CN110878343B - Cpf1 kit for rapidly detecting genetic deafness pathogenic gene SLC26A4 mutation and detection method thereof - Google Patents

Abstract

The invention discloses a Cpf1 kit for quickly detecting genetic deafness pathogenic gene SLC26A4 mutation and a detection method thereof, wherein the Cpf1 kit comprises a Cpf1 detection system; the Cpf1 detection system comprises: a crRNA, cpf1 protein and single stranded DNA reporter system specific for SLC26 A4; the specific crRNA is any one or more of designed and synthesized aiming at mutation sites; the single-chain DNA report system comprises ssDNA FQ reporter used for fluorescence detection of a microplate reader and/or ssDNA DB reporter used for detection of an immune colloidal gold test strip. The method adopts Cpf1 to detect the SLC26A4 gene mutation site for the first time, and has the advantages of high sensitivity, strong specificity, short time consumption, no dependence on large-scale experimental equipment and the like.

Description

Cpf1 kit for rapidly detecting genetic deafness pathogenic gene SLC26A4 mutation and detection method thereof

Technical Field

The invention relates to the field of genetic deafness gene detection, in particular to a rapid detection method and a detection kit for multiple mutation sites of SLC26A4 gene applied to clinical diagnosis of vestibular aqueduct enlargement/Pendred syndrome, belonging to the technical field of biology.

Background

Deafness is a clinically common hearing nervous system deficiency disease, seriously affects the life quality of human beings, causes various deafness, and genetic factors, environmental factors, medicines, wounds, infections and the like can cause the deafness. The incidence of global neonatal deafness is about 1/1000, with more than 50% being caused by genetic factors. In hereditary hearing loss, about 80% of the hereditary hearing loss is autosomal recessive inheritance, although hearing loss genes have higher gene and locus heterogeneity, most of the hereditary hearing loss is caused by a few hot-spot gene mutations, including GJB2 gene, SLC26A4 gene and mitochondrial 12S rRNA gene, etc., which makes the screening of hereditary hearing loss possible.

The large vestibular aqueduct syndrome is a non-syndrome type related autosomal recessive genetic disease, and has the same pathogenic gene as pendred syndrome. In 1997 Everett first reported that the SLC26A4 gene is the causative gene for vestibular aqueduct enlargement/pendred syndrome. The SLC26A4 gene is located in the 7q31 area of autosome, contains 21 exons, the open reading frame is 2343bp, it encodes the multi-transmembrane protein Pendrin containing 780 amino acid residues, the protein mainly consists of hydrophobic amino acids, belongs to a member of the anion transport family SLC26A, and is mainly used for mediating Cl-, HCO ₃ Transport of anions such as OH-. In the inner ear, the Pendrin protein may be able to maintain the ionic balance of lymph fluid by regulating Cl-transport, and it has also been found that the Pendrin protein is involved in coordinating the development of the inner ear. At present, hundreds of mutation sites of SLC26A4 gene are related to deafness, the mutation spectrum and the mutation frequency of different sites are greatly different among different people, and in China, the most common mutation site of SLC26A4 gene is IVS7-2A>G and c.2168A>G, and the like. The clinical manifestations of this deafness associated with SLC26A4 gene mutation are congenital sensorineural or mixed deafness, sometimes fluctuating or progressive, whose fluctuation is often associated with cold or head trauma, or with vertigo.

Currently, no treatment method exists for deafness, and three-level preventive intervention measures for hereditary deafness can be established only by screening carriers of hot spot mutation of deafness genes before pregnancy, noninvasive and invasive prenatal diagnosis during pregnancy and postpartum gene detection. At present, the deafness detection technologies mainly comprise allele specific PCR, microarray gene chips, nucleic acid mass spectrometry, sequencing technologies and the like, and the technologies have high detection flux or high accuracy, but have the defects that the main source of a detection sample is adult venous blood or neonatal heel blood, invasive sampling is adopted, the sample preparation process is complex in operation, the detection time is long, the sequencing cost is high, the data analysis difficulty is high, the sensitivity developed based on the technologies is high, the specificity is high, and rapid and convenient noninvasive detection is few.

CRISPR-Cas (Clustered regulated short palindromic repeats, CRISPRs) is an adaptive immune system in bacteria, and Cas proteins target degradation of foreign nucleic acids through RNA-guided nucleases. Among them, the CRISPR-Cas9 protein family has been widely applied to numerous fields such as gene editing, antiviral agents, biological imaging, and the like. CRISPR-Cas12a (Cpf 1) belongs to Cas enzyme second family and is used to guide RNA-guided cleavage of double stranded DNA into a single RuvC catalytic domain. The Cpf1 enzymes recognize a Thymine (T) nucleotide rich spacer adjacent motif (PAM), catalyze their own guide for CRISPR RNA (crRNA) maturation, and produce PAM distal dsDNA breaks with staggered 5 'and 3' incompliance. When the CRISPR/Cpf1 protein cleaves double-stranded DNA (dsDNA) in a sequence-specific manner, a strong non-specific single-stranded DNA (ssDNA) trans-cleavage activity can be induced. Based on the above characteristics of Cpf1, we developed a rapid and accurate detection method for detecting the mutation sites of hereditary hearing loss in clinical specimens. Genomic dsDNA is extracted from clinical samples to be tested and Recombinase Polymerase Amplification (RPA) is performed under isothermal conditions. The Cpf1-crRNA complex binds to and cleaves the target SLC26A4dsDNA, which activates the trans-cleavage of ssDNA. Fluorescent reporter molecules coupled to ssDNA generate a fluorescent signal upon cleavage. The novel method called DNA endonuclease targeting CRISPR trans-reporter gene provides a powerful platform for quickly and accurately detecting genetic mutation of genetic diseases.

Colloidal gold immunoassay is an efficient technical scheme for clinical rapid detection. When the colloidal gold particle-labeled antibody binds to the corresponding antigen, the colored immunoreactive reagent can be visually detected. The colloidal gold has the characteristics of short detection action time, long-term stable storage and relatively low cost, and the characteristics ensure that the colloidal gold is widely applicable to high specificity, high sensitivity, convenience and quickness in detection aiming at the SLC26A4 mutation site of the deafness gene clinically.

Disclosure of Invention

The invention aims to provide a Cpf1 kit for quick and visual deafness detection with high sensitivity, strong specificity and high speed aiming at the quick detection of clinical hereditary deafness vestibular aqueduct enlargement/pendred syndrome pathogenic gene SLC26A4 mutation site IVS7-2A >, c.2168A >G, c.1174A >and c.1229C >.

In order to achieve the purpose, the invention provides a Cpf1 kit for rapidly detecting multiple sites of a pathogenic gene SLC26A4 of the vestibular aqueduct/pendred syndrome of hereditary deafness, which is characterized by comprising a Cpf1 detection system suitable for mutation of multiple pathogenic sites of the vestibular aqueduct/pendred syndrome.

The Cpf1 detection system comprises: specific crRNA and control crRNA, cpf1 protein and single stranded DNA (ssDNA) reporter system for SLC26A4 gene part mutation sites.

The specific crRNA is any one or more crRNAs designed aiming at SLC26A4 gene mutation sites IVS7-2A >G, c.2168A >G, c.1174A >T and c.1229C >.

