CN113667764A - SNP molecular marker with cryptocaryon irritans disease resistance-related traits for trachinotus ovatus and application of SNP molecular marker - Google Patents

Abstract

The invention discloses an SNP molecular marker of cryptocaryon irritans disease resistance related traits of trachinotus ovatus, which is cloned from trachinotus ovatus LAAO gene and is positioned in LAAO gene exon, and the nucleotide sequence of the molecular marker is shown as SEQ ID NO: 1, two allelic gene mutations (C/T) and (G/A) exist at the 6200 base and the 6237 base of the sequence respectively, and also discloses a primer for amplifying the SNP molecular marker and application of the SNP molecular marker or the primer in identifying or breeding the cryptocaryon irritans disease resistant trachinotus ovatus variety. The molecular markers screened by the invention are used for performing correlation analysis on the cryptocaryon irritans resistant disease of trachinotus ovatus, and the two markers can be applied to early screening of trachinotus ovatus breeding materials with disease resistance as a target, so that the breeding efficiency can be effectively improved, and the breeding period can be shortened.

Description

SNP molecular marker with cryptocaryon irritans disease resistance-related traits for trachinotus ovatus and application of SNP molecular marker

Technical Field

The invention belongs to the technical field of molecular marker assisted breeding of fish genetic breeding, and particularly relates to an SNP molecular marker with characteristics related to cryptocaryon irritans disease resistance of trachinotus ovatus and application thereof.

Background

Trachinotus ovatus (Trachinotus ovatus) belongs to Perciformes (Perciformes), Carangidae (Carangidae) and Trachinotus (Trachinotus), commonly known as golden pompanus, short pompano and the like in taxonomy and is mainly distributed in southern sea areas of China. The trachinotus ovatus is thick, solid and tender in meat quality, delicious in taste and high in growth speed, and is edible seawater teleosts with both nutritional value and economic value. However, due to the influence of factors such as overlarge culture density and deterioration of water quality in sea areas, various diseases can be caused in the culture sea areas of the trachinotus ovatus to cause huge economic loss, Cryptocaryon irritans (Cryptocaryon irritans) disease is one of the diseases which can cause serious influence on the culture industry of the trachinotus ovatus, and the death rate of the trachinotus ovatus infected by the Cryptocaryon irritans is extremely high, so that the research on how to improve the resistance of the trachinotus ovatus to the Cryptocaryon irritans is very necessary.

In recent years, due to environmental pollution, frequent disease and the like, the natural population of trachinotus ovatus is seriously degenerated, the germplasm is seriously degenerated and the like; meanwhile, due to close breeding of trachinotus ovatus culture colonies, artificial breeding of small-sized parents and the like, trachinotus ovatus culture germplasm is seriously degraded, disease resistance is weakened, culture performance is reduced and the like. The continuous and healthy development of the trachinotus ovatus breeding industry is severely restricted by the problems, so that the fine breed breeding work of the trachinotus ovatus is urgently needed to be carried out. The molecular marker assisted selective breeding is one of the improved variety breeding methods, the molecular marker tightly linked with the target character gene can be used for carrying out correlation analysis on the target character, the close correlation between the candidate molecular marker and the individual phenotype can be determined, and the breeding period can be further shortened.

Single Nucleotide Polymorphism (SNP) is a genetic marker, and is regarded as a molecular marker with the most development potential due to the characteristics of large quantity, wide distribution, high representativeness, high genetic stability and easy realization of automatic analysis. The SNP is also widely applied and can be used in the aspects of genetic map construction, trait gene association analysis, germplasm identification, genetic relationship analysis, auxiliary breeding and the like, wherein the SNP and trait gene association analysis can not only reveal the connection between the SNP and the genetic traits, but also carry out molecular breeding according to SNP sites and actual breeding requirements, and has a great benefit. The polymorphism of susceptibility/resistance of the trachinotus ovatus MHC II beta gene and the photobacterium mermairei of the trachinotus ovatus is analyzed by the Kyochich et al, and the 3 polymorphic loci of TO-DAB-04, TO-DAB-05 and TO-DAB-10 in the trachinotus ovatus MHC II beta gene are found TO be obviously related TO the susceptibility of the photobacterium mermairei, the TO-DAB-01 locus has obvious relevance TO the photobacterium mermairei resistance, and the TO-DAB-01 locus can provide reference for the practical application of disease-resistant breeding.

At present, less work is carried out on cryptocaryon irritans disease resistant genetic breeding of trachinotus ovatus, SNPs have the advantages of high polymorphism, wide distribution and the like, and have wide application prospect in fish genetic breeding. At present, no report of the gene locus related to the cryptocaryon irritans resistant character of trachinotus ovatus is found.

