing the VI, V2 and V3 regions in the base sequence of 16S rRNA of a microorganism. Description of Sequence Listing

 SEQ ID NO: 153 is synthetic DNA.

 SEQ ID NO: 154 is a synthetic DNA. BEST MODE FOR CARRYING OUT THE INVENTION

 The probe for detecting and identifying microorganisms of the present invention and the method for detection and / or identification using the same will be described in more detail.

 A first aspect of the present invention is a probe for detecting and / or identifying one or more microorganisms selected from the microorganisms shown in Table 1 above, wherein the probe comprises a microorganism to be detected and / or identified. It is a probe consisting of a base sequence of 20 to 100 bp in the VI, V2 and V3 regions of 16S rRNA or its complementary sequence.

 In the present invention, a probe is an oligonucleotide DNA or RNA capable of detecting a specific fragment from DNA or RNA fragments by utilizing the property that complementary sequences of nucleic acids specifically bind to each other. This is an oligonucleotide sequence that specifically binds to a target nucleic acid having a nucleotide sequence contained in 16S rRNA or 16S rDNA derived from a microorganism.

The probe capable of detecting and / or identifying each microorganism of the present invention is obtained by performing a multiple alignment between two or more microorganisms to be detected and identified in the VI, V2 and V3 regions of 16S rRNA of each microorganism, and In particular, the probe can be prepared by determining a region having high specificity for each microorganism (see FIG. 1). In this specification, the VI, V2, and V3 regions are the gene sequences of the 5 'region of 16S rRNA of each microorganism. (Approximately 500 bp), three conserved regions, the VI region is the region of the 50th to 120th base from the 5 'end, and the V2 region is the 150th to 260th base The V3 region is a region of the 420th to 520th bases.

 For the detection and identification probes that can be prepared from these V1 to V3 regions, it is appropriate to use a region with many mismatches between microorganisms to be detected and identified from the viewpoint of detection and identification sensitivity, and there are four or more mismatches. Is preferred. In consideration of the detection sensitivity, cost, and the like in the identification method, the base sequence of the probe is preferably 20 to 100 bp, particularly preferably 30 to 80 bp. Note that these probes are referred to as vl probe, v2 probe, and v3 probe according to each corresponding region.

 These probes may be partially modified, or may have deletions, substitutions, or additions in their nucleotide sequences, as long as the microorganisms shown in Table 1 can be specifically detected and identified. Specifically, the VI, V2, and V3 regions of each microorganism were identified by homology search in the 16S rRNA base sequence of the microorganisms described in Table 1, and two or more microorganisms were identified in the VI, V2, and V3 regions. To determine a mismatch site. Based on the result, a probe containing the mismatch site and having a base length of 20 to 100 bp is prepared. The mismatch site is preferably designed near the center of the probe. Among the microorganisms shown in Table 1, organisms with a minimum number of mismatches of 4 or more between the nucleotide sequence of the V1 to V3 region of the microorganism itself and the nucleotide sequence of vl to v3 probes derived from microorganisms other than the microorganism are: A microorganism that can be detected and identified by using a probe alone. Microorganisms with a minimum number of mismatches of 3 or less are microorganisms that can be detected and identified by comprehensively judging the results of detection using multiple probes.

Tables 2 and 3 show the IDs of the detection and identification probes for each microorganism and their sequence numbers.

 Table 3

Table 2 shows examples of probes that can identify microorganisms by themselves, and Table 3 shows examples of probes that can be identified in combination.

 For example, as can be seen from Table 2, the probes capable of specifically detecting and identifying actinobacillus actinomycetemcommitans alone include the 01v2 probe having the base sequence shown in SEQ ID NO: 2 and the probe having SEQ ID NO: 3 The 01 v3 probe having the nucleotide sequence shown, or a probe having the complementary sequence thereof, and capable of specifically detecting and identifying Acinetobacter p. Calcoaceticus alone has the nucleotide sequence shown in SEQ ID NO: 4. A 02v1 probe having the nucleotide sequence shown in SEQ ID NO: 5, a 02v3 probe having the nucleotide sequence shown in SEQ ID NO: 6, or a probe having a complementary sequence to each other.

 In addition, Table 3 shows microorganisms that are difficult to detect and identify using a single probe because the 16S rRNA gene sequence is similar to other microorganisms. In the case of these microorganisms, detection and identification of individual microorganisms can be performed using hybridization patterns of probes designed for the detection of other microorganisms as well as probes designed for the detection of the microorganism. Do. For example, as shown in Table 4, all of the probes 06 vl to v3 of SEQ ID NOs: 16 to 18 for detecting Streptococcus pneumoniae have the smallest mismatch between other microorganisms in the V1 to V3 region. Since the number is within 3 bases, it is difficult to detect and identify Streptococcus pneumoniae alone. Therefore, not only the probes 06 vl to v3 of SEQ ID Nos. 16 to 18, but also the probes 29 vl to v3 of SEQ ID Nos. 82, 83, and 18, and the probes 34 vl to v3 of the system numbers J, 94, 95, and 18, or Detection and identification are performed by combining and using the detection results of the probes having each complementary sequence.

 These probes may be of natural origin or may be obtained by a conventional method such as chemical synthesis.The chemical synthesis is performed by a phosphoramidite method using, for example, a DNA synthesizer of ABI (Applied Biosystem Inc.). Can be synthesized by Further, a known phosphate triester method, H-phosphonate method, phosphite method and the like can also be used.

A second aspect of the present invention is a method for detecting and / or identifying one or more microorganisms selected from the microorganisms shown in Table 1, wherein the method comprises the steps of: A method characterized by using one or more probes each having a base sequence of 20 to 100 bp or a complementary sequence thereof in the V2 and V3 regions.

 That is, specifically, the detection and identification method of the present invention performs hybridization by bringing the probe into contact with a specimen containing a microorganism or a nucleic acid derived therefrom, and using the label as an index, the microorganism of Table 1 is used as an indicator. It is a method of detection and identification.

 If the amount of nucleic acid is very small, the specimen containing the microorganism or nucleic acid derived therefrom can be amplified using primers capable of amplifying the base sequence containing the V1 to V3 region of the 16S rDNA of the microorganism shown in Table 1. Let it. A primer is a polynucleotide that acts as a starting point for the polynucleotide chain to elongate during a nucleic acid synthesis reaction.The forward primer in the present invention is preserved between microorganisms upstream of the VI region. It is preferable to design a region that is located at bases 1 to 70, which is a highly conserved region, and the reverse primer is a region that is highly conserved between microorganisms downstream of the V3 region, approximately 450 to 620. It is preferable to design from the region existing at the 塩 基 th base. In addition, the size is preferably 15 to 35 mer, particularly preferably 18 to 30 mer. For example, as an example, the foreprimer is located at about the 1st to 70th bases, the 27F primer shown in the following SEQ ID NO: 153, and the reverse primer is about the 450th to 620th bases. 525R shown in the following SEQ ID NO: 154 can be used. These primers may be of natural origin or chemically synthesized by a conventional method. The danigami synthesis can be synthesized, for example, by a phosphoramidite method using a DNA synthesizer manufactured by ABI (Applied Biosystem Inc.). It is also possible to use a known phosphate triester method, H-phosphonate method, phosphite method, or the like.

Forward primer 27F (system number 153): 5, agagtttgatcctggctcag 3 'Reverse primer 525R (system (J number 154): 5' gtattaccgcggctgctggcag 3 'An analyte containing a microorganism or a nucleic acid derived therefrom must be prepared as described below. Prepared by the above method and subjected to PCR amplification using the above primers, for example, by centrifugation separation from a sample, using a known method such as a lysing enzyme, a surfactant, or an alkali for microorganisms collected using a membrane filter. Nucleic acids are extracted using the treatment method described above. From the viewpoints of efficiency, purity, and operability, it is preferable to use a method in which a lytic enzyme is added. In the present invention, the nucleic acid includes RNA and DNA. In addition, in the present invention, PCR can be achieved if the nucleic acid is present in a number of molecules to several tens of minutes or more. Samples include, for example, stool, urine, blood, clinical test materials such as tissue homogenates, and food materials.

 Next, the extracted nucleic acid is made into type III, and a PCR method (Science 230, 1350 (1985)) is performed using the above primers. In the present invention, the above primers (SEQ ID NOs: 153 and 154) are used to amplify the 27th to 525th bases from the 5 'end of the base sequence of the 16S rDNA of the microorganism and the sequences in the vicinity thereof. Is preferred. Reaction conditions and reaction solutions for the PCR method can be arbitrarily set based on known information. For example, heat denaturation: 1 to 30 seconds at 90 to 95 ° C, annealing: 0 to 30 seconds at 37 to 65 ° C, extension reaction: 10 to 60 seconds at 50 to 75 ° C. Preferably, amplification is performed for 50 cycles. The results of PCR amplification can be used to confirm the presence and length of amplified nucleotides by subjecting the solution after the reaction to agarol gel electrophoresis as needed.

The amplified nucleic acid of the microorganism can be used for hybridization using the above-described probe of the present invention. In the present invention, hybridization means that, under specific conditions, two single-stranded nucleotide sequences having complementary sequences bind to each other to form a double strand. In addition, the specific condition means a stringent condition in hybridization, and in particular, in the present invention, four or more mismatches between a base sequence derived from a microorganism and a base sequence of a probe of the present invention. In some cases, this means conditions that do not hybridize. The stringency conditions vary depending on the hybridization conditions to be carried out, but those skilled in the art can use a solvent such as temperature, salt concentration, and activator concentration based on the hybridization protocol. Conditions such as composition can be appropriately set. As an example, hybridization with a 50-mer probe can be performed at 55 ° C., 0.5 × SSC, and 0.2% SDS. It should be noted that, depending on the purpose, it is possible to set the stringency to be higher so that the hybridization cannot be performed when the number of mismatches is 3 or more, 2 or more, or 1 or more. Also, lower stringency Thus, it is possible to set so that hybridization can be performed even when the number of mismatches is 5 or less, 6 or less.

 Whether hybridization is possible or not can be determined by extracting the amplified nucleic acid from the microorganism prepared as described above and labeling the amplified nucleic acid with a fluorescent substance such as fluorescein isothiocyanate / tetramethylrhodamine / isothiosinate / hapten, etc. After hybridization with the above-mentioned labeled nucleic acid, it can be confirmed by measuring a label such as a fluorescent dye. Labeling can be obtained by, for example, nick translation, a method using DNA polymerase, or nucleic acid amplification using a labeled primer whose 5 ′ end is labeled with a fluorescent substance or a hapten.

 The detection and identification method of the present invention includes a method of detecting and identifying a specific microorganism shown in Table 2 by using a single probe. For example, the minimum mismatch between the nucleotide sequence of the probe consisting of the nucleotide sequence of 20 to:! OObp or its complementary sequence in the VI to V3 region of the microorganism to be identified and the nucleotide sequence derived from microorganisms other than the microorganism. Microorganisms can be detected and identified by using the above-mentioned probe having a number of 4 or more (see Tables 2 and 4).

 The method of the present invention also includes a method of detecting and further identifying a specific microorganism shown in Table 3 by comprehensively judging the detection results obtained by the plurality of probes of the present invention. Specifically, as a first step, a mismatch with the base sequence of a probe consisting of a 20 to 100 bp base sequence or its complementary sequence in the V1, V2 and V3 regions of the 16S rRNA of the microorganism to be identified is 3 Two or more microorganisms having a base sequence of not more than two or more are detected, and as a second step, the base sequence of 20 to:! OObp in the V1, V2 and V3 regions of a microorganism different from the two or more microorganisms Alternatively, the method is to further identify one of the two or more microorganisms by using one or more probes having a complementary sequence thereof.

 For example, an example is shown in Table 61 (see Example 3). Since there are three or less mismatches between the 06 vl-v3 probe of ID 06 microorganism (Streptococcus pneumoniae) and the base sequence corresponding to ID 29 microorganism (Streptococcus' miteisu),

Microorganisms detected using the 06vl-v3 probe cannot be identified until either the ID06 microorganism or the ID29 microorganism. However, as a second step, ID 34 When the detection method is performed using a 34 vl to v3 probe derived from a microorganism (Streptococcus' Oralis), the ID06 microorganism hybridizes only with the 34 v3 probe and a signal is detected, and the ID29 microorganism is detected in 34 v2 and v3. The signal hybridizes with the probe and is detected. Therefore, the microorganisms detected using the 06vl-v3 probe can be further identified as ID06 microorganisms or ID29 microorganisms by performing detection using the 34vl-v3 probe derived from the ID34 microorganism (Streptococcus oralis). An organism can be identified.

 In the field of clinical and food hygiene, it is necessary to promptly confirm whether or not the microorganism to be detected may be present in the sample.If it is not necessary to identify the microorganism, If the plurality of microorganisms that can be detected simultaneously are closely related species, and the countermeasures such as a treatment method for the plurality of microorganisms are already clear, it is only necessary to perform the first step described above.

 In addition, the method of the present invention includes (a) a step of preparing a nucleic acid from a microorganism to be identified, (b) a step of hybridizing the nucleic acid with the probe of the present invention, and (c) the presence or absence of hybridization in the step (b). (D) identifying the detection signal pattern for each probe, (d) detecting the detection signal pattern obtained in step (c) and the detection signal pattern of the microorganisms specified in Table 1 specified in advance. A method comprising the step of identifying the type of microorganism to be identified by comparison is also included. In this case, by analyzing the detection signal pattern by computer processing or the like, the efficiency of detecting and identifying microorganisms can be further enhanced. The method using the detection signal pattern can be performed more quickly and effectively by performing the method on a DNA chip.

Specifically, the detection and identification method on the DNA chip can be performed as follows. The probe of the present invention is immobilized at each position (spot) on a support such as glass or silicon by a covalent bond or the like. When a solution containing the labeled nucleic acid obtained as described above is applied to the support, the base of the microorganism-derived nucleic acid in the sample having a base sequence complementary to the base sequence of the probe in each spot is obtained. The sequences hybridize to form a double strand and remain on the support. By measuring the label of the hybridized conjugate or the non-hybridized label Thus, microorganisms in the subject can be detected and identified. Example

 Hereinafter, the present invention will be described in detail with reference to Examples, but the present invention is not limited thereto.

 [Example 1] Preparation of microorganism identification probe and preparation of identification chip

 (Microorganism for probe preparation)

 To prepare the probes of the present invention, the microorganisms shown in Table 1 were used as standard strains. Microorganisms are distributed by the American Type Culture Collection (ATCC strain) and the Microorganisms Resource Division of the National Institute of Technology and Evaluation, National Institute of Technology and Evaluation (the Fermentation Research Institute (IF0)). (IF0), available from the Institute of Medical Science, The University of Tokyo (IID).

 (Determination of VI, V2, V3 regions of the 16S rDNA 5 'region gene sequence (about 500 bp) of the microorganism, determination of base sequences usable as probes, and preparation of probes)

The VI, V2, and V3 regions of the microorganisms shown in Table 1 were determined by performing multiple alignment (Hitachi Soft DNASIS Pro) on the base sequence obtained by decoding 16S rRNA using a sequencer (Applied Biosysteni). Furthermore, using a so-called plast algorithm (Hitachi Soft DNASIS Pro), mismatch sites were identified in those regions. The nucleotide sequence of the probe was designed such that the mismatch site was near the center. Table 4 shows the number of mismatched bases for the v1 to v3 probes designed for each microorganism, assuming that they hybridize with the sequences of the V1 to V3 regions of microorganisms other than the microorganism from which each probe was derived. Indicates the minimum value (minimum mismatch number). If the minimum number of mismatches in any of the v1 to v3 probes is 4 or more, the microorganism can be detected and identified by a single probe. In any of the vl to v3 probes, if the minimum number of mismatches is 3 or less, detection and identification cannot be performed by a single probe, but detection and identification can be performed by the method of the present invention as described later. In Table 4, none means that no sequence with significant homology was found. Table 4

(Preparation of DNA chip)

 Each vl v3 probe of the microorganisms shown in Table 1 was synthesized, purified by HPLC, and stored in a lyophilized state. These were adjusted to 20 μΜ and mixed 1: 1 with a microarray spotting solution (Genetics). All samples were spotted into 2X4 blocks by a spotter (Hitachi Software SPBI0), and a total of 4X4 blocks including replicas were made. Positive controls were spotted on the four ends of each block. The pin used in the spotter was a stainless steel pin 150 μπι. After spotting, the chip was placed in 0.2% SDS solution, water and boiling water, and the chip was washed with a slide washer (Piofield), and used in the following experiments.

 [Example 2] Microorganism identification method using microorganism identification probe

 (Preparation of microbial DNA extraction solution)

 The microorganisms shown in Table 1 were cultured on LB medium agar medium (5 g of yeast extract, 10 g of tryptone, 5 g of NaCl, 20 g of agar, 1 L of distilled water, pH 7.4) and then collected. Add 300μl of 1% Tween20 (Sigma), Cell Suspension Solution (Gentra Systems) solution containing 60Unit Lytic Enzyme (Gentra Systems; 600Unit Achromopeptidase (Wako Pure Chemical)) (Bacterial Enzyme Solution), suspend and add at 37 ° C. Next, 30 μl of a 600 mU / μ1 Proteinase K solution was added, and the mixture was heated at 70 ° C. for 10 minutes.