The single-stranded DNA (ssDNA) report system comprises ssDNA FQ reporter used for fluorescence detection of a microplate reader and/or ssDNA DB reporter used for detection of an immune colloidal gold test strip; wherein the ssDNA FQ reporter is ssDNA labeled by 6-carboxyfluorescein (6-FAM) and a fluorescence quencher (BHQ 1), and the labeling products are as follows: 5 6FAM/TTTATTT/3BHQ1/, named ssDNA FQ reporter/5 6FAM/TTTATTT/3BHQ1/; the ssDNA DB reporter is ssDNA labeled by Digoxin (Digoxin) and Biotin (Biotin), and the labeling products are as follows: the gene is named ssDNA DB reporter/5Dig/TTTATTT/3Bio/.

Preferably, the Cpf1 kit for rapidly detecting the SLC26A4 gene mutation site of the hereditary hearing loss further comprises an immune colloidal gold test strip; the immune colloidal gold test strip comprises a sample pad, a combination pad, a nitrocellulose membrane, a water absorption pad and a PVC back lining; the sample pad, the combination pad, the nitrocellulose membrane and the absorbent pad are sequentially adhered to the PVC backing; the conjugate of the mouse anti-digoxin antibody marked by colloidal gold is coated on the combination pad; the cellulose nitrate membrane is respectively coated with a quality control line formed by streptavidin and a detection line formed by rabbit anti-mouse IgG antibody.

Preferably, the preparation method of the specific crRNA comprises: aiming at multiple mutation sites IVS7-2A G, c.1174A T, c.1229T and c.2168A G of SLC26A4 gene, a targeting sequence containing cpf1 recognition sequence (PAM) TTTN is searched, crRNA with the length of 23nt is designed and named IVS7-2-G-23, c.1174-T-23, c.1229-T-23 and c.2168-G-23 respectively, after the design is finished, DNA oligo is synthesized and constructed to a vector pGL3-T7-crRNA, and the target crRNA is obtained through in vitro transcription.

The invention also optimizes the Cpf1 detection system to better distinguish normal sites and mutant sites: aiming at the SLC26A4 gene mutation sites c.1229C > T and c.1174A > T, searching a targeting sequence containing a cpf1 recognition sequence TTTN, respectively designing crRNAs with lengths of 17nt,19nt,21nt and 23nt so as to detect the influence of the lengths of the crRNAs on distinguishing normal sites and mutation sites; aiming at SLC26A4 gene mutation sites IVS7-2A >and c.2168A > G sites, a targeting sequence containing a cpf1 recognition sequence TTTN is searched, single point mutation is respectively introduced into different sites of crRNA to detect the influence of additionally introduced single base mutation on distinguishing normal sites and mutation sites, after the design is completed, oligo is synthesized and constructed to a vector LbCpf1-pGL3-T7-crRNA, the target crRNA is obtained through in vitro transcription, and the optimal crRNA for better distinguishing normal sites and mutation sites is found through the design optimization and detection of the crRNA for the detection of a subsequent kit.

Preferably, the preparation method of the control crRNA comprises: according to the first scheme (figure 1), aiming at the mutation site of the SLC26A4 gene, introducing a positive control crRNA near each site, namely IVS7-2-G-ctrl, c.1174-T-ctrl, c.1229T-ctrl and c.2168-G-ctrl respectively, and determining the pure sum and heterozygous types of the detection sample by comparing the ratio of the mutation site and the positive control; according to the second scheme (FIG. 1), two crRNAs are designed for the mutation sites, one On crRNA is completely matched with WT, one Off crRNA is completely matched with the mutation sequence and is named IVS7-2-A-21, IVS7-2-G-21, c.1174-A-21, c.1174-T-21, c.1229-C-21, c.1229-T-21, c.2168-A-21 and c.2168-G-21 respectively, and the type of the detected sample is obtained according to the detection signals of the two crRNAs. After the crRNA design is finished, synthesizing oligo, constructing the oligo into a vector pGL3-T7-crRNA, and obtaining the target crRNA through in vitro transcription.

Preferably, the method of preparing the Cpf1 protein comprises: prokaryotic codon optimization is carried out on a Cpf1 protein nucleic acid sequence to obtain a sequence, a pET28a expression vector is constructed, low-temperature induced soluble protein expression is carried out, and a target protein is obtained through affinity purification and molecular sieve purification.

The Cpf1 kit for rapidly detecting a plurality of mutation sites of the deafness gene SLC26A4 gene provided by the invention can be used for carrying out fluorescence detection by using an enzyme-labeling instrument and can also be used for carrying out detection by using an immune colloidal gold test strip. When the enzyme-linked immunosorbent assay is used for fluorescence detection, a DNA (ssDNA) reporter system in the Cpf1 detection system is ssDNA FQ reporter, and when the enzyme-linked immunosorbent assay is used for detection, a DNA (ssDNA) reporter system is ssDNA DB reporter.

When fluorescence detection is performed by using a microplate reader, when a mutant SLC26A4 gene site exists in the Cpf1 detection system, the endonuclease activity of the Cpf1 protein is specifically activated under the mediation of SLC26A4 specific crRNA. The activated Cpf1 protein cleaves ssDNA FQ reporter labeled with a fluorophore and a quencher, thereby releasing the activated fluorophore, and a fluorescence reading can be detected by using a microplate reader. Correspondingly, when the normal SLC26A4 gene sequence exists in the sample to be detected, the fluorescence reading book is displayed as a base value.

When an immune colloidal gold test strip is used for detection, after a sample to be detected is added into the colloidal gold test strip after Cpf1 is cut, a mouse digoxin antibody marked by colloidal gold is combined with a digoxin-marked ssDNA (single-stranded deoxyribonucleic acid) report system, and a compound moves from a quality control line to a detection line along the direction of liquid flow; the quality control line streptavidin saturation captures a ssDNA report system marked with a biotin label, thereby displaying a strip; when the Cpf1 detects the SLC26A4 mutation site, the ssDNA reporter system labeled with digoxin and biotin is cut off, so that the ssDNA fragment labeled with digoxin is captured and developed by the detection line, and when the Cpf1 detects the normal sequence of the SLC26A4 gene, the ssDNA reporter system labeled with digoxin and biotin cannot be cut off, so that the color captured by the detection line of the ssDNA fragment labeled with digoxin is not developed.

The invention also provides a method for quickly detecting nucleic acids of a plurality of mutation sites of the SLC26A4 gene of deafness, which is characterized in that the kit for quickly detecting the Cpf1 of the nucleic acids of the mutation sites of the SLC26A4 gene related to deafness is adopted.

Preferably, the rapid detection method for the multiple mutation sites of the deafness gene SLC26A4 comprises the following steps:

step a: releasing nucleic acid in a sample to be detected by using a nucleic acid quick release reagent;

step b: amplifying nucleic acid in a sample to be detected by using an isothermal amplification primer: b, adding specific primers SEQ ID NO. 40-SEQ ID NO.45 of different mutation sites of the SLC26A4 into the product obtained in the step a, adding an RPA isothermal amplification system, and reacting at 37 ℃ for 20min for amplification to obtain a specific product;

step c: cleavage of SLC26A4 nucleic acid using Cpf1 detection system: adding the product obtained in the step b into a Cpf1 detection system, and reacting for 30min at 37 ℃;

step d: and detecting the SLC26A4 gene pathogenic site in the sample by using an enzyme-labeling instrument or an immune colloidal gold test strip.