Disclosure of Invention

The invention aims to provide an SNP molecular marker of properties related to cryptocaryon irritans resistance of trachinotus ovatus and a primer for amplifying the SNP molecular marker.

The invention also aims to provide application of the SNP molecular marker or the primer in identifying or breeding cryptocaryon irritans resistant trachinotus ovatus variety.

The last purpose of the invention is to provide a method for acquiring the SNP molecular marker and a method for identifying the cryptocaryon irritans disease resistant Trachinotus ovatus.

The first object of the present invention can be achieved by the following technical solutions: an SNP molecular marker of cryptocaryon irritans disease-resistant related traits of trachinotus ovatus, wherein the SNP molecular marker is SNP6200 or SNP6237, and the SNP6200 is located in the LAAO gene shown as SEQ ID NO: 1, the base of the base sequence is C or T at the 6200 th position from the 5' end, and the SNP6237 is located in the LAAO gene shown as SEQ ID NO: 1 at position 6237 from the 5' end, wherein the base is G or A.

The SNP molecular marker is obtained by cloning in a trachinotus ovatus LAAO gene, is positioned in an LAAO gene exon, and has a nucleotide sequence shown as SEQ ID NO: 1, two allelic mutations (C/T) and (G/A) exist at the 6200 and 6237 bases of the sequence, respectively, and the two allelic mutations respectively cause tyrosine silencing and glycine to leucine.

In the SNP molecular marker, the TT genotype individual at the 6200 position is more resistant to infection than the CC genotype individual, namely the TT genotype individual at the 6200 position has higher cryptocaryon irritans disease resistance than the CC genotype individual; the AA genotype individual at position 6237 is more resistant than the GG genotype individual, that is, the AA genotype individual at position 6237 has higher cryptocaryon irritans disease resistance than the GG genotype individual.

The invention also provides a primer for amplifying the SNP molecular marker, the primer is a primer pair SNP6200 or SNP6237, and the base sequences of the upstream primer and the downstream primer of the primer pair SNP6200 are respectively shown as SEQ ID NO: 2 and SEQ ID NO: 3, the base sequences of the upstream primer and the downstream primer of the primer pair SNP6237 are respectively shown as SEQ ID NO: 4 and SEQ ID NO: 5, respectively.

Wherein the primer pair SNP6200 is used for amplifying the 6200 th SNP molecular marker, and the primer pair SNP6237 is used for amplifying the 6237 th SNP molecular marker.

Specifically, the method comprises the following steps:

the base sequence of the upstream primer To __ LAAO-G-F1 for amplifying the SNP6200 molecular marker is as follows:

5’-TGAAACGGTAAGACGCTC-3’，

the base sequence of the downstream primer To _ LAAO-G-R1 for amplifying the SNP6200 molecular marker is as follows:

5'-GTCAGACCAGGTGTAGGAA-3' (PCR amplification length is 3841 bp);

the base sequence of the upstream primer To _ LAAO-G-F2 for amplifying the SNP6237 molecular marker is as follows:

5'-CAGCCAGTCAGATAAAGG-3', respectively; the base sequence of the downstream primer To _ LAAO-G-R2 for amplifying the SNP6237 molecular marker is as follows:

5'-CCATAATACCCAAGAACC-3' (PCR amplified length of 926bp)

The second object of the present invention can be achieved by the following technical solutions: the SNP molecular marker or the primer is applied to the identification or breeding of cryptocaryon irritans resistant Trachinotus ovatus strains.

The last object of the present invention can be achieved by the following technical solutions: the method for acquiring the SNP molecular marker comprises the following steps:

(1) extracting genome DNA of trachinotus ovatus individuals;

(2) designing the primer pair SNP6200 or SNP6237 according to the trachinotus ovatus LAAO genome sequence, and carrying out PCR amplification;

(3) detecting by using agarose gel electrophoresis after amplification, sequencing a sample with a uniform band in a gel image, and judging potential SNPs sites according to a sequencing peak image;

(4) the SNPs locus is subjected to genotyping, and two SNP loci exist in an exon of the LAAO gene, and are named as SNP6200 locus and SNP6237 locus respectively.

Wherein:

preferably, in the step (1), a MagenDNA extraction kit (D6310-03B) is used for extracting the genomic DNA of the trachinotus ovatus individual.

Preferably, during the PCR amplification in the step (2), the total volume of the PCR reaction system is 100 μ L: 76 μ L of double distilled water, 10 μ L of 10 XPCR (TaKaRa) buffer (containing Mg)²⁺) 10mmol/L dNTPs 1.5. mu.L, rTaqDNA polymerase (TaKaRa) 1.5. mu.L, forward and reverse primers 3. mu.L each, 100 ng/. mu.L genomic DNA 5. mu.L.

