CN112852994A - KASP marker for detecting properties of fruit tumors of bitter gourds and application thereof - Google Patents

Abstract

The invention relates to a bitter gourd KASP marker, wherein the KASP marker is that C-to-T mutation occurs at the position 21911842 on the chromosome 4 of the bitter gourd genome, and the mutation of the site causes the gene MC04g1395 to form a stop codon, so that the mutation site T or the heterozygous state is tightly linked with the granulomatous state, and the C state is tightly linked with the granulomatous state. Meanwhile, the inventor successfully develops a group of KASP primers and a kit thereof based on the KASP marker, and experiments prove that the detection accuracy of the KASP marker in the genetic progeny material of the balsam pear is 98.15%, and the detection accuracy in the natural germplasm of the balsam pear is 98.39%. The KASP marker detection can be used for screening the bitter gourd fruit tumor characters, can realize high-flux rapid identification of bitter gourd fruit tumor types in the seedling stage, provides effective technical support for bitter gourd molecular breeding, and has important application value.

Description

KASP marker for detecting properties of fruit tumors of bitter gourds and application thereof

Technical Field

The invention relates to the field of molecular biology, in particular to an SNP locus and a KASP marker for detecting the fruit tumor character of balsam pear and application thereof.

Background

The balsam pear is a special vegetable with both nutritive value and medicinal value, is rich in carbohydrate, protein, vitamin, mineral substances and various bioactive components, and can reduce blood sugar, resist oxidation, decompose fat, and inhibit mutagenesis, tumor, etc. It is one of the main products in the winter and spring vegetable off-season market in the areas of the Yangtze east, Guangxi, Hainan, Fujian, Sichuan and Harbour and Australia, in addition to daily consumption in the areas of Guangdong, Guangxi, Hainan, Fujian, Sichuan and Harbour and Australia.

The balsam pears can be roughly divided into types of no tumor, streak tumor, alternate particle and streak, particle tumor, thorn tumor and the like according to the shape of the tumor, in production, the shape of the tumor on the surface of the fruit is an important index for distinguishing the oil melon and the pearl balsam pear, the smooth tumor of the oil melon is the main target, and the crystal clear tumor of the pearl balsam pear is the main target. Therefore, the KASP marker closely linked with the balsam pear fruit tumor characters is developed, the high-flux rapid identification of the type of the balsam pear fruit surface tumor can be realized in the seedling stage, the different balsam pear types of the pearl balsam pear and the oil melon are screened, effective technical support is provided for balsam pear molecular breeding, and the application value is important.

Disclosure of Invention

Based on the above, one of the purposes of the present invention is to provide a KASP marker for detecting the fruit tumor character of momordica charantia, which is used for effectively detecting the fruit tumor character of momordica charantia.

The technical scheme for realizing the purpose is as follows:

a momordica charantia KASP marker, which is a C to T mutation at position 21911842 on chromosome 4 of the genome.

The invention also aims to provide application of the momordica charantia KASP marker in detection of fruit tumor characters and/or auxiliary breeding of momordica charantia.

The invention also aims to provide a bitter gourd fruit tumor character detection method.

The technical scheme for realizing the purpose is as follows:

a method for detecting the traits of fruit tumors of balsam pear, which comprises detecting whether a mutation from C to T occurs at the position 21911842 on the chromosome 4 of a balsam pear genome.

In some embodiments, the detection method includes, but is not limited to, polymerase chain reaction technology, in situ hybridization technology, enzymatic mutation detection technology, chemical shear mismatch technology, mass spectrometry technology, gene chip technology, or gene sequencing technology.

In some of these embodiments, the detection method is a polymerase chain reaction technique, the polymerase chain reaction being any one of RT-PCR, immuno-PCR, nested PCR, fluorescent PCR, in situ PCR, membrane-bound PCR, anchored PCR, in situ PCR, asymmetric PCR, long-range PCR, parachute PCR, gradient PCR.

In some of these embodiments, the detection method is fluorescence PCR, and the detection comprises the steps of:

(1) and obtaining the genomic DNA of the bitter gourd to be detected.