Compared with the prior art, the invention has the beneficial effects that:

(1) The invention realizes high sensitivity, high specificity and rapid visual detection of a plurality of pathogenic mutations of a pathogenic gene SLC26A4 of the hereditary deafness vestibular aqueduct enlargement/pendred syndrome by using Cpf1 specific recognition nucleic acid and combining an immunoassay chromatography technology. According to research findings, when detecting the SLC26A4 gene mutation site, the detection signals of normal persons, deaf patients and carriers are different, and in order to better judge the positive result, two schemes are designed, firstly, a control sequence which does not have the mutation site and SNP and contains a cpf1 recognition sequence (PAM) TTTN is selected near each specific crRNA to be detected, the fluorescence value of the crRNA designed aiming at the mutation site or the gray value of the positive strip of an immune colloidal gold test strip is compared with the control sequence result, and the obtained positive result is judged to be pure patients or mutation carriers according to the ratio; and secondly, designing two crRNAs for the mutation sites respectively, wherein one On crRNA is completely matched with WT, one Off crRNA is completely matched with the mutation sequence, and the type of the detection sample is a pure patient or a mutation carrier is obtained according to detection signals obtained by the two crRNAs.

(2) The invention relates to a rapid detection tool for a pathogenic gene SLC26A4 based on Cpf 1-deafness vestibular aqueduct enlargement/pendred syndrome, which comprises immunochromatography strip detection and can realize convenient and rapid result interpretation.

(3) The invention realizes the rapid, high specificity, high sensitivity and visual detection of the SLC26A4 nucleic acid by using Cpf1 to cut a specific sequence and an immunoassay chromatography technology. Meanwhile, based on designing different crRNA lengths or introducing mutation sites into specific crRNA sequences, the optimal detection signal of the crRNA capable of distinguishing the normal sites from the mutation sites is explored, and the purity and the heterozygosity of SLC26A4 gene mutation are obviously distinguished. The rapid detection method of the SLC26A4 nucleic acid mutation site, which is established by the invention, provides an accurate, rapid, simple and convenient detection method for clinical diagnosis and laboratory research.

(4) The invention discloses a series of Cpf1 reaction systems, crRNA combinations and RPA amplification primers for SLC26A4 nucleic acid detection, wherein the sequences of the Cpf1 reaction systems, the crRNA combinations and the RPA amplification primers are shown as SEQ ID NO.9 to NO.45 in sequence. The Cpf1, crRNA and RPA amplification primer combination can be used for detecting SLC26A4 nucleic acid deafness pathogenic mutation sites IVS7-2A >G, c.1174A >T, c.1229>T, c.2168A >. The invention adopts Cpf1 to detect hereditary hearing loss for the first time, and has the advantages of high sensitivity, strong specificity, short time consumption, high flux, independence on large-scale experimental equipment and the like. These advantages make the Cpf 1-based colloidal gold test strip detection method developed by the invention conveniently used for rapid detection and diagnosis of hereditary hearing loss in laboratories and clinical medicine.

Drawings

FIG. 1 is a schematic diagram of a method for rapidly detecting genetic deafness SLC26A4 nucleic acid pathogenic mutation based on Cpf 1;

FIG. 2 is a specific crRNA design for rapid detection of multiple mutation sites of SLC26A4 nucleic acid based on Cpf 1;

FIG. 3 shows fluorescence detection results of different crRNAs of Cpf1 for detecting SLC26A4 mutation sites;

FIG. 4 influence of crRNA length on fluorescence signal in Cpf1 detection system;

FIG. 5 shows the influence of the introduction of mutation site positions into crRNA in the Cpf1 detection system on fluorescence signals;

FIG. 6 typing of SLC26A4 IVS7-2A > -G site for Cpf1 based on the Cpf1 Rapid detection protocol;

FIG. 7Cpf1 two-pair SLC26A4 IVS7-2A > -G site typing based on the Cpf1 rapid detection protocol.

Detailed Description

The invention will be further illustrated with reference to the following specific examples. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.

In the invention: RPA amplification kit Twist

Basic kit was purchased from twist amp; the crRNA in vitro Transcription cassette MEGAshortscript T7 Transcription Kit and the purification cassette MEGA clear Kit were purchased from Ambion; conventional reagents such as Tris-Base, naCl, tris-HCl, mgCl ₂ BSA and glycerol, etc. were purchased from Thermo Fisher; nucleic acid and ssDNA probe synthesis was done by Nanjing Kinsley; the present invention uses a rapid nucleic acid release agent available from nuozoken to obtain pretreated nucleic acids.

The general technical schematic diagram of the invention is shown in the attached figure 1, and comprises the following 3 parts: preparing a nucleic acid sample to be detected, designing and preparing Cpf1 detection components, constructing a system, designing a fluorescent and colloidal gold test strip and reading results.

Example 1: rapid and sensitive detection of SLC26A4 gene mutation site fragment

1.1 nucleic acid preparation

In this case, the SLC26A2 gene fragment is obtained by referring to the SLC26A4 gene sequence in the NCBI database, designing an amplification primer according to each mutation site, using a human genomic DNA as a template, performing PCR amplification to obtain a target fragment, and then constructing the target fragment on a pUC57 vector by using a homologous recombination method, wherein the target fragment is named as pUC57-IVS7-2-a (SEQ No. 1), pUC57-IVS7-2-G (SEQ No. 2), pUC57-1174-a (SEQ No. 3), pUC57-1174-T (SEQ No. 4), pUC57-1229-C (SEQ No. 5), pUC57-1229-T (SEQ No. 6), pUC57-2168-a (SEQ No. 7), and pUC57-2168- > G (SEQ No. 8). The amplification system is shown in Table 1.

TABLE 1 amplification System for mutant site fragment of SLC26A4 Gene

The reaction system is as follows:

and (4) obtaining a sample and then carrying out the next nucleic acid detection.

Design and preparation of 2SLC26A4 Multi-site specific crRNA

As shown in FIG. 2, the preparation of crRNA was performed according to the following protocol, and the target sequence containing cpf1 recognition sequence (PAM) TTTN was searched for by selecting mutation sites in SLC26A4 gene, and 23 nt-length crRNA was designed and named IVS7-2-G-23, c.1174-T-23, c.1229-T-23, and c.2168-G-23, respectively. After the design is finished, the DNA oligo is synthesized by platinum biotechnology, inc., and is constructed on the carrier LbCpf1-pGL3-T7, and the target crRNA is obtained through in vitro transcription.

The SLC26A4 crRNA provided by the invention comprises SEQ ID NO.9 to SEQ ID NO.12, and the specific information is shown in Table 2.

TABLE 2SLC26A4 Gene-specific crRNA

The detection adopts a 20 mu L system as shown in the table 3, but is not limited to the system, and comprises the following steps of adjusting the proportion of corresponding components:

TABLE 3 detection System for multiple mutation sites cpf1 of SLC26A4

Wherein the ssDNA reporter is ssDNA FQ reporter or ssDNA DB reporter.

1.3 full-wavelength ELIASA fluorescence detection

In the fluorescence detection of the microplate reader, cpf1 is added with various components in sequence to a target gene detection system. The components are mixed evenly and then react for 30min at 37 ℃. Wherein, the concentration of RNase Inhibitors in the reaction system is 40U/. Mu.L, the Cpf1 is 200 ng/. Mu.L, the concentration of ssDNA FQ reporter is 25 pmol/. Mu.L, and the concentration of crRNA is 1 pmol/. Mu.L.