Preferably, in the PCR amplification in step (2), the PCR reaction conditions are as follows: pre-denaturation at 94 ℃ for 4 min; denaturation at 94 ℃ for 30s, annealing at 56 ℃ for 30s, extension at 72 ℃ for 40s, 30 cycles (long fragment >3kb: denaturation at 94 ℃ for 40s, annealing at 56 ℃ for 40s, extension at 72 ℃ for 90s, 30 cycles); extending at 72 deg.C for 10min, and storing at 10 deg.C.

Preferably, 1% (mass percentage) agarose gel electrophoresis is used for detection in step (3).

The invention also provides an identification method of cryptocaryon irritans disease resistant trachinotus ovatus, which comprises the following steps:

(1) extracting the genome DNA of trachinotus ovatus;

(2) carrying out PCR amplification by adopting the primer pair SNP6200 or the primer pair SNP6237 to obtain a PCR product;

(3) and carrying out genotyping on the amplified product, carrying out statistics on the genotype of the SNP locus and the frequency distribution of allele, and then testing the association degree of the SNP locus and the cryptocaryon irritans resistance character to obtain whether the significant difference exists between the SNP locus and the cryptocaryon irritans resistance character.

In the identification method of cryptocaryon irritans disease resistant Trachinotus ovatus, the identification method comprises the following steps:

preferably, in the step (3), the genotype and the frequency distribution of the allele of the SNP site are counted by using Excel 2016, and then the association degree of the SNP site and the cryptocaryon irritans resistance trait is subjected to chi-square test by using SPSS staticiscs 17.0 software to obtain whether the significant difference exists between the SNP site and the cryptocaryon irritans resistance trait.

Preferably, in step (3), the TT genotype individual at SNP6200 site is more resistant to CC genotype individuals (P <0.05), and the AA genotype individual at SNP6237 site is more resistant to GG genotype individuals (P < 0.05).

Preferably, the TT genotype individual at the SNP6200 site and the AA genotype individual at the SNP6237 site in the step (3) are cryptocaryon irritans disease resistant trachinotus ovatus strains.

The invention has the following beneficial effects:

(1) the invention obtains the SNP molecular marker of the character related to the cryptocaryon irritans resistance of the trachinotus ovatus from the LAAO gene screening, and provides a useful genetic marker for the cultivation of disease-resistant varieties of the trachinotus ovatus;

(2) the molecular markers screened by the invention are used for performing correlation analysis on the cryptocaryon irritans resistant disease of trachinotus ovatus, and the two markers can be applied to early screening of trachinotus ovatus breeding materials with disease resistance as a target, so that the breeding efficiency can be effectively improved, and the breeding period can be shortened.

Drawings

FIG. 1 is the sequencing peak of SNP6200 of Trachinotus ovatus in example 1;

FIG. 2 is the sequencing peak of Trachinotus ovatus SNP6237 in example 1.

Detailed Description

The technical solutions of the present invention are described in detail below with reference to specific examples so that those skilled in the art can better understand and implement the technical solutions of the present invention. Reagents or materials used in the examples were commercially available, unless otherwise specified.

Example 1

The SNP molecular marker of the cryptocaryon irritans resistance-related traits of trachinotus ovatus provided by the embodiment is SNP6200 or SNP6237, and the SNP6200 is located in the LAAO gene shown as SEQ ID NO: 1, the base of the base sequence is C or T at the 6200 th position from the 5' end, and the SNP6237 is located in the LAAO gene shown as SEQ ID NO: 1 at position 6237 from the 5' end, wherein the base is G or A.

The LAAO gene is shown as SEQ ID NO: 1, the TT genotype individual at 6200 th of the base sequence is more resistant than the CC genotype individual, namely the TT genotype individual at 6200 th has higher cryptocaryon irritans disease resistance than the CC genotype individual; the AA genotype individual at position 6237 is more resistant than the GG genotype individual, that is, the AA genotype individual at position 6237 has higher cryptocaryon irritans disease resistance than the GG genotype individual.

The primer for amplifying the SNP molecular marker is a primer pair SNP6200 or SNP6237, and the base sequences of the upstream primer and the downstream primer of the primer pair SNP6200 are respectively shown as SEQ ID NO: 2 and SEQ ID NO: 3, the base sequences of the upstream primer and the downstream primer of the primer pair SNP6237 are respectively shown as SEQ ID NO: 4 and SEQ ID NO: 5, respectively.