(2) PCR amplification is carried out by using a primer pair shown in a nucleotide sequence SEQ ID NO.3-SEQ ID NO.5 to obtain a product.

(3) And detecting the product in a microplate reader containing 3 channels, reading a fluorescence intensity signal value, and then combining the fluorescence signal value with the labeling information to perform genotyping to obtain a genotype result.

(4) Performing analysis according to the fluorescence signal value, wherein the sample which is polymerized on the X axis and the fluorescence signal of which is blue is a tumor genotype, A genotype; the sample which is polymerized on the Y axis and the fluorescence signal of which is green is the granuloma genotype, B genotype; the samples that polymerized in the middle and the fluorescent signal was red were the interphase genotype, H genotype.

In some embodiments, the detection method is to perform PCR amplification detection by using a genomic DNA of Momordica charantia to be detected as a template and using a primer sequence shown in SEQ ID NO.6-SEQ ID NO.7 as a nucleotide sequence.

The invention also aims to provide a bitter gourd fruit tumor character detection kit.

The technical scheme for realizing the purpose is as follows:

a bitter gourd fruit tumor character detection kit comprises a reagent for detecting whether C-to-T mutation occurs at the 21911842 position on the chromosome 4 of a bitter gourd genome.

A bitter gourd fruit tumor character detection kit comprises a primer combination for detecting the bitter gourd KASP marker, wherein the nucleotide sequence of a forward primer F in the primer combination is shown as SEQ ID No.3, the nucleotide sequence of a reverse primer R1 is shown as SEQ ID No.4, and the nucleotide sequence of a reverse primer R2 is shown as SEQ ID No. 5.

One of the purposes of the invention is to provide the application of the bitter gourd fruit tumor character detection kit in bitter gourd assisted breeding.

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

the inventor finds that the fruit tumor shape of the balsam pear is incompletely dominant, searches an SNP locus variation T/C at 21911842 position on the balsam pear No.4 chromosome, and the mutation of the locus causes the gene MC04g1395 to form a stop codon, thereby showing that the variation locus T is tightly linked with the fruit tumor shape and the C is tightly linked with the fruit tumor shape. Meanwhile, the inventor successfully develops a group of KASP primers and a kit thereof based on the KASP marker, and experiments prove that the detection accuracy of the KASP marker in the genetic progeny material of the balsam pear is 98.15%, and the detection accuracy in the natural germplasm of the balsam pear is 98.39%. The KASP marker detection can be used for screening the bitter gourd fruit tumor characters, can realize high-flux rapid identification of bitter gourd fruit tumor types in the seedling stage, provides effective technical support for bitter gourd molecular breeding, and has important application value.

Drawings

FIG. 1 is a fruit diagram of the parent material in example 1.

FIG. 2 is a gene mapping result of the bitter melon neoplasia in example 1, wherein A is: distribution of two progeny Δ (SNP-index) across the whole genome; b is as follows: distribution of two progeny Δ (SNP-index) on chromosome 4; c is as follows: and (3) finely positioning a bitter melon tumor gene map.

FIG. 3 shows F in example 2₂And 62 parts of bitter gourd material KASP marker gene typing map. Green is the granuloma sample, blue is the streak sample, red is the streak interphase sample, gray is the blank control, and black is the no judgement.

Detailed Description

In order that the invention may be more readily understood, reference will now be made to the following more particular description of the invention, examples of which are set forth below. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. These embodiments are provided so that this disclosure will be thorough and complete. It is to be understood that the experimental procedures in the following examples, where specific conditions are not noted, are generally in accordance with conventional conditions, or with conditions recommended by the manufacturer. The various reagents used in the examples are commercially available.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The present invention relates to abbreviations and terms defined as follows:

BSA-seq: and (5) carrying out mixed pool re-sequencing on extreme characters.

KASP: competitive allele-specific PCR.

SNP: single nucleotide polymorphisms.

Example 1 Momordica charantia fruit tumor trait Gene mapping

1. Experimental Material

The core germplasm of the pearl balsam pear G53-2-1, the oil melon K38 and 62 parts of balsam pear is a core breeding material collected and created by the vegetable research institute of agricultural academy of sciences in Guangdong province.