And (4) judging the detection activity of the Cpf1 detection system by using fluorescence detection. The full-wavelength microplate reader was used to measure fluorescence of the detection reaction, monitoring fluorescence kinetics, with an excitation wavelength of 485nm and an emission wavelength of 520nm, with detection every 5 minutes for 2 hours. Taking the fluorescence value detected for 30min as a reaction value. The detection of the SLC26A4 at each site is shown in figure 3, and the invention can realize the ultra-high sensitivity detection of multiple mutation sites of the SLC26A4 by utilizing a fluorescence method result judgment scheme.

1.4 colloidal gold test strip detection

In the detection of the colloidal gold test strip, various components are sequentially added into the Cpf1 target gene detection system. The components are mixed evenly and then react for 30min at 37 ℃. Wherein, the concentration of RNase Inhibitors in the reaction system is 40U/. Mu.L, the Cpf1 is 200 ng/. Mu.L, the concentration of ssDNA DB reporter is 25 pnol/. Mu.L, and the concentration of crRNA is 1 pmol/. Mu.L.

The detection steps of the immune colloidal gold test strip are as follows: mu.L of Cpf1 cleavage product was mixed with 40. Mu.L of colloidal gold dipstick buffer (4 XSSC,2% BSA and 0.05% Tween-20, pH 7.0). The test strip was immersed in the mixture and after 3 minutes of reaction, the results were visually determined and recorded by photography.

Example 2: rapid detection condition optimization of SLC26A4 gene fragment

The rapid detection of the SLC26A4 gene mutation site is helpful for definitely judging the mutation in clinical samples, and has important significance for detecting early deafness. In this embodiment, the IVS7-2A >.

Based on the property that Cpf1 is a highly specific recognition cleavage of a target sequence under crRNA guidance, a hypothesis was proposed: the reduction in the length of the crRNA that precisely pairs with the SLC26A4 gene may result in inefficient recognition by the Cpf1 cleavage system, which is manifested by a somewhat reduced fluorescence value but an increased difference in signal between wild-type and mutant. Based on this principle, we prepared crrnas of different lengths as shown in table 4, comparing the effect of crRNA length matching SLC26A4 gene on the detection signal. In the experiments for detecting the influence of crRNA length on the fluorescence signal value of the C.1229C > T site and the c.1174A > T site of the SLC26A4 gene, the comparison of the results is shown in FIG. 4, and the optimal crRNA length is selected according to the signal difference between the wild type and the mutant type.

TABLE 4 SLC26A4 Gene-specific Length-gradient crRNA

Based on the property that Cpf1 is highly specific for recognition and then cleavage of a target sequence under crRNA guidance, the hypothesis was proposed: if a point mutation is added to the crRNA which is accurately matched with the SLC26A4 gene, the Cpf1 cleavage system cannot be efficiently identified, and the detection shows that although the fluorescence value is reduced to a certain extent, the signal difference between the normal gene and the mutant gene is improved. Based on this principle, we introduced the crRNA at the mismatch site as shown in table 5, comparing the effect of the crRNA length matched to the SLC26A4 gene on the detection signal. In the experiment for detecting the influence of the introduction of crRNA mismatch sites on the fluorescence signal value at the C.2168A > G sites of the SLC26A4 gene, the result alignment is shown in figure 5.

Introduction of point mutation of crRNA into site C.2168

In the fluorescence detection, the components are added in sequence in the Cpf1 detection system. The components are mixed evenly and reacted for 30min at 37 ℃. In the present detection system, crRNA refers to the different crRNA designed as mentioned above. Wherein, the concentration of RNase Inhibitors in the reaction system is 40U/. Mu.L, the Cpf1 is 200 ng/. Mu.L, the concentration of ssDNA DB reporter is 25 pmol/. Mu.L, and the concentration of crRNA is 1 pmol/. Mu.L.

In this embodiment, the Cpf1 detection system is determined for detection activity by fluorescence detection. The full-wavelength microplate reader was used to measure fluorescence of the detection reaction, monitoring fluorescence kinetics, with an excitation wavelength of 485nm and an emission wavelength of 520nm, with detection every 5 minutes for 2 hours. Taking the fluorescence value detected for 30min as a reaction value.

In this example, the assumption of the difference between the length and the wild-type signal and the mutant-type signal is verified by detecting the crRNA signal with a length gradient that is precisely matched with the SLC26A4 gene. The result is shown in fig. 4, the fluorescence signals obtained by crrnas of different SLC26A4 recognition nucleic acid segment lengths are different, and the signal difference of c.1174a > T sites detected for wild-type and mutant sequences is most significant. Based on this, the hypothesis that the influence of crRNAs with different matching lengths on the detection signal can be detected through Cpf1 is verified, and in our detection results, 21nt crRNAs have better fluorescence signal difference, so that the subsequent design and detection of the crRNAs are carried out by using 21 nt. Next, the effect of crRNA that precisely pairs with SLC26A4 gene on fluorescence or dipstick signals was examined by introducing point mutations at different positions of crRNA, verifying the hypothesis that mutations at different positions of crRNA differ in wild-type and mutant signals. As shown in FIG. 5, the fluorescence signals obtained by introducing point mutations at different sites of the crRNA of the SLC26A4 recognition nucleic acid segment are different, and the introduced point mutations have better results in the differentiation of the fluorescence signals at one and two positions (c.2168-G-mut +1, c.2168-G-mut + 2) after the crRNA is mutated by itself. Based on this, the hypothesis that introducing different point mutations in crRNA by Cpf1 detection could more clearly distinguish between wild-type and mutant was verified.

In the detection of the colloidal gold test strip, various components are sequentially added into a Cpf1 detection system. The components are mixed evenly and reacted for 30min at 37 ℃. In the present detection system, crRNA refers to the different crRNA designed as mentioned above. mu.L of Cpf1 cleavage product was mixed with 40. Mu.L of colloidal gold dipstick buffer (4 × SSC,2% BSA and 0.05% Tween-20, pH 7.0). The test strip was immersed in the mixture and after 3 minutes of reaction, the results were visually determined and recorded by photography.

Example 3: rapid and sensitive typing of SLC26A4 gene mutation sites by using scheme

The vestibular aqueduct enlargement/Pendred syndrome is an autosomal recessive genetic disease, and the typing detection of the SLC26A4 gene mutation site of the pathogenic gene is beneficial to definitely judging that a clinical sample is a normal population, a mutation carrier or a deafness patient, and has important significance for detecting early deafness. In this embodiment, the site IVS7-2A > -G of SLC26A4 gene is used as an example to demonstrate that the Cpf1 detection kit of the present invention is applied to typing of deafness-causing sites.

Based on the influence of Cpf1 on cleavage efficiency based on the degree of matching of crRNA to the target sequence, a hypothesis was proposed: selecting a proper control sequence near the IVS7-2A >. Based on this principle, we prepared the control crRNA shown in table 6, and the detection results are shown in fig. 6.

TABLE 6 SLC26A4 Gene-specific control crRNA

In the Cpf1 detection system, the various components were added sequentially. The components are mixed evenly and reacted for 30min at 37 ℃. And (4) judging the detection activity of the Cpf1 detection system by using fluorescence detection. The full-wavelength microplate reader is used for measuring fluorescence of detection reaction and monitoring fluorescence dynamics, wherein the excitation wavelength is 485nm, the emission wavelength is 520nm, detection is carried out once every 5 minutes, and detection lasts for 2 hours. Taking the fluorescence value detected for 30min as a reaction value. The IVS7-2A >in SLC26A4 is cut and detected as shown in figure 4, and the invention can realize the ultrahigh-sensitivity detection and parting of SLC26A4 mutation sites by utilizing a fluorescence method result judging scheme.