The SNP molecular marker is obtained by the following steps:

(1) randomly and respectively selecting 10 genome DNAs of trachinotus ovatus individuals, and adopting a MagenDNA extraction kit (D6310-03B);

(2) according To the literature Zhang et al, (2019) the trachinotus ovatus LAAO genomic sequence is adjusted, the genomic sequence primer for amplifying the gene is designed, and the primer is To _ LAAO-G-F1 (the upstream primer for amplifying SNP6200 molecular marker) 5'-TGAAACGGTAAGACGCTC-3' and To _ LAAO-G-R1 (the downstream primer for amplifying SNP6200 molecular marker), 5'-GTCAGACCAGGTGTAGGAA-3' (3841bp, the length of the primer pair SNP6200 amplification) or To _ LAAO-G-F2 (the upstream primer for amplifying SNP6237 molecular marker), 5'-CAGCCAGTCAGATAAAGG-3', To _ LAAO-G-R2 (the downstream primer for amplifying SNP6237 molecular marker), 5'-CCATAATACCCAAGAACC-3' (926bp, the length of the primer pair SNP6237 amplification) are used;

(3) using 100. mu.L of a reaction system (76. mu.L of double distilled water, 10 XPCR (TaKaRa)) 10. mu.L of a buffer solution (containing Mg)²⁺) 10mmol/L dNTPs 1.5. mu.L, rTaqDNA polymerase (TaKaRa) 1.5. mu.L, forward and reverse primers each 3. mu.L, 100 ng/. mu.L genomic DNA 5. mu.L) and PCR reaction conditions: pre-denaturation at 94 ℃ for 4 min; denaturation at 94 ℃ for 30s, annealing at 56 ℃ for 30s, and extension at 72 ℃ for 40s for 30 cycles (long fragment)>3kb, 94 ℃ denaturation for 40s, 56 ℃ annealing for 40s, 72 ℃ extension for 90s, 30 cycles); extending at 72 deg.C for 10min, and storing at 10 deg.C;

(4) detecting by using 1% agarose gel electrophoresis after amplification, sending a sample with a uniform band in a gel image to Guangzhou Rui Boxing Ke biotechnology limited for sequencing, and judging potential SNPs sites according to a sequencing peak image;

the sequencing peak diagram of the SNP6200 of the trachinotus ovatus is shown in figure 1;

the sequencing peak of the trachinotus ovatus SNP6237 is shown in figure 2;

(5) the SNPs sites were genotyped in the above 10 individuals by methods such as PCR sequencing, and as a result, 2 SNP sites were found to exist in the exon of the LAAO gene, which were named SNP6200 and SNP6237, respectively.

Example 2

The method for identifying the cryptocaryon irritans resistance of the trachinotus ovatus by using the SNP molecular marker or the primer comprises the following steps:

(1) selecting the genome DNA of trachinotus ovatus;

(2) carrying out PCR amplification on SNP6200 or SNP6237 by using the primers in the embodiment 1 to obtain a PCR product;

(3) sequencing the PCR product, analyzing the genotype, and judging whether the trachinotus ovatus belongs to the cryptocaryon irritans resistant disease or not according to the difference of the genotypes.

The method specifically comprises the following steps:

selecting healthy trachinotus ovatus 1600 tails, randomly and equally dividing into a control group and an experimental group, and respectively placing the control group and the experimental group at two 20m³The pond is cultured in live seawater, cryptocaryon irritans (600 trophosome/tail) is used for infecting trachinotus ovatus in an experimental group, and the rest culture conditions are consistent with those of a control group. Defining 50 fish died firstly as susceptible group, randomly selecting 50 fish from later alive fish as resistant group, and genotyping the 100 fish.

The genotype and the frequency distribution of the allele of the SNP locus are counted by using Excel 2016, and then the relevance between the SNP locus and the cryptocaryon irritans resistance character is subjected to chi-square test by using SPSS staticiscs 17.0 software to obtain whether the significant difference exists between the SNP locus and the cryptocaryon irritans resistance character. .

As can be seen from the results of association analysis in table 1 below, the TT genotype individuals at SNP6200 sites were more resistant than the CC genotype individuals (P < 0.05); the AA genotype individual at SNP6237 site is more resistant than the GG genotype individual (P < 0.05).

Therefore, individuals with TT genotype at SNP6200 and those with AA genotype at SNP 6237.

TABLE 1 correlation analysis of different genotypes and disease resistance traits of Trachinotus ovatus LAAO gene

Note: different letters indicate significance of difference, P <0.05 indicates significance of difference.