2. The experimental steps are as follows:

using pearl balsam pear G53-2-1 (granuloma, female parent) and oil melon K38 (streak, male parent) bred and preserved by vegetable research institute of Guangdong province academy of agricultural sciences as parents, and hybridizing to obtain F₁，F₁Selfing to obtain F₂Isolating the population. The parent material has a neoplastic shape as shown in FIG. 1.

Construction of F Using parent Material₂And (5) population and investigation of bitter melon and fruit tumor conditions. F in 92 strains₂In the population, 23 bitter gourds with tumors, 45 bitter gourds with different particle phases and 24 bitter gourds with tumors are separated according to the separation ratio (chi) of 1:2:1²0.065, p 0.97), indicating that the bitter melon granuloma is not completely dominant on the tumor and is controlled by a single gene.

Using F₂20 strains of extreme phenotypes in the population are extracted, DNA mixed pool sequencing is carried out, the difference value delta SNP-index of 2 filial pool SNP-indexes is calculated, 1Mb is selected as a window, 1kb is selected as a step length, the average value of the delta SNP-index in each window is calculated to reflect the distribution of the delta SNP-index, and the bitter melon tumor gene is positioned in the interval of 18.7Mb-23.5Mb (99% confidence level) on the chromosome 4 through BSA-seq. Designing KASP mark in the interval, for F₂615 bitter gourd single plants of the population are genotyped, bitter gourd granuloma genes are positioned to 104.8kb by combining phenotype data, 9 genes exist in the interval, and specifically shown in figure 2, and the gene annotation information is shown in the following table 1.

TABLE 1 Annotation of candidate genes within the localization interval

According to F₂And (4) carrying out genome-wide re-sequencing on the parents, and searching SNP variation sites in the positioning interval. A SNP site variant T/C was found at position 21911842, which resulted in MC04g1395 forming a stop codon.

Example 2 bitter gourd fruit tumor trait KASP marker detection

Based on the marker sequence of the positioning region, based on the sequence of 300bp upstream and downstream of the SNP site, a KASP marker primer is designed by using primer premier5.0 software. Comprises a forward primer, a reverse primer 1 and a reverse primer 2. The two reverse primers have allelic variant bases at the ends, and are G/A. The 5' end of the reverse primer is connected with fluorescent tag sequences A and B, wherein the 5' end of the reverse primer 1 is connected with a fluorescent tag sequence B with a HEX group, a sequence 5'-GAAGGTGACCAAGTTCATGCT-3' (SEQ ID NO.1), the 5' end of the reverse primer 2 is connected with a fluorescent tag sequence A with a FAM group, a sequence 5'-GAAGGTCGGAGTCAACGGATT-3' (SEQ ID NO.2), and the primer sequences are specifically as follows: f: GCCTGAAGAGGTTGGGAATC (SEQ ID NO.3)

R1：GAAGGTGACCAAGTTCATGCTGAGAAGTTGTTTTCATACGACTGG(SEQ ID NO.4)

R2：GAAGGTCGGAGTCAACGGATTCAGAGAAGTTGTTTTCATACGACTGA(SEQ ID NO.5)

By F₂And (4) verifying the population and 62 parts of bitter gourd germplasm materials. Take F₂Young leaves of the colony sample are subjected to CTAB extraction to obtain genomic DNA of balsam pear, and PCR amplification is carried out by using the primer group, wherein the PCR reaction system is 10 mu L, and the PCR reaction system comprises 2 xKASP master mix 5 mu L, forward primer 0.4 mu L, reverse primer R10.15 mu L, reverse primer R20.15 mu L, DNA (10-100ng)1 mu L, ddH₂O3.3. mu.L. The PCR reaction program is 94 ℃ for 15 min; 94 ℃, 20s, 65-57 ℃ (Touch down), 1min, 10 cycles; 94 ℃, 20s, 57 ℃, 1min, 30 cycles. The fluorescent signal is read by a TECAN _ SNInfinite M1000 microplate reader, the converted fluorescent signal is analyzed by online software snpdecoder (http:// www.snpway.com/snpdecoder /), a clear and visual parting diagram is obtained, and genotype result detection is output according to different colors. Wherein the sample polymerized on the X axis and the fluorescence signal of which is blue is the genotype of the tumor streak, genotype A; the sample which is polymerized on the Y axis and the fluorescence signal of which is green is the granuloma genotype, B genotype; samples that aggregated in the middle and the fluorescence signal was red were the streak interphase genotype, H-based.