In the detection of the colloidal gold test strip, various components are sequentially added into a Cpf1 detection system. The components are mixed evenly and reacted for 30min at 37 ℃. mu.L of Cpf1 cleavage product was mixed with 40. Mu.L of colloidal gold dipstick buffer (4 × SSC,2% BSA and 0.05% Tween-20, pH 7.0). The test strips were immersed in the mixture and after 3 minutes of reaction, photographic recordings and grey value analyses were carried out. The results of the grey value analysis are shown in FIG. 6.

Example 4: rapid and sensitive typing of two pairs of SLC26A4 gene mutation sites by using scheme

In the embodiment, a double crRNA system is adopted, and the site IVS7-2A > -G of SLC26A4 gene is taken as an example to demonstrate that the Cpf1 detection kit disclosed by the invention is applied to typing of deafness pathogenic sites.

Based on the fact that Cpf1 produces significant cleavage signals based on the extent to which crRNA perfectly matches the target sequence, the hypothesis was: aiming at IVS7-2A >. Based on this principle, we prepared crRNA as shown in table 7.

TABLE 7 SLC26A4 Gene-specific control crRNA

In the Cpf1 detection system, the various components were added sequentially. The components are mixed evenly and reacted for 30min at 37 ℃. And (4) judging the detection activity of the Cpf1 detection system by using fluorescence detection. The full-wavelength microplate reader was used to measure fluorescence of the detection reaction, monitoring fluorescence kinetics, with an excitation wavelength of 485nm and an emission wavelength of 520nm, with detection every 5 minutes for 2 hours. Taking the fluorescence value detected for 30min as a reaction value. The invention utilizes a fluorescence method result judgment scheme to realize the ultra-high sensitivity detection and typing of the SLC26A4 mutation site.

In the detection of the colloidal gold test strip, various components are sequentially added into a Cpf1 detection system. The components are mixed evenly and reacted for 30min at 37 ℃. mu.L of Cpf1 cleavage product was mixed with 40. Mu.L of colloidal gold dipstick buffer (4 × SSC,2% BSA and 0.05% Tween-20, pH 7.0). The test strips were immersed in the mixture and after 3 minutes of reaction, photographic recordings and grey value analyses were carried out.

Example 5: rapid detection of SLC26A4 gene mutation site for nucleic acid of clinical blood sample and tissue sample

In this example, the rapid detection of nucleic acids from clinical blood samples or tissue samples was performed in a laboratory, where the samples were obtained from blood samples for Cpf1 detection of DNA. This example uses a rapid nucleic acid release agent from Novomedium to obtain pre-treated nucleic acids. The method comprises the following steps: and adding 20 mu L of nucleic acid lysate into 2 mu L of sample to be detected, standing for 3 minutes at normal temperature, adding 20 mu L of neutralizing solution, mixing uniformly, and carrying out next detection.

By using the RPA amplification primers SEQ NO.40 to SEQ NO.45 of the invention and referring to the RPA isothermal amplification operation steps, 2 μ l of each sample to be detected is taken for RPA pre-amplification to obtain the sample to be detected. The specific operation is as follows:

25 muL of 2 × Buffer,2 muL of RPA-F,2 muL of RPA-R,2.5 muL of magnesium acetate and 2 muL of DNA sample are added with water to be supplemented to 50 muL, the mixture is uniformly mixed and reacted for 20min at 37 ℃, the obtained sample is subjected to next nucleic acid detection, and 2 muL of Buffer, 1 muL of RNase Inhibitors, 1 muL of Cpf1, 1 muL of ssDNA DB reporter, 5 muL of RPA sample, 1 muL of crRNA and 9 muL of H are sequentially added into a Cpf1 detection system ₂ And O. The components are mixed evenly and reacted for 30min at 37 ℃.

In this example, according to the second embodiment, the Cpf1 cleavage product is subjected to colloidal gold test paper result determination. Cpf1 cleavage products were diluted in the colloidal gold assay buffer at a ratio of 1. And judging the test result of the test strip, photographing and storing the test result, and performing gray level analysis on the test result of the colloidal gold test strip. The result shows that the Cpf1 colloidal gold test strip can realize sensitive, rapid and accurate visual detection of multiple deafness related mutation sites of the SLC26A4 gene in clinical blood samples.

Sequence listing

<110> institute of science and technology of the national institute of health and wellness

<120> Cpf1 kit for rapidly detecting genetic deafness pathogenic gene SLC26A4 mutation and detection method thereof