The above embodiments are only used for illustrating the present invention, and the scope of the present invention is not limited to the above embodiments. The object of the present invention can be achieved by those skilled in the art based on the above disclosure, and any improvements and modifications based on the concept of the present invention fall within the protection scope of the present invention, which is defined by the claims.

Sequence listing

<110> research institute for aquatic products in south China sea

<120> SNP molecular marker for cryptocaryon irritans disease resistance-related traits of trachinotus ovatus and application thereof

<160> 5

<170> SIPOSequenceListing 1.0

<210> 1

<211> 7320

<212> DNA

<213> Trachinotus ovatus (Trachinotus ovatus)

<400> 1

gtgaaaattt aaaaattaat ttgcgtctga agtgaaaact tgtgtaactg catgcaaaca 60

ttagccaatt cgcacaaaat acatagtaca actgaggctg attggaatat cattaatttt 120

gcatttattt ggttttaaac ccaagtattg gacacataaa gagtttgacc tgatgttggc 180

actggatgaa tgaaaagtca gaggataacc aaaatcacta gggttcattc aggaaaggtt 240

gaatatcacg gtcaatttaa acactgaata acatcacctt ttcttcatca ttacctcttt 300

tacaaatgtt cacttcaagc agacccaagc ctccgtcctc ctgttggtgg aggaggtggt 360

gtgtcagagt ccagcttcac gtctgtctct gcatctccac tgtagaaaaa ctgtcaggcc 420

atgaacggaa accttgcatc ggtccacagt tttgacgagt atcaacacat tcagtgggtt 480

gtacggtcaa gtgctcagga tgatacgata acttggattg gaggctctga ctgtcaacag 540

gtaatttatc actaaagctc tggtgttaca gagagaacta cacttattga cacatcggtt 600

ctgtcctctc ttgtcctcta ggagagtgct tggctcgact atgatatagt gacccttgac 660

ttcaaactgt agtatgcatt gttgaccagc tgtcccactg aaagattttg taataagttc 720

atgaaaatga taccagaata agttgtttga tatgatttaa acatcagtta cagcagatag 780

tagcagatag ttggttcaca cacagtatca caccacctac agggtttcat acttttattg 840

tctggtaaca ttttcttgaa aatcacaaat cagatcaata ttaaaagaaa aatttgaaat 900

atctgttgaa aatcaaagaa aaaaaattat gtttcagaca agttatatca gcaaacgtat 960

gttcaactca aatagattga gtcaagttct ttatgtgtgt atgtgtgttt acatgtgtgc 1020

gtatgaatga gaaaaaaggg ccagagaaca aatggtcttc ttcaaaaaat gtccctacca 1080

cagataaaaa taaacctgct cccttcatac aagtggtcca ctggacattt gatccataaa 1140

acttgattag tgaaacttca tttaactaag tgtgtgggtg gctgctcatg tcggccatat 1200

ctaaatccac cattgggtgt ggtgttctgt ctcacactaa tgaaatgtat gaagccctta 1260

ctcactttta aagcattgag caaatgtttc cttcagcgat catcagagtt tactttgact 1320

gcttgactac tggctttggg cagtagctga tgtgaaactg gataaagtgg cgttgttagg 1380

ccgacatcat ccttagataa ataccagtga aaacaagtaa tgagttattt ctctcaacat 1440

gaaaaccagg atctgccttt taatatttgg aaatcattta ttgtttgact ttctgtctgt 1500

gtgttgtcac tgtggccttt gttcctggtt ttgtccctgt ttgtcagagt atttaataac 1560

ttttcctatt tctctctgtg tatgtttcag tgacttccac agtcttgggt gttttgtgga 1620

ggaaaaccca gcaggaatta tgaattaaat cctcagaccc catttatcct tgtgttacaa 1680

tcatcagaaa tttgttgttt aatgataacc agaaacatct cagccaagaa gtatcatgtc 1740

aaacaggcaa gagatacttg gggggttgtt atatatatat atgacttata tgacttatgt 1800

cccctgtagt agcctatgac atcatgctac gctatcttat gctatgttat ggtttgttat 1860

cactttgttt gcctttatct tgtttcacta gataaataga aagaaagtca catagagcat 1920

caccgtcaac ttccattgag ggtggggact tgaaacaatg ttctaaaaaa atcatgatga 1980

agagataatt cacttaaaca tttcaagagg ggaattctcc agtggccctg agagctcaat 2040