To this solution, 3301 of 5M guanidine hydrochloride-100 mM Tris-HCl solution (pH 8.0) was added and mixed for 10 minutes. Thereafter, 600 ^ 1 of TE-saturated phenol: cloth form solution (1: 1) was added and suspended, and then centrifuged at 15,000 rpm for 10 minutes at 25 ° C using a micro high-speed centrifuge. Take the upper layer for 600 minutes, and add 60μl of 3Μ sodium acetate (ρΗ6.0), 1800μl of Add 99.5% ethanol, mix and leave at -80 ° C for 10 minutes. Centrifuged at C. After rinsing with 70% cold ethanol, the precipitate was dried and dissolved sufficiently by adding 100 μl of sterilized distilled water. This solution was subjected to PCR.

 (Amplification of target DNA by PCR)

 PCR was performed using a GeneAmp9600 system (Roche diagnostics) in a reaction volume of 50 μl. Reaction solution 501 contains 11 type I DNA (microbial DM extraction solution), 5 μl 10X buffer (for Z-Taq), 0.75 units Z-Taq (Takara Shuzo), 6 nmole dNTPs Forward primer 27F (SEQ ID NO: 153) and reverse primer 525R (SEQ ID NO: 154), each containing 6 pmole.

 The PCR conditions were as follows: after 2 minutes at 98 ° C, 1 cycle at 98 ° C and 90 seconds at 60 ° C, one cycle was performed and 35 cycles were performed to obtain a PCR amplification product of the target gene in the microorganism. After completion of the reaction, the substrate was removed by spin column method using Sephadex ™ G50 Fine (Amersham pharmacia biotech), concentrated by lyophilization to dryness, and dissolved in sterile ultrapure water (の μΙ) to obtain a target DNA solution.

 (Labeling of PCR amplification products)

 The above target DNA was labeled with FluoroLink ™ Cy5-dUTP (Amersham pharmacia biotech) using Nick Translation Kit (Roche Diagnostics). In 20 μl of the labeling reaction solution, 1 g of the above target DNA solution, 3.5 / l Enzyme mixture, 0.04 mM dATP, 0.04 mM dCTP, 0.04 mM dGTP, 21 lOx buffer, 0. 1 mM

Includes FluoroLink ™ Cy 5 ~ dUTP. The reaction was performed at 15 ° C for 2 hours. After the reaction, purification was performed by a spin force ram method using Sephadex ™ G50 Fine (Amersham pharmacia biotech). The purified reaction was lyophilized and dissolved in 10 / zl sterile ultrapure water.

 (Hybridization)

 2 μl of the above-mentioned labeled target DNA was added, and the hybridization solution was adjusted so that the final concentrations were 50% formamide, 5% SSC, 2% SDS, and 1% BSA. 15 μl of this solution was denatured at 98 ° C for 2 minutes.

The solution was dropped on the microorganism identification chip prepared in Example 1, and placed on a 24 × 25 mm high precover slide (Bhem Kiki Co., Ltd.), and reacted in a 55 ° C constant temperature bath for 2 hours. After the reaction, the bacteria identification chip was immersed in a 2x ssc solution to slide down the hyperica slide. In addition, 2 x SSC, 0.2 ° /. After transferring to an SDS solution and washing for 5 minutes, the cells were washed with 0.2 × SSC and 0.2% SDS for 5 minutes. Further washing was performed with 0.5x SSC for 1 minute.

 After the microbial identification chip was centrifuged and dried at 2000 rpm for 1 minute, signals were detected using ScanArray 4000 (Packard BioChip Technologies, LLC) at room temperature and room temperature. In addition, in order to more clearly determine the signal intensity, the detected signal was digitized using a Hitachi Soft DNASIS (registered trademark) Array and used as a luminance value.

 Table 5 shows that the polynucleotide having the sequence containing the V1 to V3 region of the 16S rRNA of Actinobacillus actinomycetemcomitans of microorganism ID 01 is a vl probe of each microorganism prepared for the microorganism identification chip, v2 Probes and v3 probes were hybridized, and the top 10 probes with the highest signal brightness values were shown for each region. In Table 5, the probe ID is a combination of the microorganism ID number shown in Table 1 and the vl to v3 regions.

 For example, looking at the results of the VI region of 16S rRNA of Actinobactinoles actinomycetemcomitans, the brightness of Probe 01 vl is remarkably high. It is possible to detect the presence of Nomycetem commitans. However, in this case, since the probe 03 vl other than the probe 01 vl has a similar luminance value, it cannot be identified by using the probe 01 vl alone. This is because the base sequence of the probe 01vl has three or less mismatches with the base sequence derived from another microorganism, so that it can be compared with other microorganisms having a base sequence highly similar to a similar probe 01vl. This is because they will hybridize (see Table 1). Therefore, when it is necessary to identify in detail which microorganism is the microorganism detected by the probe 01 vl, an additional identification step needs to be performed.

 On the other hand, looking at the results of the 16S rRNA V2 region of Actinobacillus actinomycetemcomitans, the order of the brightness value of probe 01 v2 was remarkably higher than that of the other probes. It can detect and identify the presence of Actinobacillus' actinomycetemcomitans.

Looking at the results of the 16S rRNA V3 region of Actinobacillus .actinomycetemcomitans, the order of the brightness value of probe 01 v3 was significantly higher than that of other probes. Therefore, the presence of Actinobacillus' actino mycetemcomitans in a subject can be detected and identified using probe 01 v3.

 Comprehensively judging from the combination of the probes in the VI region, V2 region, and V3 region, the probes with relatively high signal intensity in the v1 probe are 03 vl and 01 vl, and the signal intensity in the v2 probe is relatively high. Since the probe is 01 v2 and the v3 probe has a relatively strong signal intensity of 01 v3, the target microorganism was Actinobacillus' actinomycetes, where strong signal intensity was detected in all regions. It can be detected and identified as cetemcomitance. Table 5

Probe ID area Emission signal intensity

 03 v1 V1 area 24292772

 01 vl V1 region 23806916

 05 v1 V1 region 6665238

 47 v1 V1 region 3385259

 24 v1 V1 region 2169069

 41 1 V1 area 2168 168

 42 vl V1 region 2021318

 13 v1 V1 region 1865555

 08 v1 V1 region 1833450

 36 v1 V1 region 1520337

 01 2 V2 area 24106717

 03 v2 V2 area 8121296

 08J 8—22—45 v2 V2 area 507673

 25 v2 V2 area 473566

 20 v2 V2 area 467841

 07 v2 V2 area 457081

 19 v2 V2 area 452294

 47 v2 V2 area 444574

 23 v2 V2 area 444368

 26 v2 V2 area 443 460

 01 v3 V3 area 44018306

 03 v3 V3 area 1563637

 53--54 v3 V3 area 1008301

 05 v3 V3 area 458131

 46 v3 V3 area 446885

 12 v3 V3 area 441418

 16 v3 V3 area 440355

 45 v3 V3 area 437947

 15 v3 V3 area 436469

26 v3 V3 area 433456 Table 6 shows the 16S rRNA of A. pactor. Calcoaceticus (microorganism ID 02).

The results of hybridizing a polynucleotide having a sequence containing the V1 to V3 regions with each probe on the chip are shown. From the results in Table 6, it is clear that acinetopactor 'calcoaceticas' can be detected and identified by using probes 02vl, 02v2, and 02v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 02 vl for vl probe, 02 v2 for v2 probe, and 02 v3 for v3 probe have relatively strong signal intensities. It can be detected and identified as Acinetobacter.

Table 6 Probe ID region Emission signal intensity

 02 v1 V1 area 13924050

 07 v1 V1 region 1862320

 20 v1 V1 region 1378305

 32 v1 V1 region 1327221

 13 v1 V1 area 1232256

 17 v1 V1 region 1 145747

 50 v1 V1 region 1 133 280

 35 v1 V1 area 1 1 15 164

 16--46 v1 V1 region 1091812

 22 v1 V1 region 1072129

 02 one v2 V2 area 14595023

 04-v2 V2 area 6953521

 07 v2 V2 region 5933146

 36 v2 V2 region 4666635

 40 v2 V2 region 3464230

 50 v2 V2 region 1883560

 05 v2 V2 region 1765482

 1 1 v2 V2 region 1536763

 10 v2 V2 region 545853

 08— 18— 22_45 v2 V2 area 321589

 02 v3 V3 region 17774582

 08 v3 V3 area 240 445

 05 v3 V3 area 2401 10

 19 v3 V3 area 232 178

 38 v3 V3 area 206877

 22 v3 V3 area 204959

 25 v3 V3 region 190615

 04 v3 V3 area 1 89167

 40 v3 V3 region 179787

07 v3 V3 area 176742 Table 7 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of the 16S rRNA of H. influenzae (microorganism ID 03) with each probe on the chip. From the results in Table 7, it is clear that Hemophilus'influenza can be detected and identified by using probes 03v2 and 03v3 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, 03 vl, 01 vl for the vl probe, 03 v2 for the v2 probe, and 03 v3 for the v3 probe have relatively strong signal strength. However, it can be detected and identified as Hemophilus' influenza, in which high intensity is detected in each region.

Table 7

Probe ID area Emission signal intensity

 03 v1 V1 region 2378623

 01 v1 V1 region 1906842

 47 v1 V1 area 1016080

 41 v1 V1 region 859149

 42 v1 V1 region 829649

 05 v1 V1 area 741202

 24 v1 V1 region 670298

 13 v1 V1 region 657089

 29 vl VI region 569133

 18--45 v1 V1 region 563785

 03 v2 V2 region 17021408

 01 v2 V2 region 1131659

 08-1-1 18--22-45 v2 V2 area 488 172

 23 v2 V2 region 467092

 04 v2 V2 area 456739

 49 v2 V2 region 450 377

 24 v2 V2 region 447638

 33 v2 V2 region 444928

 07 v2 V2 region 444421

 26 v2 V2 region 444 320

 03 v3 V3 area 34956972

 01 v3 V3 area 7686990

 53--54 v3 V3 region 992698

 33 v3 V3 area 930101

 25 v3 V3 area 851733

 50 v3 V3 region 58561 1

 47 v3 V3 area 565 322

 48 v3 V3 region 552483

 05 v3 V3 area 459296

37 v3 V3 region 458129 Table 8 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Stenotrophomonas maltophilia (microorganism ID 04) with each probe on the chip. From the results in Table 8, it is clear that Stenotrophomonas maltophila can be detected and identified by using probes 04 vl and 04 v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, the signal intensity of 04 vl for the vl probe, 04 v2, 02 v2 for the v2 probe, and 04 v3 for the v3 probe has relatively strong signal strength. However, it can be detected and identified as a Stenot-mouth Fomonas maltophylla in which high intensity was detected in each region.

Table 8

Probe ID area Emission signal intensity

 04 v1 V1 area 10553679

 36 v1 V1 region 466 306

 55 v1 V1 region 418442

 52 v1 V1 area 399038

 56 v1 V1 region 392406

 53 v1 V1 region 385 465

 11 v1 V1 region 350646

 39 v1 V1 area 345 370

 54 v1 V1 region 340987

 38 v1 V1 region 325 138

 04 v2 V2 area 10010827

 02 v2 V2 region 9289489

 07 v2 V2 region 1682837

 40 v2 V2 region 1168392

 36 v2 V2 region 1016436

 05 v2 V2 region 547876

 11 v2 V2 region 393560

 19 v2 V2 region 293886

 08J 8 1 22 1 45 v2 V2 area 286031

 24 v2 V2 region 276338

 04 v3 V3 region 17018787

 32 v3 V3 region 318622

 53-54 v3 V3 area 294 460

 05 v3 V3 area 273603

 36 v3 V3 area 156 275

 21 v3 V3 region 153557

 25 v3 V3 area 148719

 51 v3 V3 region 144 205

 48 v3 V3 region 143 748

28 v3 V3 region 142935 Table 9 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Proteus mirabilis (microorganism ID 05) with each probe on the chip. The results in Table 9, Proteus. Mirabilis is detected by a single use of the probe 05 _V 2, it is obvious that identification. Also, _V l, even if the overall judgment in combination _V 2, _V 3 probe, vl probe in 05 vl, 01 vl, v2 in Puropu 05 v2, v3 in probe 05 v3, 45 v3 is relatively Since it has a strong signal intensity, it can be detected and identified as Proteus mirabilis in which high intensity was detected in each region.

Table 9

Norono ID Light emission intensity

 05 v1 V1 region 20827926

 01 v1 V1 area 15475009

 13 vl V1 region 9362993

 10 v1 V1 area 7681042

 03 v1 V1 area 7004544

 22 v1 V1 region 3735229

 07 v1 V1 area 2610601

 24 v1 V1 region 2389560

 20 v1 V1 area 2128154

 47 v1 V1 area 1946520

 05 v2 V2 area 40877654

 04 v2 V2 area 4549427

 10 v2 V2 area 3936746

 02 v2 V2 area 2747031

 13 v2 V2 area 1756674

 25 v2 V2 area 1579401

 07 v2 V2 area 1459845

 11 v2 V2 area 1214739

 08_18— 22-45 v2 V2 area 1008826

 19 v2 V2 area 965000

 05 v3 V3 area `` 35771 120

 45 v3 V3 area 16469087

 25 v3 V3 area 4041990

 18—41 one 42 v3 V3 area 3949284

 24 v3 V3 area 1675672

 19 v3 V3 area 1537185

 13 v3 V3 area 1386238

 22 v3 V3 area 1287333

 09 v3 V3 area 902008

28 v3 V3 area 847886 Table 10 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Streptococcus pneumoniae (microorganism ID 06) with each probe on the chip. From the results in Table 10, Streptococcus pneumoniae could not be identified by using probes 06vl to 06v3 alone. However, judging comprehensively by the combination of the vl, v2, and v3 probes, 06 vl, 29 vl for the vl probe, 06 v2, 29 v2 for the v2 probe, and 06_29_34 v3 for the v3 probe have relatively strong signal strength. It can be detected and identified as Streptococcus pneumoniae, in which high intensity was detected in each region.

Table 10

Table 11 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Pseudomonas aeruginosa (microorganism ID 07) with each probe on the chip. From the results in Table 11, it is clear that Pseudomonas aeruginosa can be detected and identified by using probe 07 vl, 07 v2, and 07 v3 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, each signal has a relatively strong signal intensity of 07 vl for the vl probe, 07 v2 for the v2 probe, and 07 v3 for the v3 probe. It can be detected and identified as Pseudomonas aeruginosa with high intensity detected in the region.

Table 11

Probe ID area Emission signal intensity

 07 v1 V1 area 21582444

 35 v1 V1 region 1 140 158

 31 vl V1 region 1069940

 50 v1 V1 area 1047192

 15 v1 V1 area 1017726

 14 v1 V1 region 971673

 02 v1 V1 area 955063

 13 v1 V1 region 916576

 17 v1 V1 region 897631

 20 v1 V1 area 872552

 07 v2 V2 region 8962135

 36 v2 V2 region 2597328

 04 v2 V2 area 1886057

 29 v2 V2 area 1688042

 1 1 v2 V2 area 1565487

 24 v2 V2 area 1410365

 02 v2 V2 region 1 142371

 19 v2 V2 area 1000 455

 41.42 v2 V2 region 934199

 40 v2 V2 region 814738

 07 v3 V3 area 7269868

 40 v3 V3 area 784 278

 37 v3 V3 region 524732

 24 v3 V3 area 488 503

 13 v3 V3 region 469384

 32 v3 V3 area 438 322

 05 v3 V3 area 408 564

 45 v3 V3 region 40461 1

 31 3 V3 area 388594

06—29 one 34 v3 V3 area 387010 Table 12 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Citropactor 'Frendi (microorganism ID 08) with each probe on the chip. From the results in Table 12, it is clear that Citropactor'Frendi can be detected and identified by using Prop 08 v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 08 vl, 18-45 vl for vl probe, 41—42 v2, 08_18—22—45 v2, 24 v2, 19 v2 for v2 probe On the other hand, in the v3 probe, 08v3 has a relatively strong signal intensity, so that it is possible to detect and identify Citropobacter frendi in which high intensity was detected in each region.