<160> 45

<170> SIPOSequenceListing 1.0

<210> 1

<211> 523

<212> DNA

<213> Artificial Sequence

<400> 1

gcgtgtagca gcaggaagta tataaaatta ttttcttttt atagacgctg gttgagattt 60

ttcaaaatat tggtgatacc aatcttgctg atttcactgc tggattgctc accattgtcg 120

tctgtatggc agttaaggaa ttaaatgatc ggtttagaca caaaatccca gtccctattc 180

ctatagaagt aattgtggta agtagaatat gtagttagaa agttcagcat tatttggttg 240

acaaacaagg aattattaaa accaatggag tttttaacat cttttgtttt atttcagacg 300

ataattgcta ctgccatttc atatggagcc aacctggaaa aaaattacaa tgctggcatt 360

gttaaatcca tcccaagggg gtgagtgtgg tgttcctctt agtactaata cattaagtca 420

gtaagtcagt cttttttatt taaataaaac cttttattac aagcttcatt tcactgatac 480

tccttcaata gtcctatttg tgtgtgatct ggaagaaaca acc 523

<210> 2

<211> 523

<212> DNA

<213> Artificial Sequence

<400> 2

gcgtgtagca gcaggaagta tataaaatta ttttcttttt atagacgctg gttgagattt 60

ttcaaaatat tggtgatacc aatcttgctg atttcactgc tggattgctc accattgtcg 120

tctgtatggc agttaaggaa ttaaatgatc ggtttagaca caaaatccca gtccctattc 180

ctatagaagt aattgtggta agtagaatat gtagttagaa agttcagcat tatttggttg 240

acaaacaagg aattattaaa accaatggag tttttaacat cttttgtttt atttcggacg 300

ataattgcta ctgccatttc atatggagcc aacctggaaa aaaattacaa tgctggcatt 360

gttaaatcca tcccaagggg gtgagtgtgg tgttcctctt agtactaata cattaagtca 420

gtaagtcagt cttttttatt taaataaaac cttttattac aagcttcatt tcactgatac 480

tccttcaata gtcctatttg tgtgtgatct ggaagaaaca acc 523

<210> 3

<211> 560

<212> DNA

<213> Artificial Sequence

<400> 3

tatggcgtcc aaactcctga tgtcgtacaa ggaccccaag tacctatcac ggtaaaaatt 60

aaattggacc accacgcaga gtaggcatgg gagttttcat tcttaatgta cttcctgaaa 120

tactcagcga aggtcttgca aagattcaat ttgtaggatc gttgtcatcc agtctcttcc 180

ttaggaattc attgcctttg ggatcagcaa catcttctca ggattcttct cttgttttgt 240

ggccaccact gctctttccc gcacggccgt ccaggagagc actggaggaa agacacaggt 300

aggaacaaca gccttatgat atccatctca gagaacaagt cgaggaatgg caacagagga 360

aggctcgcac cgagcttagc aggacaattt gcctttcaga cttgtacttc ctaatctgat 420

tcacctcagg cctattcctc ttgttccact ccctcacctg aaatctctta aaaaacaaca 480

tgtatggttt tctgatacag tgattctcaa atctatttgt cagtgcttac ctgtcatgta 540

gctacactta cctgctgtgg 560

<210> 4

<211> 560

<212> DNA

<213> Artificial Sequence

<400> 4

tatggcgtcc aaactcctga tgtcgtacaa ggaccccaag tacctatcac ggtaaaaatt 60

aaattggacc accacgcaga gtaggcatgg gagttttcat tcttaatgta cttcctgaaa 120

tactcagcga aggtcttgca aagattcaat ttgtaggatc gttgtcatcc agtctcttcc 180

ttaggaattc attgcctttg ggatcagcta catcttctca ggattcttct cttgttttgt 240

ggccaccact gctctttccc gcacggccgt ccaggagagc actggaggaa agacacaggt 300

aggaacaaca gccttatgat atccatctca gagaacaagt cgaggaatgg caacagagga 360

aggctcgcac cgagcttagc aggacaattt gcctttcaga cttgtacttc ctaatctgat 420

tcacctcagg cctattcctc ttgttccact ccctcacctg aaatctctta aaaaacaaca 480

tgtatggttt tctgatacag tgattctcaa atctatttgt cagtgcttac ctgtcatgta 540

gctacactta cctgctgtgg 560

<210> 5

<211> 560

<212> DNA

<213> Artificial Sequence

<400> 5

tatggcgtcc aaactcctga tgtcgtacaa ggaccccaag tacctatcac ggtaaaaatt 60

aaattggacc accacgcaga gtaggcatgg gagttttcat tcttaatgta cttcctgaaa 120

tactcagcga aggtcttgca aagattcaat ttgtaggatc gttgtcatcc agtctcttcc 180

ttaggaattc attgcctttg ggatcagcaa catcttctca ggattcttct cttgttttgt 240

ggccaccact gctctttccc gcacggccgt ccaggagagc actggaggaa agacacaggt 300

aggaacaaca gccttatgat atccatctca gagaacaagt cgaggaatgg caacagagga 360

aggctcgcac cgagcttagc aggacaattt gcctttcaga cttgtacttc ctaatctgat 420

tcacctcagg cctattcctc ttgttccact ccctcacctg aaatctctta aaaaacaaca 480

tgtatggttt tctgatacag tgattctcaa atctatttgt cagtgcttac ctgtcatgta 540

gctacactta cctgctgtgg 560

<210> 6

<211> 560

<212> DNA

<213> Artificial Sequence

<400> 6

tatggcgtcc aaactcctga tgtcgtacaa ggaccccaag tacctatcac ggtaaaaatt 60

aaattggacc accacgcaga gtaggcatgg gagttttcat tcttaatgta cttcctgaaa 120

tactcagcga aggtcttgca aagattcaat ttgtaggatc gttgtcatcc agtctcttcc 180

ttaggaattc attgcctttg ggatcagcaa catcttctca ggattcttct cttgttttgt 240

ggccaccact gctctttccc gcatggccgt ccaggagagc actggaggaa agacacaggt 300

aggaacaaca gccttatgat atccatctca gagaacaagt cgaggaatgg caacagagga 360

aggctcgcac cgagcttagc aggacaattt gcctttcaga cttgtacttc ctaatctgat 420

tcacctcagg cctattcctc ttgttccact ccctcacctg aaatctctta aaaaacaaca 480

tgtatggttt tctgatacag tgattctcaa atctatttgt cagtgcttac ctgtcatgta 540

gctacactta cctgctgtgg 560

<210> 7

<211> 516

<212> DNA

<213> Artificial Sequence

<400> 7

ctgtagtcct agctaattgg gagggtgagg tggggggatc acttgaactt gggacgcgga 60

ggttgcagtg agcaatgatg ccactgcact ccagcctggg caatagaatg agactctgtc 120

tcaaaaacaa acaaaaattt cttttcctag gaactaacaa aacattgtgt ctttcttttg 180

aagattatgt gatagaaaag ctggagcaat gcgggttctt tgacgacaac attagaaagg 240

acacattctt tttgacggtc catgatgcta tactctatct acagaaccaa gtgaaatctc 300

aagagggtca aggttccatt ttagaaacgg taaatattca acctttctac agatgtatct 360

tttctaaact atcatgattt ctataaatgg caaacattac acaagtctag tctagctgtt 420

gaattttaag ctacctatat aacttcatgg agcctcagtt ttttcatcag taaaatggaa 480

gtaaaaacat taaccttgct aggtagatat gaagac 516

<210> 8

<211> 516

<212> DNA

<213> Artificial Sequence

<400> 8

ctgtagtcct agctaattgg gagggtgagg tggggggatc acttgaactt gggacgcgga 60

ggttgcagtg agcaatgatg ccactgcact ccagcctggg caatagaatg agactctgtc 120

tcaaaaacaa acaaaaattt cttttcctag gaactaacaa aacattgtgt ctttcttttg 180

aagattatgt gatagaaaag ctggagcaat gcgggttctt tgacgacaac attagaaagg 240

acacattctt tttgacggtc cgtgatgcta tactctatct acagaaccaa gtgaaatctc 300

aagagggtca aggttccatt ttagaaacgg taaatattca acctttctac agatgtatct 360

tttctaaact atcatgattt ctataaatgg caaacattac acaagtctag tctagctgtt 420

gaattttaag ctacctatat aacttcatgg agcctcagtt ttttcatcag taaaatggaa 480

gtaaaaacat taaccttgct aggtagatat gaagac 516

<210> 9

<211> 23

<212> DNA

<213> Artificial Sequence

<400> 9

ggacgataat tgctactgcc att 23

<210> 10

<211> 23

<212> DNA

<213> Artificial Sequence

<400> 10

ggatcagcta catcttctca gga 23

<210> 11

<211> 23

<212> DNA

<213> Artificial Sequence

<400> 11

ccgcatggcc gtccaggaga gca 23

<210> 12

<211> 23

<212> DNA

<213> Artificial Sequence

<400> 12

acggtccgtg atgctatact cta 23

<210> 13

<211> 23

<212> DNA

<213> Artificial Sequence

<400> 13

ccgcatggcc gtccaggaga gca 23

<210> 14

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 14

ccgcatggcc gtccaggaga g 21

<210> 15

<211> 19

<212> DNA

<213> Artificial Sequence

<400> 15

ccgcatggcc gtccaggag 19

<210> 16

<211> 17

<212> DNA

<213> Artificial Sequence

<400> 16

ccgcatggcc gtccagg 17

<210> 17

<211> 23

<212> DNA

<213> Artificial Sequence

<400> 17

ggatcagcta catcttctca gga 23