atactgcaac ctaagaaaac atgcaaatag acaaaaaaca aacaaattaa gaaaaaacct 2100

tcatcagtct gacaacatat gatgcacaac accaaataag aaataaaacc ttatttcctc 2160

aattcagttc attttttaac aggtttctct tgaacacaca gccttgttga tgaagataat 2220

gaagatgatg tcttgttgca ggtgtttttc tggtcatgag acatgaccag ttactcttga 2280

tcatgacagt cagacactga gaaatagtga ttatgatgac cgaaccctga tttaaaaaaa 2340

aaaaacaggg caggaagtca tgcgggcaag ctggatagat aaaagaaatt ccagcacttc 2400

acctcaggtt gatgtgactg caggttttga aacggtaaga cgctctcttt ttatttgaca 2460

ctttatctta gacaatgatt aaaatttcat gatgactaaa taagcataac caagttttag 2520

tattttcttt aactttatga attagttcaa tttctaataa atgtttagat agatagatgg 2580

atgaataagg aacaaaacta attacagata ttacagataa gattataata cagaaactgt 2640

atatctcatc aaagttttca aaatgacatg attacatttg atttccttag atcagctttt 2700

gtgttgttga attcattctg tatttgtttg aatgatatca tcagcaaatt gcatcaaatg 2760

taaatgtatg actttagtat agacattagt gaaacactta tattgttttg tcagaaagag 2820

aagtctggtc tttccaggat tgaaacatgt ctaatatatt ttctcttcct cttcatcctc 2880

ctcatgacac caaagaggga gggaacgtat acctcgtaac tgaaatggag gcgatatgga 2940

aattatgtgg gtatttctaa aaaacaaata ttgtatatgt cagatagata gatagataga 3000

tactttaagg ccagtgacag gacactttaa gcagctgtga ggttggatat ctgtatgaat 3060

gaaacacagt gactgtataa tactgtataa tactgtaagt actgtaagtt gacacttcct 3120

ctcatcagtt ccttcatctc ttccctgtct gtgattaaca tccgctgaat aatgttcaag 3180

ttctgcttta gtcttctagt ctaggtgaag ctggattgcc tgatggtatg atgaaatgag 3240

gagaggtcaa tttttgcggc acttttacag gaatatatgt gacgctgtgt ctagaggaac 3300

ttctgaggaa ctgattgttt ttcgaagcat accttcatgt cagcttcagt tgtctttaaa 3360

cgtgatgtgg acaaggtcaa atacaatcac gtgtctcacg tctagttgct tcacttggct 3420

tttaatctgt caaacactgg caactgtgca acaagtgtac tcaatttaat atccgtggat 3480

atttaacagt taaaagtctt ttggtttaaa ttccttgtcc caataattcc gttctttttc 3540

cttttgttgt gcctccagtt gccgtcaatg tgctgctgct cacactgtac catggccacg 3600

cagccgcagt cagcatgaag gcccatctgg ctgattgtct ggaggacaaa gactacgatg 3660

tgctgctgca cactgtggag accggcctcc cacacctaga gacatctcat catgttgtca 3720

ttgttggagc tggcatggct ggactgacgg ccgccaaact actacaagat gcaggacaca 3780

aggtaacaaa gaggaagaga ttttgacaaa cggctcttat acaatatatt ccctcaaaat 3840

ctgctaaaaa tttcaggagc cacaccaagc actaaccagt tcagttcatg acagtacaaa 3900

gttaaaatta atcaaatcac cacaacataa ttgccatatg ggggccttag gcttcctggc 3960

ttcctttttt tttttttggt atgaatgcaa gtagcagtaa ttctagacag ccagaggtaa 4020

cacatgtaaa acattacaag actggtttta ctcgtattta tccatttgta cttatgtgtt 4080

tgaataaggt aaccatcgta gaggctaata gtcgtgttgg aggacgtgtg gagacataca 4140

ggaatgaaaa agagggctgg tatgctgaac tgggggccat gaggatccca gattctcacc 4200

agtaagttgg agagtttaat ttaaacatgt atatgcagtc tttcgcctct cagactaaca 4260

tgattgacct gcttaacagg attgcccttt ggtttgctaa aaagcttgga gtgaagttga 4320

ataaattcat catggatgac ccgcagacct ttttggttaa tgggcggcgg gagcggacat 4380

acacagtgaa agcaaaccct gatgtcctcg ggtacaaggt agacatagaa tgagaaaggg 4440

aagtcggccg accagctgct acagcaagct ttgcagaagg tacttgagac aaaggaaagg 4500

atggaggtgt caaaaaacac tggaaataaa accacaaacc tactgtttca gcaaagcttc 4560

acattaaacg gctggtcaca caaaaaagtt gcacaactac cctaaggggg ggaaggagct 4620

gagaagaaag tgtgagggag gaatggagag atgggcgaag ggtgattgag ggtgagcttc 4680