Table 12

Probe ID area Emission signal intensity

 08 vl VI region 12042247

 18.45 v1 V1 region 8702122

 01 v1 V1 region 1482998

 52 v1 V1 region 1481 121

 04 v1 V1 area 1387682

 53 v1 V1 region 131 1987

 36 v1 V1 region 1234712

 42 v1 V1 region 1 180 221

 41 v1 V region 1 180 112

 56 v1 V1 region 1078698

 41 one 42 v2 V2 area 24978187

 08-18 18 22-45 v2 V2 area 20819098

 24 v2 V2 area 16861254

 19 v2 V2 region 12857791

 25 v2 V2 region 71 69 295

 1 1 2 V2 area 2316184

 40 v2 V2 region 1966698

 36 v2 V2 region 1305178

 10 v2 V2 region 1201810

 13 v2 V2 area 981693

 08 v3 V3 area 31353656

 19 v3 V3 region 10317886

 18—41—42 v3 V3 domain 8251997

 25 v3 V3 area 3888031

 10 v3 V3 area 2857964

 22 v3 V3 region 1232473

 45 v3 V3 region 970905

 53—54 v3 V3 region 905069

 02 v3 V3 region 859252

13 v3 V3 region 597583 Table 13 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Bayonella pulpula (microorganism ID 09) with each probe on the chip. From the results in Table 13, it is clear that Bayonela 'pulpula can be detected and identified by using the probes 09vl, 09v2, and 09v3 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, the vl probe has a relatively strong signal intensity of 09 vl, the v2 probe has 09 v2, and the v3 probe has 09 v3. It can be detected and identified as bayonela / pulpura with detected intensity.

Table 13

Probe ID area Emission signal intensity

 09 v1 V1 region 1 1262606

 39 v1 V1 region 1525696

 38 v1 V1 area 1386804

 31 v1 V1 region 1279271

 52 v1 V1 area 1273860

 36 v1 V1 region 1201348

 27 v1 V1 region 1 175722

 53 v1 V1 region 1 154955

 1 1 v1 V1 area 1154121

 50 v1 V1 area 1087600

 09 v2 V2 area 4576479

 36 v2 V2 area 1594541

 1 1 v2 V2 area 1457529

 07 v2 V2 area 1312259

 49 v2 V2 area 1052090

 41--42 v2 V2 area 1040564

 04 v2 V2 area 1024936

 24 v2 V2 area 101 1879

 40 v2 V2 area 998 230

 13 v2 V2 area 963780

 09 v3 V3 area 5145378

 53--54 v3 V3 area 841703

 32 v3 V3 area 770670

 1 1 3 V3 region 724 183

 06-29 1 34 v3 V3 area 701800

 52 1 55 v3 V3 area 692188

 31 v3 V3 area 691998

 22 v3 V3 area 683726

 37 v3 V3 area 679404

13 v3 V3 area 678675 Table 14 shows the results obtained by hybridizing a polynucleotide having a sequence containing the VI to V3 regions of 16S rRNA of Providence Stuarty (microorganism ID 10) with each probe on the chip. From the results in Table 14, it is clear that Providence's quality can be detected and identified by using probes 10 vl, 10 v2, and 10 v3 alone. In addition, even when comprehensively judged by the combination of the vl, v2, and v3 probes, each region has relatively strong signal intensity of 10 vl, 13_vl for the vl probe, 10 v2 for the v2 probe, and 10 v3 for the v3 probe. Can be detected and identified as a Providence / Stuarty with a high intensity detected.

Table 14

Probe ID area Emission signal intensity

 10 v1 V1 region 7987691

 13 v1 V1 region 5972673

 05 v1 V1 region 1 197313

 22 v1 V1 area 1076876

 07 v1 V1 region 986987

 19—25 v1 V1 region 907682

 20 v1 V1 area 829768

 04 v1 V1 region 788987

 40 v1 V1 area 787867

 01 v1 V1 area 781687

 10 v2 V2 region 14879362

 1 1 v2 V2 region 2737726

 40 v2 V2 region 2233598

 51 v2 V2 region 1483104

 08_18_22.45 v2 V2 area 947619

 19 v2 V2 region 879936

 25 v2 V2 area 877404

 36 v2 V2 region 839596

 41--42 v2 V2 region 693910

 02 v2 V2 area 693016

 10 v3 V3 area 25810166

 45 v3 V3 region 765859

 25 v3 V3 area 760872

 13 v3 V3 region 755829

 19 v3 V3 region 668770

 08 v3 V3 area 596139

 49 v3 V3 area 538412

 18—41—42 v3 V3 region 514935

 05 v3 V3 area 470843

26 v3 V3 area 464401 Table 15 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Neisseria gonorrhoeae (microorganism ID 11) with each probe on the chip. From the results in Table 15, it is clear that Neisseria gonorrhoeae can be detected and identified by using probe 11 v3 alone. Further, vl, _V 2, v3 even after comprehensive consideration a combination of probe, vl probe in 11 vl, 36 vl, v2 in probe 11 ν2, 36 v2, the v3 probe 11 v3 is relatively strong signal Because of the high intensity, it is possible to detect and identify Neisseria gonorrhoeae in which high intensity was detected in each region.

Table 15

Probe ID area Emission signal intensity

 1 1 v1 V1 region 26218769

 36 v1 V1 region 20106531

 04 v1 V1 region 1 148687

 17 v1 V1 region 1 123692

 56 v1 V1 region 795876

 53 v1 V1 region 709876

 54 v1 V1 area 658782

 52 v1 V1 region 647787

 53 v1 V1 region 638967

 18_45 v1 V1 region 629876

 11 v2 V2 region 30109876

 36 v2 V2 region 23409746

 40 v2 V2 region 3997698

 51 v2 V2 region 2598790

 10 v2 V2 area 1207098

 08—18—22—45 v2 V2 region 1027869

 07 v2 V2 area 1011769

 19 v2 V2 region 908763

 04 v2 V2 area 792340

 41_42 v2 V2 region 748769

 1 1 v3 V3 area 18694137

 36 v3 V3 region 884298

 07 v3 V3 area 390 902

 39 v3 V3 region 387087

 25 v3 V3 area 378093

 46 v3 V3 area 375906

 53--54 v3 V3 region 374803

 45 v3 V3 region 370866

 15 v3 V3 area 367255

13 v3 V3 area 365979 Table 16 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Streptococcus agaratache (microorganism ID 12) with each probe on the chip. From the results in Table 16, it is clear that Streptococcus agarakche can be detected and identified by using probes 12vl, 12v2, and 12v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 12 vl for the vl probe, 12 v2 for the v2 probe, and 12 v3 for the v3 probe have relatively high signal intensities, and are high in each region. It can be detected and identified as Streptococcus agalacti whose strength is detected.

Table 16

Probe ID area Emission signal intensity

 12 vl VI region 44947674

 06 v1 V1 region 3873241

 34 v1 V region 2703603

 29 v1 V1 region 2651862

 44 v1 V1 region 2623306

 43 v1 V1 region 2484804

 49 v1 V1 region 1889335

 28 v1 V1 region 1818534

 21-28 v1 V1 region 1810848

 01 1 V1 area 1490870

 12 v2 V2 area 30700769

 49 v2 V2 area 6918627

 19 v2 V2 area 3579 300

 06 v2 V2 area 3512292

 24 v2 V2 area 3464250

 29 v2 V2 area 3287064

 07 v2 V2 area 3106369

 25 v2 V2 area 3007513

 08J 8— 22— 45 v2 V2 area 2691057

 34 v2 V2 area 2579428

 12 v3 V3 area 53581492

 49 v3 V3 area 8548413

 43 v3 V3 area 6200222

 44 v3 V3 area 3240147

 27 v3 V3 area 2352093

 39 v3 V3 area 2291647

 38 v3 V3 area 2219299

 32 v3 V3 area 1785051

 21 v3 V3 area 1329525

06— 29_34 v3 V3 area 1211039 Table 17 shows the results of hybridization of a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Morganella morga (microorganism ID 13) with each probe on the chip. From the results in Table 17, it is clear that Morganella morganii can be detected and identified by using probes 13v2 and 13v3 alone. In addition, even when comprehensively judged by the combination of vl, v2, and v3 probes, since the vl probe has a relatively strong signal intensity of 13 vl, 10 vl, 13 v2 for the v2 probe, and 13 v3 for the v3 probe, It can be detected and identified as Morganella morganii, where high intensity was detected in the region.

Table 17

Probe ID area Emission signal intensity

 13 v1 V1 region 28976987

 10 vl V1 region 20876298

 05 v1 V1 area 5987986

 22 v1 V1 region 2376987

 07 v1 V1 region 1 187687

 20 v1 V1 region 1176876

 17 v1 V1 area 1089768

 35 v1 V1 region 997987

 14 v1 V1 region 949879

 16—46 v1 V1 region 893987

 13 v2 V2 area 20920924

 10 v2 V2 area 2053932

 25 v2 V2 area 1500 548

 19 v2 V2 region 1021487

 08.18_22_45 v2 V2 area 1001221

 41-42 v2 V2 area 902148

 36 v2 V2 area 803154

 04 v2 V2 area 728878

 1 1 v2 V2 area 700703

 24 v2 V2 area 699761

 13 v3 V3 area 14425456

 18.41.42 v3 V3 area 1 160989

 10 v3 V3 area 1 102065

 19 v3 V3 area 1092044

 53-54 v3 V3 area 856732

 05 v3 V3 area 823358

 45 v3 V3 area 470 306

 08 v3 V3 area 454786

 50 v3 V3 area 386009

52 one 55 v3 V3 area 370832 Table 18 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Bacteroides fragilis (microorganism ID 14) with each probe on the chip. From the results in Table 18, it is clear that Pacteroides fragilis can be detected and identified by using Prop 14 vl, 14 v2, and 14 v3 alone. In addition, even when comprehensively judged by the combination of vl, v2, and v3 probes, 14 vl for the vl probe, 14 v2 for the v2 probe, and 14 v3 for the v3 probe have relatively strong signal intensities. It can be detected and identified as Pacteroides fragilis in which high intensity was detected in the region.

Table 18 Probe ID region Emission signal intensity

 14 v1 V1 region 26790920

 47 v1 V1 area 1 18741 1

 05 v1 V1 region 527363

 36 v1 VI region 507633

 22 v1 V1 area 485571

 13 v1 V1 region 452603

 50 v1 V1 region 414464

 20 v1 V1 region 391619

 07 v1 V1 region 383929

 37 v1 V1 region 383808

 14 v2 V2 area 21293063

 25 v2 V2 area 629025

 19 v2 V2 region 606147

 07 v2 V2 region 360 263

 08—18— 22 1 45 v2 V2 region 289 452

 15 v2 V2 area 288 112

 54 v2 V2 region 282965

 16 v2 V2 region 281 543

 41—42 v2 V2 region 278321

 50 v2 V2 region 277973

 14 v3 V3 area 17838095

 37 v3 V3 area 301 773

 25 v3 V3 region 283 236

 16 v3 V3 region 279815

 51 v3 V3 region 275369

 18--41 one 42 v3 V3 area 268 313

 50 v3 V3 region 267447

 13 v3 V3 region 264208

 56 v3 V3 region 263492

08 v3 V3 region 263058 Table 19 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Staphylococcus' hominis (microorganism ID 15) with each probe on the chip. From the results in Table 19, it was found that Staphylococcus 'Hominis' probe 15v :! ~ 15 v3 alone could not be detected and identified, but when comprehensively judged by the combination of vl, v2, v3 probes, 16__46 vl, 15 vl, 17 vl for vl probe, 15 v2 for v2 probe, In the 16v2 and v3 probes, 15v3 and 16v3 had relatively high signal intensities, suggesting the presence of Staphylococcus 'hominis or Staphylococcus' perneri, in which high intensity was detected in each region. Table 19 Probe ID area Emission signal intensity

 16 one 46 v1 V1 area 9636297

 15 v1 V1 region 8688319

 17 v1 V1 region 7822648

 20 v1 V1 area 2690099

 35 v1 V1 region 756910

 53 v1 V1 region 499825

 02 v1 V1 area 451079

 07 v1 V1 region 412397

 32 v1 V1 area 395656

 13 v1 V1 region 377834

 15 v2 V2 region 8187686

 16 v2 V2 region 7896897

 35 v2 V2 region 1897098

 20 v2 V2 area 987973

 56 v2 V2 area 398768

 46 v2 ί area 298767

 02 v2 V2 area 208 768

 50 v2 V2 region 201767

 07 v2 V2 region 198769

 31 v2 V2 area 188678

 15 v3 V3 area 12898732

 16 v3 V3 region 1 1866243

 35 v3 V3 region 4776521

 20 v3 V3 area 886287

 46 v3 V3 region 517652

 17 v3 V3 region 418761

 04 v3 V3 area 239766

 32 v3 V3 region 221876

 36 v3 V3 region 198767

37 v3 V3 area 191852 Table 20 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Staphylococcus' Perneri (microorganism ID 16) with each probe on the chip. From the results in Table 20, it was not possible to identify Staphylococcus coccus perneri by using probes 16 vl to 16 v3 alone.However, judging from the combination of the vl, v2, and v3 probes, the vl probe showed 16_46 The vl, 15 vl, 17 vl, and v2 probes have relatively high signal intensities at 16 v2, 35 v2, and v3 probes at 16 v3, 35 v3, and 15 v3, and high intensity was detected in each region. Detection and identification of Perneri were possible.

Table 20

Table 21 shows the results of hybridization of a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Staphylococcus' hemolyticus (microorganism ID 17) with each probe on the chip. From the results in Table 21, Staphylococcus hemoriticus could not be identified by using probes 17 vl to 17 v3 alone, but when comprehensively judged by the combination of vl, v2, and v3 probes, 17 vl, 15 vl, 16_46 vl, 17 v2, 15 v2 for the v2 probe, and 17 v3 and 20 v3 for the v3 probe have relatively high signal intensities, so that high intensity was detected in each region. Was detected and identified.

Table 21

Probe ID area Emission signal intensity

 17 v1 V1 region 9140975

 15 v1 V1 region 9067760

 16_46 v1 V1 area 6804271

 20 v1 V1 region 1905673

 50 v1 V1 area 1064254

 02 v1 V1 area 995094

 35 v1 V1 region 854346

 31 v1 V1 region 835559

 13 v1 V1 region 807708

 07 v1 V1 region 713656

 17 v2 V2 region 2983744

 15 v2 V2 region 2442856

 35 v2 V2 area 857752

 46 v2 V2 region 820022

 20 v2 V2 region 536312

 16 v2 V2 region 337042

 03 v2 V2 region 289 615

 38.39 v2 V2 region 237405

 19 v2 V2 region 230 281

 04 v2 V2 area 225625

 17 v3 V3 region 4176321

 20 v3 V3 region 2798760

 15 v3 V3 region 1 197281

 46 v3 V3 region 1 119872

 35 v3 V3 area 1022122

 16 v3 V3 area 796758

 32 v3 V3 area 567851

 37 v3 V3 area 3961 12

 14 v3 V3 region 289868

22 v3 V3 region 217865 Table 22 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Enterobacter 'croaka (microorganism ID 18) with each probe on the chip. From the results in Table 22, it was not possible to identify Enterobacter croaka by using probes 18 vl, 18 v2, and 18 v3 alone.However, considering the combination of vl, v2, and v3 probes, vl 18_45 vl for the probe, 08_18_22_45 v2 for the v2 probe, and 18-41-42 v3 for the 41-42 v2, 24 v2, and v3 probes have relatively strong signal intensities. · It was detected and identified as one.

Table 22 Probe ID region Emission signal intensity

 18-45 v1 V1 area 24 178 609

 19—25 v1 V1 region 10966958

 08 v1 V1 region 3226628

 56 v1 V1 area 2249984

 55 v1 V1 region 1955213

 52 v1 V1 region 1825328

 53 v1 V1 region 1746709

 36 v1 V1 region 1714315

 01 v1 V1 region 1658325

 04 v1 V1 area 1634919

 08-18-1 22-45 v2 V2 area 34967588

 41 one 42 v2 V2 area 26612959

 24 v2 V2 area 22463213

 25 v2 V2 area 16145401

 19 v2 V2 area 16030188

 1 1 v2 V2 area 3678267

 40 v2 V2 area 2477658

 51 v2 V2 area 2156539

 36 v2 V2 area 2094885

 13 v2 V2 area 2021289

 18 1 41 1 42 v3 V3 area 58668243

 08 v3 V3 area 12496515

 05 v3 V3 area 5472813

 25 v3 V3 area 5283913

 13 v3 V3 area 3228907

 45 v3 V3 area 2914331

 24 v3 V3 area 2546582

 22 v3 V3 area 1839215

 53_54 v3 V3 area 1434928

19 v3 V3 area 1238023 Table 23 shows the results obtained by hybridizing a polynucleotide having a sequence containing the VI-V3 region of 16S rRNA of Enterobacter aerogenes (microorganism ID 19) with each probe on the chip. From the results in Table 23, it is clear that Enterobacter aerogenes can be detected and identified by using probe 19 v3 alone. In addition, even when comprehensively judged by the combination of vl, v2, and v3 probes, relatively strong signal intensity is obtained at 19_25 vl for vl probe, 19 v2 for v2 probe, 08_18_22_45 v2, and 19 v3 for v3 probe. Enterobacter p. Aerogenes, whose high intensity was detected in each region, can be detected and identified.