<210> 18

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 18

ggatcagcta catcttctca g 21

<210> 19

<211> 19

<212> DNA

<213> Artificial Sequence

<400> 19

ggatcagcta catcttctc 19

<210> 20

<211> 17

<212> DNA

<213> Artificial Sequence

<400> 20

ggatcagcta catcttc 17

<210> 21

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 21

acggtgcgtg atgctatact c 21

<210> 22

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 22

acggtcggtg atgctatact c 21

<210> 23

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 23

acggtccgag atgctatact c 21

<210> 24

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 24

acggtccgtc atgctatact c 21

<210> 25

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 25

ggtcgataat tgctactgcc a 21

<210> 26

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 26

ggtcgataat tgctactgcc a 21

<210> 27

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 27

ggaggataat tgctactgcc a 21

<210> 28

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 28

ggaccataat tgctactgcc a 21

<210> 29

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 29

atatggagcc aacctggaaa a 21

<210> 30

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 30

taggatcgtt gtcatccagt c 21

<210> 31

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 31

cctttcagac ttgtacttcc t 21

<210> 32

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 32

taaaatggaa ccttgaccct c 21

<210> 33

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 33

agacgataat tgctactgcc a 21

<210> 34

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 34

ggacgataat tgctactgcc a 21

<210> 35

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 35

ggatcagcaa catcttctca g 21

<210> 36

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 36

ccgcacggcc gtccaggaga g 21

<210> 37

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 37

acggtccatg atgctatact c 21

<210> 38

<211> 21

<212> DNA

<213> Artificial Sequence

<400> 38

acggtccgtg atgctatact c 21

<210> 39

<211> 3744

<212> DNA

<213> Artificial Sequence

<400> 39

agcaagctgg aaaaatttac caactgctac agcctgagca agaccctgcg tttcaaagcg 60

atcccggttg gcaagaccca ggaaaacatt gacaacaaac gtctgctggt tgaggacgaa 120

aagcgtgcgg aggattataa aggtgtgaag aaactgctgg atcgttacta tctgagcttt 180

atcaacgacg tgctgcacag cattaagctg aaaaacctga acaactacat cagcctgttc 240

cgtaagaaaa cccgtaccga gaaggaaaac aaagagctgg aaaacctgga aatcaacctg 300

cgtaaggaga ttgcgaaggc gttcaagggt aacgagggct acaagagcct gttcaagaaa 360

gatatcatcg aaaccatcct gccggagttc ctggacgata aggacgaaat tgcgctggtt 420

aacagcttca acggttttac caccgcgttc accggcttct ttgataaccg tgagaacatg 480

tttagcgagg aagcgaaaag caccagcatc gcgttccgtt gcattaacga aaacctgacc 540

cgttacatca gcaacatgga cattttcgag aaggttgacg cgatctttga taaacacgag 600

gtgcaggaaa tcaaggagaa aattctgaac agcgactatg atgttgaaga tttctttgag 660

ggtgaattct ttaactttgt tctgacccaa gagggcatcg acgtgtacaa cgcgatcatt 720

ggtggcttcg tgaccgaaag cggcgagaag atcaaaggcc tgaacgagta cattaacctg 780

tataaccaga agaccaaaca aaagctgccg aaatttaagc cgctgtataa gcaggtgctg 840

agcgatcgtg aaagcctgag cttctacggc gagggctata ccagcgacga ggaagttctg 900

gaagtgtttc gtaacaccct gaacaaaaac agcgagatct tcagcagcat taagaaactg 960

gaaaagctgt tcaaaaactt tgacgagtac agcagcgcgg gtatctttgt taagaacggc 1020

ccggcgatca gcaccattag caaagatatc ttcggtgaat ggaacgtgat tcgtgacaag 1080

tggaacgcgg agtatgacga tatccacctg aagaaaaagg cggtggttac cgaaaagtac 1140

gaggacgatc gtcgtaaaag cttcaaaaag attggcagct ttagcctgga acagctgcaa 1200

gagtacgcgg acgcggatct gagcgtggtt gaaaaactga aggagatcat tatccagaag 1260

gttgatgaaa tctacaaagt gtatggtagc agcgagaagc tgttcgacgc ggattttgtt 1320

ctggagaaga gcctgaaaaa gaacgacgcg gtggttgcga tcatgaagga cctgctggat 1380

agcgtgaaaa gcttcgaaaa ctacattaag gcgttctttg gtgaaggcaa agagaccaac 1440

cgtgacgaga gcttctatgg cgattttgtt ctggcgtacg acatcctgct gaaggtggac 1500

cacatctacg atgcgattcg taactatgtt acccaaaaac cgtacagcaa ggataagttc 1560

aagctgtact tccagaaccc gcaattcatg ggtggctggg acaaggataa agagaccgac 1620

tatcgtgcga ccatcctgcg ttacggtagc aagtactatc tggcgattat ggataaaaag 1680

tacgcgaaat gcctgcagaa gatcgacaaa gacgatgtta acggtaacta cgaaaagatc 1740

aactacaagc tgctgccggg cccgaacaag atgctgccga aagtgttctt tagcaaaaag 1800

tggatggcgt actataaccc gagcgaggac atccaaaaga tctacaagaa cggtaccttc 1860

aaaaagggcg atatgtttaa cctgaacgac tgccacaagc tgatcgactt ctttaaagat 1920

agcattagcc gttatccgaa gtggagcaac gcgtacgatt tcaactttag cgagaccgaa 1980

aagtataaag acatcgcggg tttttaccgt gaggttgagg aacagggcta taaagtgagc 2040

ttcgaaagcg cgagcaagaa agaggtggat aaactggtgg aggaaggtaa actgtacatg 2100

ttccaaatct acaacaagga cttcagcgat aagagccacg gcaccccgaa cctgcacacc 2160

atgtacttca agctgctgtt tgacgaaaac aaccatggtc agatccgtct gagcggtggc 2220

gcggagctgt tcatgcgtcg tgcgagcctg aagaaagagg agctggttgt gcacccggcg 2280

aacagcccga ttgcgaacaa aaacccggat aacccgaaaa agaccaccac cctgagctac 2340

gacgtgtata aggataaacg ttttagcgaa gaccaatacg agctgcacat tccgatcgcg 2400

attaacaagt gcccgaaaaa catcttcaag attaacaccg aagttcgtgt gctgctgaaa 2460

cacgacgata acccgtatgt tatcggtatt gaccgtggcg agcgtaacct gctgtacatc 2520

gtggttgtgg acggtaaagg caacattgtg gaacagtata gcctgaacga gattatcaac 2580

aactttaacg gtatccgtat taagaccgat taccacagcc tgctggacaa aaaggagaag 2640

gaacgtttcg aggcgcgtca gaactggacc agcatcgaaa acattaagga gctgaaagcg 2700

ggctatatca gccaagttgt gcacaagatt tgcgaactgg ttgagaaata cgatgcggtg 2760

atcgcgctgg aggacctgaa cagcggtttt aagaacagcc gtgttaaggt ggaaaagcag 2820

gtttaccaaa agttcgagaa gatgctgatc gataagctga actacatggt ggacaaaaag 2880

agcaacccgt gcgcgaccgg tggcgcgctg aaaggttatc agattaccaa caagttcgaa 2940

agctttaaaa gcatgagcac ccaaaacggc ttcatctttt acattccggc gtggctgacc 3000

agcaaaatcg atccgagcac cggttttgtt aacctgctga agaccaaata taccagcatt 3060

gcggatagca aaaagttcat cagcagcttt gaccgtatta tgtacgtgcc ggaggaagac 3120

ctgttcgagt ttgcgctgga ctataagaac ttcagccgta ccgacgcgga ctacatcaaa 3180

aagtggaaac tgtacagcta tggtaaccgt atccgtattt tccgtaaccc gaaaaagaac 3240

aacgtttttg actgggagga agtgtgcctg accagcgcgt ataaggaact gttcaacaaa 3300

tacggtatca actatcagca aggcgatatt cgtgcgctgc tgtgcgagca gagcgacaag 3360

gcgttctaca gcagctttat ggcgctgatg agcctgatgc tgcaaatgcg taacagcatc 3420

accggtcgta ccgatgttga ttttctgatc agcccggtga aaaacagcga cggcattttc 3480

tacgatagcc gtaactatga agcgcaggag aacgcgattc tgccgaagaa cgcggacgcg 3540

aacggtgcgt ataacatcgc gcgtaaagtt ctgtgggcga ttggccagtt caaaaaggcg 3600

gaggacgaaa agctggataa ggtgaaaatc gcgattagca acaaagaatg gctggagtac 3660

gcgcaaacca gcgttaagca cgagaacctg tacttccaat cccaccacca ccaccaccac 3720

caccaccacc accaccacca ctga 3744

<210> 40