atctagtgac aatgaattcc atatcaaatt tcatgacagg caatacaata cctcactgtg 4740

gatgaaaatt ttgaatttta ccgaccgagt ggttttgctt tttgggggct tcagttttct 4800

cttcagtgtt ttgtctgtgc gctccaacct ccaagacctt ccactggttt gtgttttgtg 4860

tcaggcttgg gcatacagta gagttacaca ctcttggttt attgtagaca gatgtcagag 4920

ctcagtctgt gactactcac catagcagca ccagctcaag agataagttg acacatttct 4980

attttctttg ttgtaggtga aagatgaaat ggaggctcat ggctgccagg ctgcgttcaa 5040

aaaatatgac cattattctg tgaaggtaaa gcacaatgtg atccaatgga atgttgtcca 5100

atgagaacac tgtgtgttga ataaatatgt gcatcactac cagtattttg aaacatatca 5160

aataacacaa gttgggtgag ccattttcct tagaaacagt cacctaatgg ttaacttgat 5220

ggatatcata ggacacactt gcttcagctt aaggttttgt ttgcggaacg attttttctg 5280

catgtatctt aatattgact attgtgagtc acataacgtg acctcgaaaa gtacatcaaa 5340

tcagtgttaa aaattaacac aacttttcaa atattagatt tagagaaaag tgttctatgt 5400

cttgtcacat aaaaggccca tattttactc ttattttcca actctgtttt catattttgt 5460

aaaatgctac acaaactgtc aaactattag aactggttga gccatttggc aacctgacta 5520

gtgaaaacat ttcatcaaaa atgtggtttt aacaaatctt tgtttaatag gagtatctga 5580

aagaagaagg acatttgagt tcagaagcag tgagaatgat tggagatctg ctaaatgaac 5640

agagcctcat gtacacagcg ctgactgaga tgctctatga ccaggctgac atcaatgaca 5700

acaccatgta aggcctgaat tctcacaatg aaaactattt aaaatgtaca gaacttcact 5760

tcacattaaa ttggttgctt gaaaaatgca taaaacaatt ctatttctct ttctgttttg 5820

taggtactat gaagtgactg gtgggtcgga ccttctcccc aaagcttttc ttaacgtact 5880

cgatgtccct attttcttga actccaaggt caggcgcatc agccagtcag ataaaggtgt 5940

cgttgtatca taccagacgg gtgaagagtc ttctctgacg aacattcagg cagacgttgt 6000

cctggtaaca accacagcca aagcagccct gttcattgac tttgatccac ctctctctat 6060

cagaaagatg gaggcgctga ggtcagtcca ctatgacagc tccactaaaa tcatcctcac 6120

cttcaacgag acgttctgga cggaggacgg catcaaagga ggaaagagca tcaccgacag 6180

gccctctcat ttcatctact accccagcca cagtttccca aagaacaaga ccatcggcgt 6240

ccttctggct tcctacacct ggtctgacga ctccctcctc ttccaaggag caagtgatga 6300

ggacctgaaa gagctcgttc tgagagattt ggtgaagatc cacggtgagc gggtcaggtc 6360

tcgctgcaca ggggtggtgg tgaagaggtg gacctcagat cctcacagtt tgggcgcctt 6420

tgctctgttc acaccctacc aacatttaga gtactcaagg gagctcttta aacatgaagg 6480

cagggttcac ttcgctggcg aacacacagc cttccctcac gcttggatcg aaacgtctat 6540

gaaatctgcg atcagggctg ctaccaacat caacaaagag gcgcacaaag cagcagctaa 6600

acaccgaggg gagctctagg ctgttaaaat ttaaaaatta cataaaagta ttgtattttt 6660

tcttgttgat tgctttgctt taaggttttt ttttattact gattaatcta cagattattt 6720

gggctgcaag acatctatga aattcaaaat cagagctgtt acaaatatta gcgtgtggtg 6780

gcattgaact cagagtcatt caaatatcca gtgcaagatg agctctaggt tcttgggtat 6840

tatggtatta ataaaagaat aacatttcat tgaatattaa tgtaacctgt ttgagcaata 6900

taaagtgctt gtttcacatt gacttaacaa agaaagataa atgtctccct aaaaatctcc 6960

caaacaactt cttttacata tacattcaca atttacattt ttcctccatc catccattat 7020

ttatatctat ccatctagtg cgtggttgca ggaaactgga gactaacatt gcctggtcac 7080

aaagtctatc acagaggtga catatagaca gacaatcatt cgagctcaca ttaacaccta 7140

caggtcattt taaagtcagg gttgaaccta acagcctgca gatttgaacc cagaacgttt 7200

ttgctgcaaa gtgacaatct tttcttcttg ccttgtttgt ttctacccca gcacctctgt 7260

atcatgcata ataaatcaat gtgatatctg aatcaagctg tgacattttg ttaagtaatg 7320

<210> 2

<211> 18

<212> DNA

<213> Artificial Sequence (Artificial Sequence)