Table 23

Probe ID area Emission signal intensity

 19-1 25 v1 V1 region 28812260

 18--45 v1 V1 region 9383804

 05 v1 V1 region 2187459

 13 v1 V1 region 1854417

 22 v1 V1 region 1802189

 14 v1 V1 region 1390057

 07 v1 VI area 1316013

 20 v1 V1 region 1235029

 10 v1 V1 region 1210090

 32 v1 V1 region 1 158607

 19 v2 V2 area 38919738

 08-18-22-45 v2 V2 area 24987198

 25 v2 V2 area 13987281

 41-42 v2 V2 area 12981961

 24 v2 V2 area 1 1964021

 1 1 2 V2 area 1890122

 07 v2 V2 area 182541 1

 36 v2 V2 area 148761 1

 40 v2 V2 area 1298731

 13 v2 V2 area 1016732

 19 v3 V3 area 53121093

 08 v3 V3 area 10985176

 45 v3 V3 area 8292437

 25 v3 V3 area 2575095

 05 v3 V3 area 1383349

 13 v3 V3 area 1288969

 1 1 v3 V3 area 1268765

 22 v3 V3 area 1245965

 18 1 41 1 42 v3 V3 area 1200 845

10 v3 V3 area 1 152808 Table 24 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Staphylococcus' epidemidis (microorganism ID 20) with each probe on the chip. From the results in Table 24, Staphylococcus' epididermidis could not be identified by using probes 20 vl, 20 v2, and 20 v3 alone, but it was determined that the combination of the vl, v2, and v3 probes was comprehensive. , 20 vl, 15 vl for vl probe, 20 v2, 35 v2, 17 v2 for v2 probe, 20 v3, 46 v3, 17 v3, 16 v3, 15 v3 for v3 probe have relatively strong signal strength, It can be detected and identified as Staphylococcus 'Epidermidis' in which high intensity was detected in the region.

Table 24

Blown ID area Light emitting

 20 v1 V1 region 5564151

 15 v1 V1 region 4297641

 13 v1 V1 region 2298763

 50 v1 V1 region 227651 1

 17 v1 V1 region 219 261 1

 16—46 v1 V1 region 2017652

 14 v1 V1 region 2012 51 1

 31 v1 V1 region 1918761

 02 v1 V1 region 1876181

 32 v1 V1 area 1586519

 20 v2 V2 area 371 1401

 35 v2 V2 area 3544303

 17 v2 V2 area 2252854

 16 v2 V2 area 1447884

 46 v2 V2 area 1 188084

 15 v2 V2 area 1179760

 56 v2 V2 area 750663

 04 v2 V2 area 587370

 32 v2 V2 area 554422

 52 v2 V2 area 550 275

 20 v3 V3 area 8696647

 46 v3 V3 area 5234071

 17 v3 V3 area 5181402

 16 v3 V3 area 4043267

 15 v3 V3 area 3725666

 35 v3 V3 area 221 1902

 37 v3 V3 region 1747232

 32 v3 V3 area 1455263

 36 v3 V3 area 859988

14 v3 V3 area 759021 Table 25 shows the results obtained by hybridizing a polynucleotide having a sequence containing the 16S rRNA region of Streptococcus' consteratas (microorganism ID 21) with each probe on the chip. From the results in Table 25, it is clear that Streptococcus constellus can be detected and identified by using probe 21 v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 21_30 vl for vl probe, 30 v2, 21 v2 for v2 probe, and 21 v3 for v3 probe have relatively strong signal strength. It can be detected and identified as Streptococcus constellus where high intensity was detected in each region.

Table 25

Probe ID area Emission signal intensity

 21 30 v1 V1 region 13493205

 49 v1 V1 region 626462

 14 v1 V1 region 472249

 28 v1 V1 region 406692

 09 v1 V1 region 372127

 23 v1 V1 region 334462

 04 v1 VI Ti Good area 281259

3g _vl VI area 264440

 33 v1 V1 region 261432

 44 v1 V1 region 231 431

 30 v2 V2 area 40001310

 21 2 V2 region 37777213

 36 v2 V2 region 442244

 13 v2 V2 region 435 228

 04 v2 V2 region 434745

 25 v2 V2 region 405090

 1 1 2 V2 region 389678

 19 v2 V2 area 386999

 41-42 v2 V2 area 365 454

 23 v2 V2 region 362880

 21 3 V3 area 48491419

 06-29-34 34 v3 V3 area 16236812

 28 v3 V3 area 10188066

 23—30 v3 V3 region 1704489

 32 v3 V3 region 501471

 33 v3 V3 area 2551 13

 49 v3 V3 area 240367

 04 v3 V3 area 221273

 12 v3 V3 area 216686

44 v3 V3 area 215405 Table 26 shows the results of hybridization of a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Serratia marcescens (microorganism ID 22) with each probe on the chip. From the results in Table 26, it is clear that Serratia marcescens can be detected and identified by using probes 22vl and 22v3 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, the relative intensity of 22 vl for the vl probe, 08_18_22—45 v2 for the v2 probe, and 22 v3 for the v3 probe have relatively strong signal intensities. Serratia detected with high intensity in ''

Can be detected.

Table 26 Probe ID region Emission signal intensity

 22 v1 V1 area 2799986

 19_25 v1 V1 area 645042

 05 v1 V1 area 464262

 14 v1 V1 region 403849

 13 v1 V1 region 348639

 10 v1 V1 area 340 365

 08 v1 V1 region 334770

 56 v1 V1 region 329794

 07 v1 V1 region 319945

 20 v1 V1 region 301988

 08—18—22—45 v2 V2 area 8881924

 41-42 v2 V2 area 361 1 108

 19 v2 V2 region 3501442

 24 v2 V2 region 3388138

 25 v2 V2 area 1364269

 36 v2 V2 region 440534

 1 1 2 V2 area 437523

 10 v2 V2 region 351575

 07 v2 V2 region 333596

 13 v2 V2 area 330089

 22 v3 V3 region 4336423

 25 v3 V3 area 552973

 19 v3 V3 region 376449

 1 8—41 1 42 v3 V3 area 370767

 05 v3 V3 area 359246

 08 v3 V3 area 317135

 53-54 v3 V3 area 251 368

 40 v3 V3 region 241465

 02 v3 V3 area 183823

13 v3 V3 area 156441 Table 27 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of the 16S rRNA of Streptococcus' anginosus (microorganism ID 23) with each probe on the chip. From the results in Table 27, it is clear that Streptococcus angiosus can be detected and identified by using probes 23vl and 23v2 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, each region has a relatively strong signal intensity of 23 vl for the vl probe, 23 v2 for the v2 probe, and 23-30 v3 for the v3 probe. Can be detected and identified as Streptococcus anguinosa with high intensity.

Table 27

Probe ID area Emission signal intensity

 23 v1 V1 region 13621920

 21_30 v1 V1 area 1429074

 12 v1 V1 region 351954

 54 v1 V1 region 322529

 06 v1 V1 region 313548

 29 v1 V1 region 285 465

 56 v1 V1 area 279073

 52 v1 V1 region 277580

 55 v1 V1 area 270 510

 53 v1 V1 region 265961

 23 v2 V2 region 17801418

 08-18-18 22-45 v2 V2 region 939544

 41-42 v2 V2 area 853515

 19 v2 V2 region 767853

 36 V2 area 678990

 25 v2 V2 area 661394

 24 v2 V2 area 660099

 40 v2 V2 region 629656

 13 v2 V2 region 614760

 1 1 v2 V2 area 463405

 23—30 v3 V3 area 34042714

 06—29 one 34 v3 V3 area 2910169

 21 v3 V3 area 2028456

 28 v3 V3 region 1845357

 32 v3 V3 area 1 1 17 260

 25 v3 V3 region 522676

 37 v3 V3 area 364 237

 33 v3 V3 region 281 238

 09 v3 V3 area 274590

43 v3 V3 area 261961 Table 28 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Escherichia coli (microorganism ID 24) with each probe on the chip. From the results in Table 28, it is clear that Escherichia coli can be detected and identified by using probe 24v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 24 vl, 41 vl for vl probes, 08—18—22_45 v2, 24 v2, 41—42 v2, and v3 probes for v2 probes Since 24v3 has a relatively strong signal intensity, it can be detected and identified as Escherichia coli in which high intensity was detected in each region.

Table 28

Probe ID area Emission signal intensity

 24 v1 V1 region 17987542

 41 v1 V1 region 15887613

 42 v1 V1 region 4765198

 03 v1 V1 region 2191683

 01 v1 V1 region 1486217

 08 v1 V1 area 13291 1 1

 56 v1 V1 area 991762

 52 v1 V1 region 978628

 55 v1 V1 area 987780

 53 v1 V1 region 926 175

 08-- 18-- 22 1 45 v2 V2 area 982791 1

 24 v2 V2 area 9218763

 41-42 v2 V2 area 4907915

 19 v2 V2 area 3896124

 25 v2 V2 region 1778622

 1 1 v2 V2 area 598792

 36 v2 V2 area 597517

 10 v2 V2 area 527651

 13 v2 V2 area 486981

 40 v2 V2 area 479617

 24 v3 V3 area 4646334

 05 v3 V3 area 676154

 25 v3 V3 area 614952

 18 1 41 1 42 v3 V3 area 587 388

 53_54 v3 V3 area 506098

 07 v3 V3 area 475754

 32 v3 V3 area 435 473

 45 v3 V3 area 409346

 13 v3 V3 area 332258

19 v3 V3 area 276499 Table 29 shows the results of hybridization of a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Klebsiella 'pneumoniae (microorganism ID 25) with each probe on the chip. The results in Table 29, Kurepusera 'pneumoniae, the probe 25 vl, 25 v2, but could not identify the single use of _{25 v3, vl, v 2,} v3 probe of the comprehensively judged yarn且combined The Klebcella 'Nummonie, which has relatively high signal intensity in each region, has relatively strong signal intensity in the v_ probe, 19_25 vl, 18_45 vl, v2 probe, 25 v2, 19 v2, v3 probe, 25 v3, 45 v3. Can be detected and identified.

Table 29 Probe ID region Emission signal intensity

 19—25 v1 V1 region 44899827

 18--45 v1 V1 region 22296940

 13 v1 V1 area 5066743

 05 v1 V1 area 4572823

 22 v1 V1 region 3932829

 10 v1 V1 region 3095199

 14 v1 V1 area 28641 13

 07 v1 V1 region 2658302

 20 v1 V1 region 2612310

 32 v1 V1 region 2529941

 25 v2 V2 region 56236707

 19 v2 V2 region 52302190

 08-1 18_22--45 v2 V2 area 22930464

 41-42 v2 V2 area 20291404

 24 v2 V2 area 15891725

 07 v2 V2 region 3433724

 11 2 V2 region 3330589

 13 v2 V2 region 2995258

 40 v2 V2 region 2330892

 36 v2 V2 region 2213813

 25 v3 V3 area 4457641 1

 45 v3 V3 region 27662864

 19 v3 V3 region 13943196

 18_41_42 v3 V3 area 6416896

 05 v3 V3 area 6387121

 08 v3 V3 region 4853371

 24 v3 V3 region 2016 550

 10 v3 V3 area 1424743

 13 v3 V3 area 1402032

53--54 v3 V3 area 1042800 Table 30 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Enterococcus feucalis (microorganism ID 26) with each probe on the chip. From the results in Table 30, it is clear that Enterococcus feucharis can be detected and identified by using probes 26 vl, 26 v2, and 26 v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 26 vl for the vl probe, 26 v2 for the v2 probe, and 26 v3 for the v3 probe have relatively strong signal intensities. It can be detected and identified as Enterococcus faecalis with high intensity.

Table 30 Probe 1D region luminescence signal intensity

 26 v1 V1 region 6245244

 50 v1 V1 area 1519767

 31 v1 V1 region 997 402

 03 v1 V1 area 971075

 08 v1 V1 area 749485

 27 v1 V1 region 743405

 01 v1 V1 region 683398

 41 v1 V1 area 630838

 07 v1 V1 region 627885

 13 v1 V1 area 616087

 26 v2 V2 area 6899137

 41-42 v2 V2 area 575015

 08-- 18-- 22 1 45 v2 V2 area 494906

 19 v2 V2 region 492700

 24 v2 V2 area 427571

 36 v2 V2 area 415871

 40 v2 V2 region 410 203

 07 v2 V2 area 381812

 04 v2 V2 area 374505

 25 v2 V2 area 358563

 26 v3 V3 area 4672443

 31 v3 V3 region 439 560

 27 v3 V3 area 369990

 39 v3 V3 area 337964

 32 v3 V3 region 330311

 38 v3 V3 area 317024

 37 v3 V3 area 31 1826

 13 v3 V3 region 245796

 10 v3 V3 area 213954

12 v3 V3 area 187308 Table 31 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of the 16S rRNA of Enterococcus ′ fezium (microorganism ID 27) with each probe on the chip. From the results shown in Table 31, it is clear that Enterococcus faecium can be detected and identified by using probes 27vl and 27v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, relatively high signal intensity is obtained at 27 vl for the vl probe, 27 v2 for the v2 probe, 27 v3, and 39 v3 for the v3 probe. However, it can be detected and identified as Enterococcus faecium in which high intensity was detected in each region.

Table 31

Probe ID area Emission signal intensity

 27 v1 V1 region 9778728

 39 v1 V1 area 3061690

 56 v1 V1 region 2755188

 53 v1 V1 region 2721 149

 54 v1 V1 region 2565777

 38 v1 V1 region 2549340

 26 v1 V1 area 2330722

 52 v1 V1 region 2263885

 55 v1 V1 region 2049533

 09 v1 V1 region 969809

 27 v2 V2 area 9929701

 V2 area 1671 138

 38_39 v2 V2 area 331665

 26 v2 V2 region 312678

 07 v2 V2 region 278453

 16 v2 V2 region 260 282

 04 v2 V2 area 239858

 15 v2 V2 area 238 161

 24 v2 V2 region 235895

 19 v2 V2 region 223883

 27 v3 V3 area 8639767

 39 v3 V3 area 7896327

 38 v3 V3 area 237 681 1

 31 v3 V3 area 1098762

 44 v3 V3 area 675861

 26 v3 V3 area 589761

 19 v3 V3 region 318761

 32 v3 V3 area 307681

 05 v3 V3 area 297987

08 v3 V3 area 278768 Table 32 shows the results of hybridization of a polynucleotide having a sequence containing the VI to V3 region of 16S rRNA of Streptococcus sundaices (microorganism ID 28) with each probe on the chip. From the results in Table 32, it is clear that Streptococcus sanguis can be detected and identified by using probes 28 vl and 28 v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 28 vl for the vl probe, 28 v2 for the v2 probe, 28 v3 for the v3 probe, 06—29—34 v3 force S Since it has a strong signal intensity, it can be detected and identified as Streptococcus' Sandice, in which high intensity was detected in each region.

Table 32 Probe ID region Emission signal intensity

 28 v1 V1 region 16338885

 06 v1 V1 region 1 181797

 29 v1 V1 region 730573

 21—30 v1 V1 region 483231

 34 vl V1 region 472055

 43 v1 V1 region 459749

 44 v1 V1 region 404 106

 12 v1 V1 region 381948

 49 v1 V1 region 376 569

 09 v1 V1 region 351832

 28 v2 V2 area 12909216

 24 v2 V2 area 503344

 36 v2 V2 area 499619

 41-42 v2 V2 area 431 345

 13 v2 V2 area 424502

 19 v2 V2 region 417881

 25 v2 V2 area 403362

 08_18.22_45 v2 V2 area 395035

 04 v2 V2 area 394017

 1 1 v2 V2 area 374090

 28 v3 V3 area 45542140

 06-29-34 v3 V3 area 351 14448

 21 3 V3 area 15435778

 23—30 v3 V3 area 1521965

 32 v3 V3 area 739219

 24 v3 V3 area 465434

 49 v3 V3 area 450 890

 43 v3 V3 area 427491

 44 v3 V3 area 396805

01 v3 V3 area 355158 Table 33 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Streptococcus ′ miteis (microorganism ID 29) with each probe on the chip. From the results in Table 33, Streptococcus' miteis could not be identified by using probes 29vl, 29v2, and 29v3 alone, but when comprehensively judged by the combination of vl, v2, and v3 probes, vl 29 vl, 28 vl for the probe, 29 v2, 06 v2 for the v2 probe, and 06—29—34 v3 and 28 v3 for the v3 probe have relatively strong signal intensities.Streptococcus in which high intensity was detected in each region Miteth can be detected and identified.