<211> 20

<212> DNA

<213> Artificial Sequence

<400> 40

tggattgctc accattgtcg 20

<210> 41

<211> 20

<212> DNA

<213> Artificial Sequence

<400> 41

ggttgtttct tccagatcac 20

<210> 42

<211> 15

<212> DNA

<213> Artificial Sequence

<400> 42

gatggtatgg cgtcc 15

<210> 43

<211> 20

<212> DNA

<213> Artificial Sequence

<400> 43

ttcaggtgag ggagtggaac 20

<210> 44

<211> 20

<212> DNA

<213> Artificial Sequence

<400> 44

gctaattggg agggtgaggt 20

<210> 45

<211> 20

<212> DNA

<213> Artificial Sequence

<400> 45

ggaaccttga ccctcttgag 20

Claims (6)

1. A Cpf1 kit for rapidly detecting genetic deafness SLC26A4 gene mutation sites is characterized by comprising a Cpf1 detection system suitable for SLC26A4 gene mutation sites IVS7-2A >G, c.2168A >G, c.1174A >T and c.1229C >;

the Cpf1 detection system comprises: specific crRNA and control crRNA, cpf1 protein and ssDNA reporter systems for multiple sites of the SLC26A4 gene;

the specific crRNA is the crRNA shown in SEQ ID NO.34, SEQ ID NO.23, SEQ ID NO.18 and SEQ ID NO.14 which is designed aiming at SLC26A4 gene mutation site IVS7-2A >G, c.2168A >G, c.1174A > -T, c.1229C > -T;

the control crRNA is a positive control crRNA, the positive control crRNA is a positive control crRNA introduced near the SLC26A4 gene mutation site, and the homozygous and heterozygous types of the detection sample are determined by comparing the ratio of the mutation site to the positive control; the positive control crRNA has the sequences of SEQ ID NO.29, SEQ ID NO.30, SEQ ID NO.31 and SEQ ID NO.32;

the ssDNA report system comprises a ssDNA FQ reporter used for fluorescence detection of a microplate reader and/or a ssDNA DB reporter used for detection of an immune colloidal gold test strip; wherein the ssDNA FQ reporter is ssDNA labeled by 6-carboxyfluorescein and a fluorescence quencher, and the labeling products are as follows: 5 6FAM/TTTATTT/3BHQ1/, named ssDNA FQ reporter/5 6FAM/TTTATTT/3BHQ1/; the ssDNA DB reporter is ssDNA labeled by digoxin and biotin, and the labeling products are as follows: the gene is named ssDNA DB reporter/5Dig/TTTATTT/3 Bio/5 Dig/TTTATTT/3Bio/.

2. The Cpf1 kit for rapidly detecting the SLC26A4 gene mutation site of hereditary hearing loss according to claim 1, further comprising an immune colloidal gold test strip;

the immune colloidal gold test strip comprises a sample pad, a combination pad, a nitrocellulose membrane, a water absorption pad and a PVC back lining; the sample pad, the combination pad, the nitrocellulose membrane and the absorbent pad are sequentially adhered to the PVC backing; the conjugate of the mouse anti-digoxin antibody marked by colloidal gold is coated on the combination pad; the cellulose nitrate membrane is respectively coated with a quality control line formed by streptavidin and a detection line formed by rabbit anti-mouse IgG antibody.

3. The Cpf1 kit for rapid detection of SLC26A4 gene mutation site of hereditary hearing loss according to claim 1, wherein the Cpf1 detection system is optimized to better distinguish the normal site from the mutation site: aiming at C.1229C > T and c.1174A > T of SLC26A4 gene mutation sites, searching a targeting sequence containing a cpf1 recognition sequence TTTN, and respectively designing crRNA with the lengths of 17nt,19nt,21nt and 23nt so as to detect the influence of the length of the crRNA on distinguishing normal sites and mutation sites; aiming at SLC26A4 gene mutation sites IVS7-2A >, G and c.2168A > G sites, searching a targeting sequence containing a cpf1 recognition sequence TTTN, respectively introducing single point mutation at different sites of crRNA to detect the influence of additionally introduced single base mutation on distinguishing normal sites and mutation sites, synthesizing oligo after the design is completed, constructing a vector LbCpf1-pGL3-T7-crRNA, obtaining the target crRNA through in vitro transcription, and finding the optimal crRNA for better distinguishing the normal sites and the mutation sites through the design optimization and detection of the crRNA for the subsequent detection of a kit.

4. The Cpf1 kit for rapidly detecting the SLC26A4 gene mutation site of hereditary hearing loss according to claim 1, wherein the preparation method of the specific crRNA comprises the following steps: aiming at the mutation site of the SLC26A4 gene and respective control sequences, a targeting sequence containing a cpf1 recognition sequence TTTN is searched, crRNA with the length of 21nt is designed, after the design is finished, oligo is synthesized and constructed to a vector LbCpf1-pGL3-T7-crRNA, and the target crRNA is obtained through in vitro transcription.

5. The Cpf1 kit for rapidly detecting the SLC26A4 gene mutation site of hereditary hearing loss according to claim 1, wherein the preparation method of the Cpf1 protein comprises the following steps: prokaryotic codon optimization is carried out on the cpf1 protein nucleic acid sequence to obtain a sequence SEQ NO.39, a pET28a expression vector is constructed, low-temperature induction soluble protein expression is carried out, and the target protein is obtained through affinity purification and molecular sieve purification.

6. A genetic deafness SLC26A4 gene mutation site rapid detection method for non-disease diagnosis and treatment purposes, which is characterized in that a Cpf1 kit used for rapidly detecting the SLC26A4 gene mutation site IVS7-2A >G, c.2168A >G, c.1174A >T, c.122C >;

the rapid detection method of the SLC26A4 gene mutation site comprises the following steps:

step a: releasing nucleic acid in a sample to be detected by using a nucleic acid rapid release reagent;

step b: amplifying nucleic acid in a sample to be detected by using an isothermal amplification primer: b, adding the product obtained in the step a into an RPA isothermal amplification system by using specific primers SEQ NO. 40-SEQ NO.45 of different sites, and reacting at 37 ℃ for 20min for amplification to obtain a specific product;

step c: detecting signals of the SLC26A4 gene mutation site and a control site by using a Cpf1 detection system: adding the product obtained in the step b into a Cpf1 detection system, and reacting for 30min at 37 ℃;

step d: and detecting a detection signal of SLC26A4 gene IVS7-2A >G, c.2168A >G, c.1174A > -T, c.1229C > -T site and a control sequence signal in a sample by using an immune colloidal gold test strip, and performing typing after a ratio is made.

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