<400> 2

tgaaacggta agacgctc 18

<210> 3

<211> 19

<212> DNA

<213> Artificial Sequence (Artificial Sequence)

<400> 3

gtcagaccag gtgtaggaa 19

<210> 4

<211> 18

<212> DNA

<213> Artificial Sequence (Artificial Sequence)

<400> 4

cagccagtca gataaagg 18

<210> 5

<211> 18

<212> DNA

<213> Artificial Sequence (Artificial Sequence)

<400> 5

ccataatacc caagaacc 18

Claims (9)

1. An SNP molecular marker of properties related to cryptocaryon irritans resistance of trachinotus ovatus, which is characterized in that: the SNP molecular marker is SNP6200 or SNP6237, and the SNP6200 is located in the LAAO gene shown in SEQ ID NO: 1, the base of the base sequence is C or T at the 6200 th position from the 5' end, and the SNP6237 is located in the LAAO gene shown as SEQ ID NO: 1 at position 6237 from the 5' end, wherein the base is G or A.

2. The SNP molecular marker according to claim 1, which is characterized in that: the TT genotype individual at 6200 is more resistant than the CC genotype individual, namely the TT genotype individual at 6200 has higher cryptocaryon irritans disease resistance than the CC genotype individual; the AA genotype individual at position 6237 is more resistant than the GG genotype individual, that is, the AA genotype individual at position 6237 has higher cryptocaryon irritans disease resistance than the GG genotype individual.

3. The primer for amplifying the SNP molecular marker of claim 1, which is characterized in that: the primer is a primer pair SNP6200 or SNP6237, and the base sequences of the upstream primer and the downstream primer of the primer pair SNP6200 are respectively shown as SEQ ID NO: 2 and SEQ ID NO: 3, the base sequences of the upstream primer and the downstream primer of the primer pair SNP6237 are respectively shown as SEQ ID NO: 4 and SEQ ID NO: 5, respectively.

4. The use of the SNP molecular marker of claim 1 or 2 or the primer of claim 3 for identifying or breeding strains of Trachinotus ovatus which are resistant to cryptocaryon irritans.

5. The method for obtaining a SNP molecular marker according to claim 2, which comprises the steps of:

(1) extracting genome DNA of trachinotus ovatus individuals;

(2) designing a primer pair SNP6200 or a primer pair SNP6237 according to the trachinotus ovatus LAAO genome sequence, and carrying out PCR amplification;

(3) detecting by using agarose gel electrophoresis after amplification, sequencing a sample with a uniform band in a gel image, and judging potential SNPs sites according to a sequencing peak image;

(4) the SNPs locus is subjected to genotyping, and two SNP loci exist in an exon of the LAAO gene, and are named as SNP6200 locus and SNP6237 locus respectively.

6. An identification method of cryptocaryon irritans disease resistant Trachinotus ovatus is characterized by comprising the following steps:

(1) extracting the genome DNA of trachinotus ovatus;

(2) carrying out PCR amplification by using the primer pair SNP6200 or the primer pair SNP6237 in the claim 3 to obtain a PCR product;

(3) and carrying out genotyping on the amplified product, carrying out statistics on the genotype of the SNP locus and the frequency distribution of allele, and then testing the association degree of the SNP locus and the cryptocaryon irritans resistance character to obtain whether the significant difference exists between the SNP locus and the cryptocaryon irritans resistance character.

7. The authentication method as claimed in claim 6, wherein: and (3) counting the genotype of the SNP site and the frequency distribution of the allele by using Excel 2016 in the step (3), and then carrying out chi-square test on the association degree of the SNP site and the cryptocaryon irritans resistance by using SPSS staticiscs 17.0 software to obtain whether a significant difference exists between the SNP site and the cryptocaryon irritans resistance.

8. The authentication method as claimed in claim 6, wherein: in the step (3), the TT genotype individual at the SNP6200 site is more resistant to the CC genotype individual (P <0.05), and the AA genotype individual at the SNP6237 site is more resistant to the GG genotype individual (P < 0.05).

9. The authentication method as claimed in claim 6, wherein: and (4) in the step (3), the TT genotype individual at the SNP6200 site and the AA genotype individual at the SNP6237 site are cryptocaryon irritans disease resistant trachinotus ovatus variety.

Images