Table 33

Probe ID area Emission intensity

 29 v1 V1 region 38198721

 28 v1 V1 region 24682981

 06 v1 V1 area 5817621

 21-1 30 v1 V1 area 2119781

 34 v1 V1 region 1087983

 12 v1 V1 area 909878

 49 v1 V1 region 687 611

 44 v1 V1 area 576 586

 43 v1 V1 region 467651

 27 v1 V1 region 416581

 29 v2 V2 region 46472243

 06 v2 V2 region 24406385

 34 v2 V2 region 12962338

 08—18— 22— 45 v2 V2 area 902177

 12 v2 V2 region 866 635

 19 v2 V2 region 849684

 30 v2 V2 area 826972

 25 v2 V2 area 743509

 24 v2 V2 region 736106

 36 v2 V2 region 669629

 06— 29_34 v3 V3 area 43974721

 28 v3 V3 region 28728883

 21 v3 V3 area 11488 220

 23-1 30 v3 V3 area 3778464

 32 v3 V3 region 1193519

 47 v3 V3 area 600 238

 12 v3 V3 area 288689

 43 v3 V3 region 258797

 49 v3 V3 area 253604

08 v3 V3 region 237332 Table 34 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Streptococcus intermedius (microorganism ID 30) with each probe on the chip. From the results in Table 34, Streptococcus intermedius could not be identified by using probes 30 vl, 30 v2, and 30 v3 alone, but it was judged comprehensively by the combination of vl, v2, and v3 probes. , 21--30 vl for vl probe, 30 v2, 21 v2 for v2 probe, and 23_30 v3 for v3 probe have relatively strong signal intensities, so Streptococcus' intermedius with high intensity detected in each region And can be identified.

Table 34

Probe ID area Emission signal intensity

 21-1 30 v1 V1 area 1744391 1

 23 v1 V1 region 430 260

 06 v1 V1 region 417406

 09 v1 V1 area 41 1 180

 28 v1 V1 region 357081

 29 v1 V1 region 333449

 43 v1 V1 region 321 388

 49 v1 V1 area 295344

 44 v1 V1 region 290 890

 39 v1 V1 region 270773

 30 v2 V2 area 28660345

 21 v2 V2 area 26065824

 36 v2 V2 area 564 178

 24 v2 V2 area 552656

 25 v2 V2 area 542309

 19 v2 V2 area 525 497

 08-18-18-22-45 v2 V2 area 510266

 04 v2 V2 area 509800

 41-42 v2 V2 area 498506

 49 v2 V2 area 473932

 23-30 v3 V3 area 26887538

 06--29--34 v3 V3 area 4386868

 21 v3 V3 area 2120637

 28 v3 V3 area 209741 1

 32 v3 V3 area 663634

 25 v3 V3 area 630821

 37 v3 V3 area 296965

 43 v3 V3 area 243304

 49 v3 V3 area 233886

27 v3 V3 area 193883 Table 35 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Listeria monocytogenes (microorganism ID 31) with each probe on the chip. From the results in Table 35, it is clear that Listeria monocytogenes can be detected and identified by using probes 31 vl, 31 v2, and 31 v3 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, 31 vl for the vl probe, 31 v2 for the v2 probe, and 31 v3 for the v3 probe have relatively strong signal intensities. It can be detected and identified as Listeria monositegenes with high intensity.

Table 35 Probe ID region Emission signal intensity

 31 v1 V1 area 10579601

 50 v1 V1 region 2532393

 55 v1 V1 area 984441

 56 v1 V1 region 891055

 53 v1 V1 area 853211

 52 v1 V1 region 828 320

 02 v1 V1 region 776127

 01 v1 V1 region 726 470

 13 v1 V1 area 719011

 07 v1 V1 region 691938

 31 v2 V2 area 10336138

 06 v2 V2 area 6911 13

 52 v2 V2 area 31 1987

 56 v2 V2 area 280 315

 55 v2 V2 area 269 230

 24 v2 V2 area 254 150

 14 v2 V2 area 251251

 51 v2 V2 area 250 609

 28 v2 V2 area 247383

 49 v2 V2 area 243528

 31 v3 V3 area 7713541

 27 v3 V3 area 807508

 39 v3 V3 area 606205

 38 v3 V3 area 519822

 32 v3 V3 area 367659

 37 v3 V3 area 338211

 26 v3 V3 area 275414

 53--54 v3 V3 area 249554

 46 v3 V3 area 248050

15 v3 V3 area 245416 Table 36 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Clostridium perfringens (microorganism ID 32) with each probe on the chip. From the results in Table 36, it is clear that Clostridium perfringens can be detected and identified by using the probes 32 vl, 32 v2, and 32 v3 alone. In addition, even when comprehensively judged by the combination of vl, v2, and v3 probes, 32 vl for vl probe, 32 v2 for v2 probe, and 32 v3 for v3 probe have relatively strong signal intensities, and are high in each region. It can be detected and identified as a crossstream with a detected intensity. Perfringens.

Table 36

Probe ID area Emission signal intensity

 32 v1 V1 area 13777878

 02 v1 V1 area 6313849

 50 v1 V1 region 4552246

 07 v1 V1 area 3595672

 13 v1 V1 area 3360097

 20 v1 V1 region 2960479

 17 v1 V1 region 2794853

 16 one 46 v1 V1 area 2575870

 15 v1 V1 region 2569927

 22 v1 V1 region 2336865

 32 v2 V2 area 19353147

 13 v2 V2 area 816957

 41-42 v2 V2 area 757723

 25 v2 V2 area 716 127

 08-18-18-22-45 v2 V2 area 690633

 24 v2 V2 area 644953

 19 v2 V2 region 635561

 35 v2 V2 area 585 284

 03 v2 V2 area 531673

 26 v2 V2 area 525063

 32 v3 V3 area 16219819

 35 v3 V3 area 650373

 37 v3 V3 area 565 610

18_41— 42 v3 V3 ^areaΊ 500 354

 16 v3 V3 area 497630

 05 v3 V3 area 496913

 15 v3 V3 area 496064

 08 v3 V3 area 487976

 17 v3 V3 area 484020

20 v3 V3 area 476998 Table 37 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Corynebacterium aquatium (microorganism ID 33) with each probe on the chip. From the results in Table 37, it is clear that Corynepacteria bacterium can be detected and identified by using probes 33 vl, 33 v2, and 33 v3 alone. In addition, even when comprehensively determined by the combination of vl, v2, and v3 probes, 33 vl for the vl probe, 33 v2 for the v2 probe, and 33 v3 for the v3 probe have relatively strong signal intensities. Corynebacterium / aquatium with high intensity can be detected and identified.

Table 37 Probe ID area Emission signal intensity

 33 v1 V1 region 28909022

 09 v1 V1 region 2068941

 56 v1 V1 area 1810656

 54 v1 V1 area 1617630

 27 v1 V1 region 1480859

 55 v1 V1 region 1439777

 50 v1 V1 region 1409621

 26 v1 V1 region 1387770

 53 v1 VI region 1291271

 39 v1 V1 region 1 138148

 33 v2 V2 region 25700462

 24 v2 V2 region 457898

 49 v2 V2 area 456921

 54 v2 V2 area 428638

 01 v2 V2 area 41 1464

 36 v2 V2 region 400441

 04 v2 V2 area 393 293

 53 v2 V2 region 390 216

 17 v2 V2 area 384017

 51 v2 V2 region 382889

 33 v3 V3 region 28292530

 53_54 v3 V3 area 5160490

 36 v3 V3 area 674367

 09 v3 V3 region 446040

 14 v3 V3 region 412684

 12 v3 V3 region 404894

 1 1 v3 V3 area 400 830

 45 v3 V3 area 400482

 51 v3 V3 area 395 914

37 v3 V3 area 386918 Table 38 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of the 16S rRNA of Streptococcus oralis (microorganism ID 34) with each probe on the chip. From the results in Table 38, it is clear that Streptococcus oralis can be detected and identified by using probe 34 vl alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, relatively strong signals of 34 vl for vl probe, 34 v2, 29 v2 for v2 probe, and 06_29—34 v3, 28 v3 for v3 probe Because of its strength, it can be detected and identified as Streptococcus oralis with high intensity detected in each region.

Table 38

Table 39 shows the results of hybridization of a polynucleotide having a sequence containing the VI to V3 region of 16S rRNA of Staphylococcus aureus (microorganism ID 35) with each probe on the chip. From the results in Table 39, it is clear that Staphylococcus aureus can be detected and identified by using probe 35 vl alone. In addition, even when comprehensively judged by the combination of vl, v2, and v3 probes, 35 vl for the vl probe, 35 v2, 20 v2 for the v2 probe, 35 v3, and 16 v3 for the v3 probe have relatively strong signal intensities. Therefore, it can be detected and identified as Staphylococcus aureus in which high intensity was detected in each region.

Table 39 Probe ID region Emission signal intensity

 35 v1 V1 region 2697296

 13 v1 V1 area 474763

 20 v1 V1 region 454987

 10 v1 V1 region 428401

 17 v1 V1 region 426633

 15 v1 V1 region 413146

 16.46 v1 V1 area 405001

 32 v1 V1 region 404788

 07 v1 V1 area 401 440

 31 v1 V1 area 399650

 35 v2 V2 area 7879871

 20 v2 V2 area 5687671

 46 v2 V2 region 387611

 17 v2 V2 region 381876

 15 v2 V2 region 381541

 16 v2 V2 region 378876

 38--39 v2 V2 region 326987

 19 v2 V2 region 329887

 49 v2 V2 region 318761

 34 v2 V2 region 309919

 35 v3 V3 area 19330782

 16 v3 V3 area 14291750

 15 v3 V3 area 5158030

 17 v3 V3 region 2649605

 20 v3 V3 area 2643488

 46 v3 V3 region 2466902

 04 v3 V3 area 519443

 37 v3 V3 region 457426

 32 v3 V3 region 445579

24 v3 V3 region 419666 Table 40 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Neisseria meningitidis (microorganism ID 36) with each probe on the chip. From the results in Table 40, it is clear that Neisseria meningitidis can be detected and identified by using probe 36v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 36 vl, 11 vl for vl probe, 36 v2, 11 v2 for v2 probe, and 36 v3 for v3 probe have relatively strong signal strength. Therefore, Neisseria meningitidis can be detected and identified as having high intensity detected in each region.

Table 40 Probe ID region Emission signal intensity

 36 v1 V1 area 32 691 1 13

 1 1 vl VI region 17218976

 04 v1 V1 area 47651 1 1

 50 vl VI region 2786176

 08 v1 V1 region 1567121

 09 v1 V1 region 1387629

 52 v1 V1 region 1018762

 53 v1 V1 region 908761

 54 v1 V1 area 892 145

 56 v1 V1 region 882165

 36 v2 V2 area 35287615

 1 1 v2 V2 area 188761 1 1

 07 v2 V2 area 5876819

 04 v2 V2 area 48761 12

 40 v2 V2 area 308761 1

 02 v2 V2 area 2898798

 24 v2 V2 area 2787687

 41_42 v2 V2 area 2287657

 08-18 18 22-45 v2 V2 area 2098791

 19 v2 V2 area 200761 1

 36 v3 V3 area 24445975

 1 1 3 V3 area 1785303

 49 v3 V3 area 685013

 38 v3 V3 area 640 621

 53--54 v3 V3 area 615 719

 04 v3 V3 area 567466

 48 v3 V3 area 470694

 33 v3 V3 area 420 137

 28 v3 V3 area 272902

52--55 v3 V3 area 270469 Table 41 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Campylobacter 1 ′ fuetas (microorganism ID 37) with each probe on the chip. From the results in Table 41, it is clear that Campylobacter huetas can be detected and identified by using probes 37 vl, 37 v2, and 37 v3 alone. In addition, even when comprehensively judged by the combination of the vl, v2, and v3 probes, each of the 37 vl for the vl probe, 37 v2 for the v2 probe, and 37 v3 for the v3 probe have relatively strong signal strength. It can be detected and identified as Campylobacter phytas, where high intensity was detected in the region.

Table 41 Probe ID region Emission signal intensity

 37 v1 V1 region 28176245

 50 v1 V1 region 6876182

 09 v1 V1 region 3876141

 39 v1 V1 region 3201876

 38 v1 V1 area 301641 1

 53 v1 V1 region 2787635

 55 v1 V1 area 2516252

 31 v1 V1 region 2387613

 27 v1 V1 region 2298713

 52 v1 V1 region 2017824

 37 v2 V2 area 38923509

 35 v2 V2 area 352 512

 16 v2 V2 area 341168

 15 v2 V2 area 333426

 03 v2 V2 area 330858

 26 v2 V2 area 326 179

 04 v2 V2 area 317611

 17 v2 V2 area 308803

 38-39 39 v2 V2 area 307 528

 05 v2 V2 area 306582

 37 v3 V3 area 32361007

 05 v3 V3 area 620 284

 33 v3 V3 area 556 400

 32 v3 V3 area 444124

 45 v3 V3 area 344770

 13 v3 V3 area 341006

 11 v3 V3 area 331067

 48 v3 V3 area 323257

 17 v3 V3 area 322958

35 v3 V3 area 319 217 Table 42 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Enterococcus' galinarum (microorganism ID 38) with each probe on the chip. From the results in Table 42, Enterococcus galinarum could not be identified by the single use of the probes 38 vl, 38 v2, and 38 v3.However, judging comprehensively by the combination of the vl, v2, and v3 probes, 38 38-39 v2 for vl, 39 vl, and v2 probes and 38 v3 and 39 v3 for v3 probes have relatively strong signal intensities, and high intensity was detected in each region. Enterococcus gallinarum or Enterococcus kaseriflavas Was detectable.

Table 42

Probe ID area Emission signal intensity

 38 v1 V1 area 6517750

 39 v1 V1 region 4901402

 27 v1 V1 area 789749

 55 v1 V1 area 676041

 53 v1 V1 area 672 402

 56 v1 V1 region 668186

 52 v1 V1 region 665378

 54 v1 V1 region 628 486

 50 v1 V1 region 586 201

 09 v1 V1 region 540023

 38_39 v2 V2 area 4946381

 27 v2 V2 area 324809

 46 v2 V2 area 283923

 04 v2 V2 area 266692

 07 v2 V2 area 243399

 26 v2 V2 area 237094

 36 v2 V2 area 225802

 35 v2 V2 area 220052

 24 v2 V2 area 199337

 16 v2 V2 area 198654

 38 v3 V3 area 2487517

 39 v3 V3 area 1886944

 27 v3 V3 area 678538

 31 v3 V3 area 491787

 28 v3 V3 area 348711

 06_29.34 v3 V3 area 298851

 32 v3 V3 area 281756

 37 v3 V3 area 278761

 26 v3 V3 area 215761

23_30 v3 V3 area 198725 Table 43 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Enterococcus ′ force seriflavas (microorganism ID 39) with each probe on the chip. From the results in Table 43, Enterococcus force seriflapas could not be identified by using probes 39 vl, 39 v2, and 39 v3 alone, but when comprehensively judged by the combination of vl, v2, and v3 probes, the vl probe 39 vl, 38 vl, 38_39 v2 for the v2 probe, and 39 v3, 38 v3, 27 v3 for the v3 probe have relatively strong signal intensities, so that high intensities were detected in each region.Enterococcus 'Casseriflavas or Enterococcus' The presence of Galinalum can be detected. Table 43

Probe ID area Emission signal intensity

 39 v1 V1 region 10173097

 38 v1 V1 region 9707541

 27 v1 V1 region 1919310

 26 v1 V1 area 1016063

 52 v1 V1 region 905910

 53 v1 V1 area 841171

 56 v1 V1 area 80 1008

 55 v1 V1 region 754869

 54 v1 V1 region 746 869

 09 v1 V1 region 729929

 38--39 v2 V2 area 10097683

 27 v2 V2 area 308179

 04 v2 V2 area 288 203

 33 v2 V2 area 253786

 07 v2 V2 area 243847

 36 v2 V2 area 232551

 28 v2 V2 area 225088

 06 v2 V2 area 222919

 14 v2 V2 area 222 342

 46 v2 V2 area 221837

 39 v3 V3 area 761 1583

 38 v3 V3 area 5728271

 27 v3 V3 area 2777612

 31 3 V3 area 61 1879

 28 v3 V3 area 528693

 44 v3 V3 area 329 722

 32 v3 V3 area 294821

 23-1 30 v3 V3 area 281 214

 37 v3 V3 area 277122

21 3 V3 area 223212 Table 44 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of the 16S rRNA of E. monas hydrophila (microorganism ID 40) with each probe on the chip. From the results in Table 44, it is clear that Aeromonas hydrophila can be detected and identified by using prop 40 vl, 40 v 2 and 40 v 3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 40 vl for the vl probe, 40 v2 for the v2 probe, and 40 v3 for the v3 probe have relatively strong signal strengths. It can be detected and identified as an Aeromonas' Hydrofila whose high intensity was detected in the region.

Table 44 Probe ID area Emission signal intensity

 40 v1 V1 region 8192676

 14 v1 V1 region 1257526

 13 v1 V1 area 1086045

 32 v1 V1 region 943819

 02 v1 V1 area 840592

 22 v1 VI region 715704

 10 v1 V1 region 707947

 07 v1 V1 region 696602

 50 v1 V1 area 615060

 36 v1 V1 region 560709

 40 v2 V2 area 204731 1 1

 1 1 v2 V2 area 5040956

 04 v2 V2 region 4658427

 36 v2 V2 region 3038991

 10 v2 V2 area 156 251 1

 51 Ml V2 region 1443971

 41--42 v2 V2 region 1240287

 25 v2 V2 region 1048912

 07 v2 V2 area 1011046

 19 v2 V2 region 921406

 40 v3 V3 region 17741881

 53--54 v3 V3 area 878575

 22 v3 V3 region 788368

 08 v3 V3 region 361891

 19 v3 V3 area 265936

 25 v3 V3 region 260828

 18—41—42 v3 V3 area 227853

 46 v3 V3 area 222 916

 07 v3 V3 region 220238

05 v3 V3 area 217679 Table 45 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of the 16S rRNA of Salmonella paratyphi A (microorganism ID 41) with each probe on the chip. From the results in Table 45, Salmonella paratyphi A could not be identified by using probes 41 vl, 41 v2, and 41 v3 alone, but when comprehensively determined by the combination of vl, v2, and v3 probes, vl For the probe, 41 vl, 42 vl, for the v2 probe, 41--42 v2, 08_18_22--45_v2, and for the v3 probe, 18_41_42 v3 has a relatively strong signal intensity.

The presence of A or Salmonella chifi was detectable.

Table 45

Probe ID area Emission signal intensity

 41 v1 V1 region 1 1027871

 42 v1 V1 area 999/321

 , hundred

 01 v1 V1 area 1698719

 56 v1 V1 region 1349871

 39 v1 V1 area 1321897

 55 v1 V1 region 1299873

 52 v1 V1 region 1288176

 03 v1 V1 region 1284125

 53 v1 V1 region 1187664

 41_42 v2 V2 area 14866236

 08-18 18 22-45 v2 V2 area 1 1 103694

 24 v2 V2 region 7643623

 19 v2 V2 region 6381 197

 25 v2 V2 region 4083972

 1 1 v2 V2 region 1708635

 36 v2 V2 region 1 151729

 40 v2 V2 region 987650

 13 v2 V2 area 861170

 07 v2 V2 area 8381 10

 18—41—42 v3 V3 area 44477558

 08 v3 V3 region 3883445

 25 v3 V3 area 2592177

 13 v3 V3 area 2196040

 05 v3 V3 region 2070933

 24 v3 V3 area 1238550

 45 v3 V3 region 1 144361

 22 v3 V3 area 1019021

 19 v3 V3 area 788897

10 v3 V3 area 687740 Table 46 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Salmonella 'Thifi (microorganism ID 42)' with each probe on the chip. From the results in Table 46, Salmonella typhi could not be identified by using probes 42 vl, 42 v2, and 42 v3 alone, but when comprehensively judged by the combination of vl, v2, and v3 probes, 41 For vl, 42 vl, and v2 probes, 41_42 v2, 08_18_22_45 v2, and v3 probe for 18_41--42 v3 have relatively strong signal intensities, so the presence of Salmonella typhi or Salmonella paratyphi A in which high intensity was detected in each region Was detectable.

Table 46

Probe ID area Emission signal intensity

 41 v1 V1 region 19765781

 42 v1 V1 region 18519837

 26 v1 V1 area 5918762

 24 v1 V1 region 4891983

 05 v1 V1 region 4151873

 56 v1 V1 region 3924512

 55 v1 V1 region 3518762

 52 v1 V1 region 3401 191

 53 v1 V1 region 2998712

 01 1 V1 region 2122987

 41_42 v2 V2 area 20917542

 08—18—22 1 45 v2 V2 area 16851388

 24 v2 V2 area 7913337

 1 9 v2 V2 area 5278967

 25 v2 V2 area 3466704

 1 1 v2 V2 area 2547883

 36 v2 V2 area 1767852

 40 v2 V2 area 1730755

 02 v2 V2 area 1500814

 07 v2 V2 area 1405621

 18 1 41 1 42 v3 V3 area 21554387

 05 v3 V3 area 4929756

 08 v3 V3 area 3710485

 25 v3 V3 area 3325205

 13 v3 V3 area 2317940

 45 v3 V3 area 1974662

 24 v3 V3 area 1796852

 19 v3 V3 area 1366178

 22 v3 V3 area 1361857

53--54 v3 V3 area 1049738 Table 47 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Streptococcus ′ ethisimilis (microorganism ID 43) with each probe on the chip. From the results in Table 4a, it is clear that Streptococcus ethicillus can be detected and identified by using probe 43v2 alone. Comprehensively judging from the combination of vl, v2, and v3 probes, 43 vl, 49 vl, 44 vl for vl probe, 43 v2 for v2 probe, 43 v3, 49 v3 for v3 probe have relatively strong signal strength. Therefore, Streptococcus equisimilis in which high intensity was detected in each region can be detected and identified.

Table 47

Probe ID area Emission signal intensity

 43 v1 VI region 17876978

 49 v1 V1 region 10987138

 44 v1 V1 region 7918732

 07 v1 V1 area 61 7 263

 21-30 v1 V1 region 601987

 28 v1 V1 region 578186

 06 v1 V1 region 558761

 12 v1 V1 area 497867

 09 vl VI region 481649

 29 v1 V1 region 463 278

 43 v2 V2 area 16515111

 44 v2 V2 area 1 1 14371

 24 v2 V2 region 552425

 25 v2 V2 region 528801

 19 v2 V2 area 4961 15

 36 v2 V2 region 434616

 08-18-22-45 v2 V2 area 432575

 13 v2 V2 area 432559

 04 v2 V2 area 416492

 49 v2 V2 region 407 134

 43 v3 V3 area 43685987

 49 v3 V3 area 27404940

 45 v3 V3 area 1861661

 12 v3 V3 area 1662885

 44 v3 V3 area 1586160

 32 v3 V3 region 1 171556

 28 v3 V3 region 433031

 06-29 One 34 v3 V3 area 290481

 23.30 v3 V3 area 286664

21 3 V3 area 272 138 Table 48 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Streptococcus varnish (microorganism ID 44) with each probe on the chip. From the results in Table 48, it is clear that Streptococcus varnish can be detected and identified by using probes 44 vl, 44 v2, and 44 v3 alone. Comprehensively judging from the combination of the vl, v2, and v3 probes, 44 vl for the vl probe, 44 v2 for the v2 probe, and 44 v3 for the v3 probe have relatively strong signonole intensities. Can be detected and identified as the detected Streptococcus power varnish.

Table 48

Probe ID area Emission signal intensity

 44 v1 V1 region 35094631

 43 v1 V1 area 2427565

 47 v1 V1 region 1943075

 49 v1 V1 region 1355586

 52 v1 V1 region 1229788

 28 v1 V1 region 1 151 650

 53 v1 V1 region 1026335

 21-1 30 v1 V1 area 1010370

 12 v1 V1 region 993928

 39 v1 V1 area 985182

 44 v2 V2 area 23079672

 25 v2 V2 area 1627031

 24 v2 V2 area 1529748

 19 v2 V2 area 1427430

 08J8—22—45 v2 V2 area 1348247

 13 v2 V2 area 1306064

 43 v2 V2 area 1276319

 36 v2 V2 area 1220998

 49 v2 .V2 area 1088665

 04 v2 V2 area 1081821

 44 v3 V3 area 21280416

 43 v3 V3 area 3751773

 49 v3 V3 area 3344193

 12 v3 V3 area 2123092

 32 v3 V3 area 1237399

 46 v3 V3 area 1066998

 28 v3 V3 area 985713

 21 v3 V3 area 943735

 06--29 one 34 v3 V3 area 714979

39 v3 V3 area 690467 Table 49 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Klebsiella oxytoxite (microorganism ID 45) with each probe on the chip. From the results in Table 49, the Klebsiella's oxytox force could not be identified by using probes 45 vl, 45 v2, and 45 v3 alone, but when comprehensively judged by the combination of vl, v2, and v3 probes, the vl probe 18--45 vl, 19--25 vl for the v2 probe, 41--42 v2 for the v2 probe, 45 v3 for the 08_18_22_45 v2 probe, and 05 v3 for the v3 probe have relatively high signal intensity, so high intensities were detected in each region It can be detected and identified as Klebsiella oxytka.

Table 49 Probe ID region Emission signal intensity

 18_45 v1 V1 area 2898674

 19—25 v1 V1 region 1208235

 26 v1 V1 region 755934

 35 v1 V1 region 721250

 52 v1 V1 region 717318

 42 v1 V1 region 660524

 41 v1 V1 region 634 164

 55 v1 V1 area 613698

 53 v1 V1 area 601442

 08 v1 V1 region 593709

 41-42 v2 V2 area 8934930

 08-1 18-1 22-- 45 v2 V2 area 5101372

 24 v2 V2 area 2385253

 19 v2 V2 area 1623113

 25 v2 V2 area 11 12 476

 1 1 v2 V2 area 721183

 40 v2 V2 area 66 800

 51 2 V2 area 567 220

 36 v2 V2 area 535714

 10 v2 V2 area 534958

 45 v3 V3 area 7431501

 05 v3 V3 area 4897697

 18--41 one 42 v3 V3 area 1598792

 25 v3 V3 area 1298790

 08 v3 V3 area 778 610

 13 v3 V3 area 729871

 19 v3 V3 area 619873

 15 v3 V3 area 588761

 31 3 V3 area 568712

26 v3 V3 area 512791 Table 50 shows the results of hybridization of a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Staphylococcus saprophyticus (microorganism ID 46) with each probe on the chip. From the results in Table 50, it is clear that Staphylococcus' subphyticus can be detected and identified by using probe 46v2 alone. Also, even when comprehensively judged by the combination of vl, v2, v3 probes, 16_46 vl, 17 vl, 15 vl for vl probe, 46 v2 for v2 probe, 46 v3, 15 v3, 20 v3, 16 for v3 probe v3, 17 v3 has a relatively strong signal intensity, so that Staphylococcus sapro

Can be detected and identified.

Table 50

Probe ID area Emission signal intensity

 16—46 v1 V1 region 10277032

 17 v1 V area 9674540

 15 v1 V1 region 8769172

 20 v1 V1 region 3283426

 07 v1 V1 region 1892855

 02 v1 V1 region 1889753

 22 v1 V1 area 154 601 1

 13 v1 V1 region 1243847

 50 v1 V1 region 1070738

 35 v1 V1 area 1003672

 46 v2 V2 area 4786129

 17 v2 V2 area 1887621

 35 v2 V2 area 1717876

 15 v2 V2 area 886876

 16 v2 V2 area 478765

 20 v2 V2 area 437165

 01 2 V2 area 258761

 04 v2 V2 area 231987

 24 v2 V2 area 228761

 51 v2 V2 area 217861

 46 v3 V3 area 6991 183

 15 v3 V3 area 6554178

 20 v3 V3 area 5145896

 16 v3 V3 area 4530444

 17 v3 V3 area 4503253

 35 v3 V3 area 2942362

 04 v3 V3 area 456583

 32 v3 V3 area 366061

 49 v3 V3 area 334 503

09 v3 V3 area 281 250 Table 51 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Pasulella 'multocida (microorganism ID 47) with each probe on the chip. From the results in Table 51, it is clear that Pasulella 'Multocida can be detected and identified by using probes 47 v2 and 47 v3 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, the vl probe has a relatively strong signal intensity of 47 vl, 01 vl, 47 v2 for the v2 probe, and 47 v3 for the v3 probe. It can be detected and identified as Pasulella multocida where high intensity was detected in the area.

Table 51

Probe ID area Emission signal intensity

 47 v1 V1 area 26718761

 01 1 V1 area 187651 12

 03 v1 V1 region 88761 12

 14 v1 V1 region 6987991

 24 v1 V1 region 5989798

 42 v1 V1 region 5587619

 41 v1 V1 region 5287681

 56 v1 V1 region 3987911

 50 v1 V1 region 3387162

 05 v1 V1 area 2589761

 47 v2 V2 region 37586588

 03 v2 V2 area 4960568

 24 v2 V2 region 446 406

 01 v2 V2 region 347257

 19 v2 V2 region 304 368

 48 v2 V2 region 302776

 07 v2 V2 area 301 324

 25 v2 V2 area 293772

 08J 8-1-1 22-45 v2 V2 area 288850

 41-42 v2 V2 area 286 261

 47 v3 V3 region 33921374

 53_54 v3 V3 area 1892549

 14 v3 V3 region 261579

 01 3 V3 region 257277

 04 v3 V3 area 250816

 23-30 v3 V3 area 250456

 28 v3 V3 area 247470

 1 1 v3 V3 region 246482

 21 v3 V3 region 245279

49 v3 V3 area 244577 Table 52 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Eikenella's mouth mouth (microorganism ID 48) with each probe on the chip. From the results in Table 52, it is clear that Eikenella's colodense can be detected and identified by using the probes 48 vl, 48 v2, and 48 v3 alone. Also, even when comprehensively judged by the combination of vl, v2 and v3 probes, 48 vl for the vl probe, 48 v2 for the v2 probe, and 48 v3 for the v3 probe have relatively strong signal intensities, so they are high in each region. The intensity can be detected and identified as Eikenella colodense. ' ^: ' Table 52

Probe ID area Emission signal intensity

 48 vl V1 region 13502759

 56 v1 V1 area 990652

 53 v1 V1 area 901384

 55 v1 V1 area 896 907

 54 v1 V1 region 853309

 51 v1 V1 region 751093

 52 v1 V1 region 730236

 50 v1 V1 region 557710

 36 v1 V1 region 468439

 40 v1 V1 region 427702

 48 v2 V2 area 14921478

 7 v2 V2 area 1825342

 40 v2 V2 area 1026522

 4 v2 V2 area 732834

 36 v2 V2 area 514674

 50 v2 V2 area 389476

 8_18_22_45 v2 V2 area 360461

 55 v2 V2 area 357967

 51 v2 V2 area 356 507

 1 1 v2 V2 area 353923

 48 v3 V3 area 10069025

 53_54 v3 V3 area 794485

 50 v3 V3 area 440 359

 51 v3 V3 area 376628

 47 v3 V3 area 366841

 52--55 v3 V3 area 349558

 40 v3 V3 area 344429

 2 v3 V3 area 326945

 56 v3 V3 area 324890

36 v3 V3 area 324201 Table 53 shows the results obtained by hybridizing a polynucleotide having a sequence containing the VI to V3 region of 16S rRNA of Streptococcus pyogenes (microorganism ID 49) with each probe on the chip. From the results in Table 53, it is clear that Streptococcus pyogenes can be detected and identified by using probe 49v2 alone. Also, even when comprehensively judged by the combination of the vl, v2, and v3 probes, 49 vl, 3 vl, 49 v2 for the v2 probe, 49 v3, and 43 v3 for the v3 probe have relatively strong signal intensities. Therefore, it is possible to detect and identify Streptococcus pyogenes in which high intensity was detected in each region.

Table 53

Probe ID area Emission signal intensity

 49 v1 V1 region 9198798

 43 v1 V1 area 7387612

 28 v1 V1 region 987988

 21_30 v1 V1 region 787618

 44 v1 V1 region 678681

 1 9-1 25 v1 V1 region 571 614

 17 v1 V1 region 571 185

 16_46 v1 V1 area 479871

 4 v1 V1 area 408791

 53 v1 V1 region 387987

 49 v2 V2 region 14086816

 7 v2 V2 region 431324

 25 v2 V2 region 361329

 4 v2 V2 area 350067

 19 v2 V2 region 348217

 24 v2 V2 region 342690

 41--42 v2 V2 region 323245

 36 v2 V2 region 317579

 34 v2 V2 region 305 133

 8.18.22_45 v2 V2 area 301791

 49 v3 V3 area 14313338

 43 v3 V3 area 14017125

 12 v3 V3 area 1716148

 32 v3 V3 area 551288

 44 v3 V3 area 525 264

 45 v3 V3 area 464793

 46 v3 V3 region 359604

 8 v3 V3 area 358 468

 24 v3 V3 region 355960

22 v3 V3 area 339749 Table 54 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Moraxella catarrhalis (microorganism ID 50) with each probe on the chip. From the results in Table 54, it is clear that Moraxella's force tararis can be detected and identified by using probes 50 vl, 50 v2, and 50 v3 alone. Even when the combination of vl, v2, and v3 probes is comprehensively evaluated, the vl probe has a relatively strong signal intensity of 50 vl, the v2 probe has 50 v2, and the v3 probe has 50 v3. It can be detected and identified as a Moraxella or catarrhalis whose intensity has been detected.

Table 54

Probe ID area Emission signal intensity

 50 v1 V1 region 33692348

 31 v1 V1 region 2237951

 07 v1 V1 region 1491773

 08 v1 V1 region 1395166

 01 v1 V1 region 1 184515

 20 v1 V1 region 1 133034

 09 v1 V1 region 1067291

 17 v1 V region 9351 14

 16--46 v1 V1 region 91 1298

 03 v1 V1 area 907361

 50 v2 V2 area 8304820

 04 v2 V2 area 329961 1

 07 v2 V2 area 893720

 08 18 22 45 v2 V2 area 827816

 40 v2 V2 area 788590

 19 v2 V2 area 758554

 25 v2 V2 area 743874

 36 v2 V2 area 654 115

 02 v2 V2 area 591388

 1 1 v2 V2 area 589922

 50 v3 V3 area 5799671

 31 v3 V3 area 319034

 18-1 41_42 v3 V3 area 312670

 24 v3 V3 area 308527

 25 v3 V3 area 290 458

 05 v3 V3 area 281378

 45 v3 V3 area 254033

 19 v3 V3 area 252532

 07 v3 V3 area 244682

20 v3 V3 area 239298 Table 55 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Legionella 'pneumophila (microorganism ID 51) with each probe on the chip. From the results in Table 55, it is clear that Legionella pneumophila can be detected and identified by using probes 51 vl, 51 v2, and 51 v3 alone. In addition, even when comprehensively judged by the combination of vl, v2, and v3 probes, 51 vl for the vl probe, 51 v2 for the v2 probe, and 51 v3 for the v3 probe have relatively strong signal strengths. Legionella's pneumophila with high intensity detected in the region can be detected and identified.

Table 55

Probe ID area Emission signal intensity

 51 vl VI region 24876818

 52 v1 V1 area 528761 1

 55 v1 V1 region 51 19832

 53 v1 V1 area 387181 1

 54 v1 V1 area 2876861

 56 v1 V1 area 1976817

 09 v1 V1 region 1387681

 50 v1 V1 area 1287681

 48 v1 V1 region 1 19871 1

 39 v1 V1 region 1019871

 51 v2 V2 area 21387192

 52 v2 V2 area 8987614

 55 v2 V2 region 1989729

 54 v2 V2 area 1898798

 53 v2 V2 area 1598791

 56 v2 V2 area 1498791

 40 v2 V2 area 146761 1

 1 1 v2 V2 area 129871 1

 10 v2 V2 area 1 1 19821

 36 v2 V2 area 987123

 51 3 V3 area 14398704

 52--55 v3 V3 domain 1319899

 53--54 v3 V3 area 491713

 56 v3 V3 area 44871 1

 38 v3 V3 area 418731

 07 v3 V3 area 389816

 19 v3 V3 area 387681

 39 v3 V3 area 379918

 37 v3 V3 area 368761

25 v3 V3 area 351875 Table 56 shows the results of hybridization of a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Mycobacterium tuberculosis (microorganism ID 52) with each probe on the chip. From the results shown in Table 56, it is clear that mycopacteria tuberculosis can be detected and identified by using probe 52 v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, the signal intensity is relatively strong at 52 vl, 55 vl for the vl probe, 52 v2 for the v2 probe, 52_55 v3, and 53—54 v3 for the v3 probe. Therefore, it can be detected and identified as Mycobacterium. Table 56

Probe ID area Emission signal intensity

 52 v1 V1 area 17196053

 55 v1 V1 region 1041 1849

 53 v1 V1 region 6047891

 54 v1 V1 region 3971764

 71 1 V1 area 3827331

 09 v1 V1 region 1 197595

 50 v1 V1 region 863188

 48 v1 V1 area 843273

 39 v1 V1 region 746841

 38 v1 V1 area 672 658

 52 v2 V2 area 173981 18

 55 v2 V2 area 3193388

 54 v2 V2 area 1821709

 53 v2 V2 area 1598909

 56 v2 V2 area 777591

 40 v2 V2 area 408032

 51 v2 V2 area 287459

 1 1 2 V2 area 251307

 10 v2 V2 area 250094

 36 v2 V2 area 240 315

 52 1 55 v3 V3 area 20381022

 53-54 v3 V3 area 1 1 192775

 56 v3 V3 area 8461940

 39 v3 V3 area 220756

 07 v3 V3 area 157302

 19 v3 V3 area 150 205

 39 v3 V3 area 148797

 37 v3 V3 area 148389

 25 v3 V3 region 142268

20 v3 V3 area 140806 Table 57 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Mycobacterium avidum (microorganism ID 53) with each probe on the chip. From the results in Table 57, it is clear that mycobacterium avime can be detected and identified by using probe 53v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, the vl probe has 53 vl, 54 vl, the v2 probe has 53 v2, the v3 probe has 56 v3, 53—54 v3, and 52—55 v3 force. S Since it has a relatively strong signal intensity, it can be detected and identified as a mycobacterium avium in which high intensity was detected in each region.

Table 57

Probe ID area Emission signal intensity

 53 v1 V1 region 46987988

 54 v1 V1 area 36176731

 52 v1 V1 area 6876819

 55 v1 V1 region 6198763

 56 v1 V1 region 1879132

 10 v1 V1 region 1 198723

 13 v1 V1 region 939714

 38 v1 V1 region 879813

 05 v1 V1 area 826813

 27 v1 V1 area 771568

 53 v2 V2 area 21270538

 40 v2 V2 area 2009083

 10 v2 V2 region 1205790

 1 1 v2 V2 area 963480

 04 v2 V2 area 697372

 51 2 V2 area 694035

 07 v2 V2 region 654143

 19 v2 V2 region 604806

 54 v2 V2 region 583414

 52 v2 V2 area 566 515

 56 v3 V3 area 9459717

 53 one 54 v3 V3 area 7329665

 52-55 v3 V3 area 5980193

 20 v3 V3 region 469364

 17 v3 V3 area 441098

 25 v3 V3 area 380 680

 07 v3 V3 area 347 194

 46 v3 V3 area 315047

 15 v3 V3 area 289 176

10 v3 V3 area 275 267 Table 58 shows the results obtained by hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Mycobacterium 'intrasenorale (microorganism ID 54) with each probe on the chip. From the results in Table 58, it is clear that Mycobacterium intracellulare can be detected and identified by using probe 54v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, 54 vl for the vl probe, 54 v2 for the 53 vl, v2 probe, 56 v3 for the v3 probe, and 53_54 v3 have relatively strong signal intensities. Therefore, it can be detected and identified as Mycobacterium intracellulare in which high intensity was detected in each region.

Table 58

Table 59 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Mycobacterium kansasii (microorganism ID 55) with each probe on the chip. From the results in Table 59, it is clear that Mycobacterium kansasii can be detected and identified by using probe 55 v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, the signal intensity is relatively strong at 55 vl, 52 vl for the vl probe, 55 v2 for the v2 probe, and 52-55 v3, 56 v3 for the v3 probe. Therefore, it can be detected and identified as Mycobacterium kansasii in which high intensity was detected in each region.

Table 59

Probe ID area Emission signal intensity

 55 v1 V1 region 27987135

 52 vl VI region 18971812

 53 v1 V1 region 4786132

 54 v1 V1 area 3987133

 56 v1 V1 area 2187634

 38 v1 V1 region 1387681

 39 v1 V1 area 1287731

 27 v1 V1 region 1216765

 26 vl VI region 1098791

 05 v1 V1 region 798716

 55 v2 V2 area 4421 7188

 52 v2 V2 area 1 171394

 40 v2 V2 area 1 161 661

 54 v2 V2 area 1 123 512

 1 1 v2 V2 area 942604

 53 v2 V2 area 872231

 56 v2 V2 area 826313

 10 v2 V2 area 695878

 51 v2 V2 area 689889

 07 v2 V2 area 663997

 52 one 55 v3 V3 area 39856910

 56 v3 V3 area 20 350 562

 53--54 v3 V3 area 16127395

 18—41 one 42 v3 V3 area 392542

 08 v3 V3 area 368803

 20 v3 V3 area 352527

 07 v3 V3 area 347768

 17 v3 V3 area 347648

 45 v3 V3 area 343925

19 v3 V3 area 332638 Table 60 shows the results of hybridizing a polynucleotide having a sequence containing the V1 to V3 region of 16S rRNA of Mycobacterium gordonii (microorganism ID 56) with each probe on the chip. From the results in Table 60, it is clear that mycobacterium 'Gordone' can be detected and identified by using probes 56 vl and 56 v2 alone. Also, even when comprehensively judged by the combination of vl, v2, and v3 probes, the signal intensity is relatively strong at 56 vl for the vl probe, 56 v2 for the v2 probe, 56 v3 for the v3 probe, and 53_54 v3. However, it can be detected and identified as Mycobacterium gordone in which high intensity was detected in each region.

Table 60

Probe ID area Emission signal intensity

 56 v1 V1 region 30688338

 54 v1 V1 region 2713077

 53 v1 V1 region 2497231

 52 v1 VI region 2093852

 55 v1 V1 region 1112548

 36 v1 VI region 788790

 10 v1 V1 region 725818

 05 v1 V1 area 542286

 13 v1 V1 area 538930

 39 v1 V1 region 53330.

 56 v2 V2 area 7578904

 52 v2 V2 area 1892398

 40 v2 V2 region 1364607

 51 v2 V2 area 984604

 11 2 V2 area 585449

 10 v2 V2 area 580267

 55 v2 V2 area 486057

 02 v2 V2 area 450 110

 41-42 v2 V2 region 408259

 54 v2 V2 area 397348

 56 v3 V3 area 56594408

 53-54 v3 V3 area 28772559

 52-55 55 v3 V3 area 11861849

 12 v3 V3 area 406138

 20 v3 V3 area 296776

 07 v3 V3 area 292847

 44 v3 V3 area 290 502

 11 3 V3 area 289832

 17 v3 V3 area 284805

50 v3 V3 area 282254 [Example 3] Microorganism identification method based on signal results from a plurality of probes The microorganism-derived vl, v2, and v3 probes described in Table 3 above all have their nucleotide sequences and nucleotide sequences derived from other microorganisms. Since the number of mismatches was 3 or less, cross-hybridization with nucleotide sequences derived from other microorganisms occurred, and it was difficult to detect and identify them with a single probe. For this reason, the microorganisms listed in Table 3 above were grouped based on their detection signal trends, and the results of the hybridization detection signals using vl, v2, and v3 probes derived from those microorganisms were comprehensively analyzed. After examination, the genus of the microorganism was identified. '

 For example, Streptococcus' pneumoniae (microbe ID 06), Streptococcus' miteis (microbe ID 29) and Streptococcus' Olaris (microbe ID 34) are highly homologous because they belong to the same genus, and are distinguished from each other. In particular, Streptococcus pneumoniae and Streptococcus miteis were indistinguishable by a single probe. Therefore, these were put together as Group A, and when the subject was determined to be any of these three types, further identification work using three types of v1 to v3 probes corresponding to each was performed. The results of the detection signals for the three types of microorganisms, Streptococcus 'nucleus monies (microorganism ID 06), Streptococcus' miteis (microorganism ID 29), and Streptococcus oralis (microorganism ID 34), were recorded. Table 61 summarizes the microorganism probes. Table 61

 ◎ indicates that there is no mismatch in the nucleotide sequence between the microorganism and the probe, and that it has strong Gunnar strength

 〇 indicates that the base sequence between the microorganism and the probe has 3 or less mismatches and the signal intensity is strong.

X has 4 or more mismatches in the base sequence between the microorganism and the probe. As evident from Table 61, each microorganism in Group A has a unique detection signal pattern for each probe. In other words, Streptococcus ′ pneumoniae (microorganism ID 06) has a weak signal intensity for 34 vl and v2 probes, and a strong signal intensity for other 06 vl to v3 probes, 29 vl to v3 probes, and 34 v3 probes. By comprehensively judging the degree of color development in these spots, it was possible to identify whether or not the specimen was Streptococcus' pneumoniae (microorganism ID 06). Similarly, for Streptococcus mitices (microorganism ID 29) and Streptococcus olaris (living organism ID 34), signals specific to probes 06 vl to v3, 29 vl to v3, and 34 vl to v3 are also available. Because of the intensity presentation pattern, by comprehensively judging the degree of color development at the spots of these probes, the specimen can be treated with Streptococcus' mitices (microorganism ID 29) or Streptococcus. It was possible to identify whether or not the microorganism was Streptococcus' pneumoniae (microorganism ID 06).

Similarly, Staphylococcus hominis (microorganism ID 15), Staphylococcus perneri (microorganism ID 16), Staphylococcus hemoriticus (microorganism ID 17), Staphylococcus * epidermidis (microorganism ID 20), Staphylo Coccus aureus (microorganism ID 35), Staphylococcus ♦ Saprophyticus (microorganism ID 46) has a high similarity in the 16S rRNA gene sequence because of its genus, making it difficult to distinguish them from each other. Coccus hominis, Streptococcus perneri, Staphylococcus hemoriticus, and Staphylococcus' epidermidis could not be distinguished by a single probe. Therefore, these microorganisms were classified into Group B, and their unique detection signal patterns for each probe of each microorganism were examined. Table 62 shows the results. As a result, it was found that the microorganisms could be identified based on the unique detection signal pattern of each microorganism. Table 62

 ◎ indicates that there is no mismatch in the nucleotide sequence between the microorganism and the probe, and that it has strong Gunnar strength

 〇 indicates that the number of mismatches in the base sequence between the microorganism and the probe is 3 or less and the re-signal intensity is strong.

X has 4 or more mismatches in the base sequence between the microorganism and the probe and has a low re-signal intensity. Similarly, Citropactor-Frendi (Microbial ID 08), Enterobacter-Chlore force (Microorganism ID 18), and Enteropator 'Aerogenes ( Microbial ID 19), Serratia marcescens (Microbial ID 22), Escherichia coli (Microbial ID 24), Klebsiella pneumoniae (Microbial ID 25), Salmonella Paratifi A (Microbial ID 41), Salmonella chifi (Microbial ID 24) 42), Krebsella 'Oxitka (microbial ID 45) has a high similarity of 16S rRNA gene sequences and is difficult to distinguish from each other. Krebsella oxytite force could not be distinguished by a single probe Therefore, these microorganisms were group C, and their unique detection signal patterns for each probe were examined. The results are shown in Table 63. As a result, it was found that the microorganisms could be identified based on the unique detection signal pattern of each microorganism. However, among them, in the case of Salmonella 'paratyphi and Salmonella typhi, it was possible to detect the presence of any of the microorganisms. 03 07 620 Table 63

 ◎ indicates that there is no mismatch in the nucleotide sequence between the microorganism and the probe, and that it has strong Gunnar strength

 〇 indicates that the number of mismatches is 3 or less in the base sequence between the microorganism and the probe.

X has four or more mismatches in the nucleotide sequence between the microorganism and the probe, and has a weak signal intensity.Similarly, Enterococcus' Fesidum (Microorganism ID 27), Streptococcus sandais (Microorganism ID 28), and Enterococcus galinarum (Microorganism ID) 38), Enterococcus cerevisiae (microbial ID 39) has a high similarity in the 16S rRNA gene sequence and is difficult to distinguish from each other. In particular, Enterococcus' Galinarum and Enterococcus cerevisiae. Was. Therefore, these microorganisms were classified into Group D, and their unique detection signal patterns for each probe of each microorganism were examined. Table 64 shows the results. As a result, it was found that the microorganism can be identified based on the unique detection signal pattern of each microorganism. However, among these, in the case of Enterococcus 'Gallinanolem, Enterococcus' force seriflapus, it was possible to detect either microorganism. Table 64

 O indicates that the base sequence between the microorganism and the probe has 3 or less mismatches and the signal intensity is strong.

Are those with four or more mismatches in the base sequence between the microorganism and the probe and weak signal intensity. Streptococcus '' consteratas (microorganism ID 21), Streptococcus anginosus (microorganism ID 23), Streptococcus intermedius (microbial ID 30) is a congener and has a high similarity in the 16S rRNA gene sequence and is difficult to distinguish from each other. In particular, Streptococcus intermedius can be distinguished by a single probe. It was impossible. Therefore, these microorganisms were classified into Group E and their unique detection signal patterns for each probe of each microorganism were examined. Table 65 shows the results. As a result, it was found that the microorganisms could be identified based on the unique detection signal pattern of each microorganism.

Table 65

 ◎ indicates that there is no mismatch in the nucleotide sequence between the microorganism and the probe, and that it has strong Gunnar strength

 O indicates that the base sequence between the microorganism and the probe has less than 3 mismatches and strong re-signal strength.

 X is a nucleotide sequence between the microorganism and the probe having four or more mismatches and a low re-signal intensity.As described above, the microorganisms shown in Table 1 are detected and / or identified by using the probe of the present invention. Became possible. In addition, since the detection signal pattern has been clarified, the microorganism of the subject can be quickly and reliably detected and identified by registering the detection signal pattern in a storage analysis medium such as a computer in advance. .

 All publications, patents and patent applications cited in this specification are incorporated herein by reference in their entirety. Industrial applicability

 Among the 16S rRNA nucleotide sequences of the microorganism of the present invention, using a probe designed from the nucleotide sequences of the VI, V2 and V3 regions, which have particularly high specificity, the nucleic acid extracted from the microorganism to be tested is used as a type II by PCR method. By performing amplification and analyzing the obtained amplification product, harmful bacteria can be specifically and rapidly detected and identified in the fields of medicine and food.

Claims

The scope of the claims

1. Actinobacillus act inomycetemcomi tans, Actinobacillus act inomycetemcomi tans, Acinetobacter calcoaceticus, Hemophilus influenzasa, Haemophi 丄 us influenzae Lya (Stenotrophomonas maltophilia), Proteus 'Miravilis (Proteus mirabilis), Streptococcus' Pneumoniae

(Streptococcus pneumoniae), N'yu Tomonasu-Erukinosa (Pseudomonas aeruginosa), ShitoronoヽKuta ¹ ~ · Frendy (Citrobacter freundii) Beiyo non-La. Parupura (Veillonella parvula), professional Bidenshia-Stu artistic

(Providencia stuartii) _N Neisseria Konoroe (Neisseria gonorrhoeae scan Bok replica Bok Staphylococcus-Agarakuche (Streptococcus agalactiae) _N Morganella Monoregani (Morganella morganii) _N Roh Kuteroi τ ~ scan - Furajijisu (Bacteroides fragilis), Staph Gray Staphylococcus hominis (Staphylococcus hominis), Staphylococcus warneri ス タ Staphylococcus warneri ゝ Staphylococcus haemolyticus, Enterobacter-Croca

(Enterobacter cloacae), Enterobacter aerogenes, Staphylococcus << Staphylococcus epidermidis, Streptococcus' Consuffac ¹ ~ tas, Streptococcus constellatus, sera 'Manolessesens (Serratia marcescens), Streptococcus anginosus (Streptococcus anginosus), Escherichia coli

(Escherichia coli), Klebsiella pneumoniae ( _N. enterococcus faecalis), Enterococcus faeciura, Streptococcus sanguisu

(Streptococcus sanguis), Streptococcus ice (Streptococcus mitis Streptococcus intermedius), Listeria monocytogenes, Clostridium perfringens, Clostridium perfringens

(Corynebacterium aquatium) Sleff. Tococcus' offris (Streptococcus oralis), Staphylococcus aureus, Neisseria meningitidis

 ), Campylonecta. Fuetus (Campylobacter fetus), Enterococcus' Gallinolem (Enterococcus gallinarum) Enterococcus-Force celiflabas

(Enterococcus casseliflavus), Aeromonas hydrophila, Salmonella paratyphi A, Salmonella typhi, Streptococcus ethysimilis

(Streptococcus equisimilis), Streptococcus 'force varnish (Streptococcus canis), Kurebusera * Okishito force (Klebsiella oxytoca), Staph aureus Gray' saprophyticus _{(Staphylococcus} saprophyticus) Λ Roh Surrera "Munore Bok signaling

(Pasteurella multocida), Eikene: · Eikenella corrodens, Stref. R. ; Mycobacterium intracellulars (Mycobacterium intracellulars, Mycobacterium kansasii) ^ Myconobacterium intracellulars

A probe for detecting and / or identifying one or more microorganisms selected from (Mycobacterium gordonae) in the VI, V2 and Z or V3 regions of the 16S rRNA of the microorganism to be detected and / or identified. A probe consisting of each base sequence of 20 to 100 bp or its complement.

 2. The probe according to claim 1, which is selected from the base sequence represented by SEQ ID NOs: 1 to 152 or a complementary sequence thereof.

 3. A probe for detecting and / or identifying R. cutinobacillus actinomycetemcomitans, comprising the nucleotide sequence shown in SEQ ID NO: 1, 2, or 3, or a complementary sequence thereof.

 4. A probe for detecting and / or identifying Acinetobacter P. calcoaceticus, comprising the nucleotide sequence shown in SEQ ID NO: 4, 5 or 6, or a complementary sequence thereof.

5. Including the nucleotide sequence shown in SEQ ID NO: 7, 8 or 9, or a complementary sequence thereof, Probe for detecting and / or identifying Hemophilus influenza.

6. A probe for detecting and / or identifying or identifying Stenotrophomonas maltophilia, comprising the nucleotide sequence shown in SEQ ID NO: 10, 11 or 12, or a complementary sequence thereof.

 7. A probe for detecting, detecting, or identifying Proteus mirabilis, comprising the base sequence shown in SEQ ID NO: 13, 14, or 15, or a complementary sequence thereof.

 8. A probe for detecting and / or identifying Streptococcus pneumoniae, comprising the nucleotide sequence shown in SEQ ID NO: 16, 17, or 18, or a complementary sequence thereof.

 9. A probe for detecting and / or identifying Pseudomonas aeruginosa, comprising the nucleotide sequence shown in SEQ ID NO: 19, 20, or 21, or a complement thereof.

 10. A probe for detecting, detecting, or identifying Citropactor. Frendi, comprising the nucleotide sequence of SEQ ID NO: 22, 23 or 24, or a complementary sequence thereof.

 11. A probe for detecting and / or identifying Bayonella's parvula, comprising the base sequence shown in SEQ ID NO: 25, 26 or 27, or a complementary sequence thereof.

 12. A probe for detecting and / or identifying Providence 'stuarty, comprising the nucleotide sequence of SEQ ID NO: 28, 29' or 30, or the complement thereof.

 13. A probe for detecting and / or identifying Neisseria gonorrhoeae, comprising the nucleotide sequence shown in SEQ ID NO: 31, 32 or 33, or a complementary sequence thereof.

 14. A probe for detecting and / or identifying or identifying Streptococcus agalactus, comprising the nucleotide sequence shown in SEQ ID NO: 34, 35 or 36, or a complementary sequence thereof.

 15. A probe for detecting and / or identifying Morganella morganii, comprising the nucleotide sequence of SEQ ID NO: 37, 38 or 39, or a complementary sequence thereof.

 16. A probe for detecting and / or identifying Pacteroides fragilis, comprising the nucleotide sequence shown in SEQ ID NO: 40, 41 or 42, or a complementary sequence thereof.

 17. A probe for detecting and / or identifying or identifying Staphylococcus hominis, comprising the nucleotide sequence shown in SEQ ID NO: 43, 44 or 45, or a complementary sequence thereof.

18. A probe for detecting and / or identifying Staphylococcus perneri, comprising a nucleotide sequence represented by SEQ ID NO: 46, 47 or 48, or a complementary sequence thereof.

19. A probe for detecting, detecting, or identifying Staphylococcus hemolyticus, comprising the nucleotide sequence shown in SEQ ID NO: 49, 50 or 51, or a complementary sequence thereof.

 20. A probe for detecting and / or identifying or identifying Enterobacter choraka, comprising the base sequence shown in SEQ ID NO: 52, 23 or 53, or a complementary sequence thereof.

 21. A probe for detecting and / or identifying Enterobacter aerogenes, comprising the nucleotide sequence shown in SEQ ID NO: 54, 55 or 56, or a complementary sequence thereof.

2 2. SEQ ID NO: 57, 58 or 59 nucleotide sequence shown in, or including the phases capturing sequence, Staph Gray Lactococcus. Epiderumidisu detection and Z or flop π- Bed for identifying ₀

2 3. SEQ ID NO: 60, 61 or 62 nucleotide sequence shown in, or including a sequence complementary thereto, stress but-Staphylococcus con Suterata scan detection及Pi z or flop port one Bed for identifying ₀

 24. A probe for detecting, detecting or identifying Serratia marcescens, comprising the base sequence shown in SEQ ID NO: 63, 23 or 64, or a complementary sequence thereof.

 25. A probe for detecting and Z or identifying Streptococcus angiosus comprising the nucleotide sequence shown in SEQ ID NO: 65, 66 or 67, or a complementary sequence thereof.

 26. A probe for detecting and Z or identifying Escherichia coli, comprising the base sequence shown in SEQ ID NO: 68, 69 or 70, or a complementary sequence thereof.

 27. A probe for detecting, detecting, or identifying Klebsiella 'pneumoniae, comprising the nucleotide sequence shown in SEQ ID NO: 54, 71 or 72, or a complement thereof.

 28. A probe comprising the nucleotide sequence of SEQ ID NO: 73, 74 or 75, or a complementary sequence thereof, for detecting, detecting or identifying Enterococcus faecalis.

 29. A probe for detecting, detecting or identifying Enterococcus faecium, comprising the nucleotide sequence shown in SEQ ID NO: 76, 77 or 78, or a complementary sequence thereof.

 30. A probe for detecting and / or identifying or identifying Streptococcus' sandyce, comprising the nucleotide sequence shown in SEQ ID NO: 79, 80 or 81, or a complementary sequence thereof.

31. Including the base sequence shown in SEQ ID NO: 82, 83 or 18, or its complementary sequence A probe for detecting and / or identifying Streptococcus mites.

32. A probe for detecting and / or identifying Streptococcus intermedius, comprising the nucleotide sequence of SEQ ID NO: 60, 84 or 67, or a complementary sequence thereof.

 33. A probe comprising the nucleotide sequence of SEQ ID NO: 85, 86 or 87, or a complementary sequence thereof, for detecting and identifying or identifying Listeria monocytogenes.

 34. A probe for detecting and / or identifying Clostridium perfringens, comprising the nucleotide sequence shown in SEQ ID NO: 88, 89 or 90, or a complementary sequence thereof.

 35. A probe for detecting and / or identifying Corynebacterium aquatium, comprising a nucleotide sequence represented by SEQ ID NO: 91, 92 or 93, or a complementary sequence thereof.

 36. A probe for detecting and / or identifying Streptococcus oralis, comprising the nucleotide sequence shown in SEQ ID NO: 94, 95 or 18, or a complementary sequence thereof.

 37. A probe for detecting, detecting, or identifying Staphylococcus aureus comprising the nucleotide sequence of SEQ ID NO: 96, 97, or 98, or a complementary sequence thereof.

 38. A probe for detecting, detecting, or identifying Neisseria meningitidis comprising the nucleotide sequence of SEQ ID NO: 99, 100 or 101, or a complement thereof.

 39. A probe for detecting and / or identifying Campylobacter huetas, comprising the nucleotide sequence shown in SEQ ID NO: 102, 103 or 104, or a complementary sequence thereof.

 40. A probe for detecting and / or identifying Enterococcus gallinarum, comprising the nucleotide sequence shown in SEQ ID NO: 105, 106 or 107, or a complementary sequence thereof.

 41. A probe for detecting and / or identifying Enterococcus caseriflapus, comprising the nucleotide sequence shown in SEQ ID NO: 108, 106 or 109, or a complementary sequence thereof.

 4 2 A probe for detecting and / or identifying Aeromonas hydrophila, comprising the base sequence shown in SEQ ID NO: 110, 111 or 112, or a complementary sequence thereof.

43. A probe for detecting, detecting, or identifying Salmonella paratyphi, comprising the nucleotide sequence of SEQ ID NO: 113, 114, or 53, or a complement thereof.

44. A probe for detecting and / or identifying Salmonella typhi, comprising the nucleotide sequence of SEQ ID NO: 115, 114 or 53, or the complement thereof.

 45. A probe for detecting and / or identifying or identifying Streptococcus equisimilis, comprising the base sequence IJ shown in SEQ ID NO: 116, 117 or 118, or a complementary sequence thereof.

 46. A probe comprising the nucleotide sequence of SEQ ID NO: 119, 120 or 121, or a complementary sequence thereof, for detecting, detecting or identifying Streptococcus varnish.

 47. A probe for detecting and / or identifying Klebsiella oxytoca, comprising the nucleotide sequence shown in SEQ ID NO: 52, 23 or 122, or a complementary sequence thereof.

 48. A probe for detecting, Z or identifying Staphylococcus saprophyticus, comprising the nucleotide sequence of SEQ ID NO: 46, 123 or 124, or a complement thereof.

 49. A probe for detecting and / or identifying or identifying Z. pasturella multocida, comprising the nucleotide sequence shown in SEQ ID NO: 125, 126 or 127, or a complementary sequence thereof.

 50. A probe for detecting, identifying, or identifying Eikenella corodense, comprising the nucleotide sequence shown in SEQ ID NO: 128, 129 or 130, or a complementary sequence thereof.

 51. A probe for detecting and / or identifying Streptococcus pyogenes comprising the nucleotide sequence shown in SEQ ID NO: 131, 132 or 133, or a complementary sequence thereof.

 52. A probe for detecting and Z or identifying Moraxella catarrhalis, comprising the nucleotide sequence of SEQ ID NO: 134, 135 or 136, or a complementary sequence thereof.

 53. A probe comprising the nucleotide sequence of SEQ ID NO: 137, 138 or 139 or a complementary sequence thereof for detecting and identifying Legionella pneumophila.

5 4. SEQ ID NO: 140, 141 or 142 nucleotide sequence shown in, or its complementary sequence, Mycobacterium Riu-time Bberuku detecting port cis and / or probes for identifying ₀

 55. A probe for detecting and / or identifying mycopacterium 'avime, comprising the nucleotide sequence of SEQ ID NO: 143, 144 or 145, or a complement thereof.

5 6The base sequence shown in SEQ ID NO: 146, 147 or 145, or its complementary sequence A probe for detecting and / or identifying mycobacterium intracellulare.

 57. A probe for detecting and / or identifying Mycobacterium kansasii, comprising the nucleotide sequence of SEQ ID NO: 148, 149 or 145, or a complementary sequence thereof.

 58. A probe for detecting and / or identifying Mycobacterium gordonii, comprising the nucleotide sequence shown in SEQ ID NO: 150, 151 or 152, or a complementary sequence thereof.

5 9. Homology search in the nucleotide sequence of 16S rRNA of a plurality of microorganisms, their VI in microorganisms respectively, identify V2, V ³ region, the VI, V2, V3 2 or in the nucleotide sequence of the region A method for designing a probe, comprising determining a mismatched site by comparing the microorganisms described above, and determining a region containing the mismatched site and having a base length of 20 to 100 bp.

60. An actinopati ^ / s ♦ actinopathy ^ / s, characterized by using at least one of the probes according to claim 1 or 2, acinetopactor 力 レ レ レ へ へ へMouth Fomonas maltophilia, Proteus' Miravilis, Streptococcus' Pneumonia, Cypudomonas enoreginosa, Citrono kuqta. Frendi, Bayonela 'Panorebula, Providencia stuati, Neisseria gonolkoska Agaratache, Monoreganella Mo ^ "Gani, Batateroides 'Fragris, Staphylococcus' Hominis, Staphylococcus. Penorenelli, Stafylococcus. Certa Erogenes, Staphylococcus .Epidenoremidis, Streptococcus 'Constellatas, Serratia .Manoresessence, Streptococcus anginosus, Escherichia' Koli, Klebcella Neumonnier, Enterococcus fuecoccas fenecocus Fuesium, Streptococcus' Sandice, Streptococcus miteis, Streptococcus' Intermedius, Listeria 'Monositegenes', Clostridium' Perfringens, Corynebacterium 'Aquatium, Streptococcus' Oralis , Staphylococcus apereus, Neisseria meningitidis, Campylobacter fuetas, Enterococcus galinarum, Enterococcus' case Riflanokus, Eromonas · Hydrophila, Salmonella paratyphi A, Salmonella chifi, Streptococcus equisimilis, Streptococcus dysfunction, Klebseira oxytoca, Staphylococcus saprofiticus, Pasulella 'Mnoretoshida, Jequeneres piquones la trek 'Kitara squirrel, Legionella pneumophila, Mycopacteriam' bergberg cis, Mycobacterium 'Abimu, Mycobacterium' Intracenorellare, Mycobata terium 'Kansasi, Mycopacteria gordone selected from 1 or A method for detecting and Z or identifying a plurality of microorganisms.

 61. The method according to claim 60, comprising hybridizing both sequences using stringency conditions that do not hybridize when there are four or more mismatches between the base sequence derived from the microorganism and the base sequence of the probe. Method.

 6 2. Within the V1, V2 and V3 regions of the 16S rRNA of the microorganism to be identified, 20 or more: Two or more microorganisms having the nucleotide sequence of 20 to 100 bp in the VI, V2 and V3 regions of a microorganism different from the two or more microorganisms, or at least one probe comprising a complementary sequence thereof, The method of claim 60 or 61, further comprising identifying one of the two or more microorganisms.

 63. The following steps: (a) a step of preparing a nucleic acid from a microorganism to be identified, (b) a step of hybridizing the nucleic acid with the probe according to claim 1 or 2, and (c) a step of (b) Detecting the presence or absence of hybridization and identifying the detection signal pattern for each probe, (d) comparing the detection signal pattern obtained in step (c) with the detection signal pattern of the microorganism specified in advance The method according to claim 60 or 61, comprising the step of identifying the type of microorganism to be identified by the identification.

 64. The method according to any one of claims 60 to 63, comprising amplifying a nucleotide containing the target sequence using the primers represented by SEQ ID NOS: 153 and 154, and then hybridizing the amplified nucleotide with the probe.

 65. The method according to any one of claims 60 to 64, wherein labeling is performed using a fluorescent substance when amplifying a nucleotide containing the target sequence.

66. The method according to any one of claims 60 to 65, wherein the detection is performed on a DNA chip. ^