At 108 strains F₂The detection results of the individual plants and 62 bitter gourd germplasm resources are shown in figure 3. F₂A, B and H3 genotypes exist in random individuals of the population, and the A: B: H ═ 23:31:54 strains. 62 parts of balsam pear material, A, B, H, 34, 25 and 3. Simultaneously, the sequence development is carried out according to the sequence of 300bp around the variation siteCommon primer, primer sequence F3: TTGACTGGAGAAATCCCACC (SEQ ID NO.6), R3: TGTCTTGCACTCAGAAAAGG (SEQ ID NO.7), performing PCR amplification in a PCR system of 50. mu.L: DNA template 2. mu.L, 2 XPCRmix 25. mu.L, forward primer F32. mu.L, reverse primer R32. mu.L, ddH₂O19. mu.L. The PCR amplification procedure was: 94 ℃ for 5 min; 30 cycles of 94 ℃, 30s, 52 ℃, 30s, 72 ℃, 30 s; extension at 72 ℃ for 5 min. Then, the sequencing was performed (Compton Bioengineering (Shanghai) Co., Ltd.) and the sequencing result completely coincided with the KASP labeling result. The KASP marker detection result is proved to be accurate.

Combining the phenotypic and genotypic analyses of the material to be tested, F₂Only 2 individuals in 108 individuals in the population are incompatible with the genotype and the phenotype, the phenotypes of other individuals with the same genotype as K38 are the streak tumors, and the genotype with the same or heterozygous with G53-2-1 is expressed as the streak tumors or the streak particles, and the detection accuracy is 98.15%. Only 1 of 62 bitter gourd resources with different sources and types has incompatible phenotype and genotype, and the detection accuracy is 98.39%. Therefore, the base of the SNP variation site discovered by the inventor is T which is closely linked with the tumor shape, C which is closely linked with the tumor shape, and the KASP marker can be used for screening the characteristics of the tumors on the surface of the balsam pear fruit.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

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Claims (10)

1. A momordica charantia KASP marker, wherein the KASP marker is a C to T mutation at position 21911842 on chromosome 4 of the momordica charantia genome.

2. The use of a bitter gourd KASP marker according to claim 1 for the detection of a gomphostema trait and/or for assisted breeding.

3. A method for detecting the fruit tumor character of balsam pear, which is characterized by detecting whether the mutation from C to T occurs at the 21911842 position on the chromosome 4 of the balsam pear genome.

4. The detection method of claim 3, wherein the detection method comprises, but is not limited to, polymerase chain reaction technology, in situ hybridization technology, enzymatic mutation detection technology, chemical shear mismatch technology, mass spectrometry technology, gene chip technology, or gene sequencing technology.

5. The detection method according to claim 4, wherein the detection method is a polymerase chain reaction technique, and the polymerase chain reaction is any one of RT-PCR, immuno-PCR, nested PCR, fluorescence PCR, in situ PCR, membrane-bound PCR, anchored PCR, anchor PCR, in situ PCR, asymmetric PCR, long-range PCR, parachute PCR, and gradient PCR.

6. The detection method according to claim 5, wherein the detection method is fluorescence PCR, and the detection comprises the following steps:

(1) obtaining the genomic DNA of the bitter gourd to be detected;

(2) carrying out PCR amplification by using a primer pair shown in a nucleotide sequence SEQ ID NO.3-SEQ ID NO.5 to obtain a product;

(3) detecting the product in an enzyme-labeling instrument containing 3 channels, reading a fluorescence intensity signal value, and then combining the fluorescence signal value with labeling information to perform genotyping to obtain a genotype result;

(4) performing analysis according to the fluorescence signal value, wherein the sample which is polymerized on the X axis and the fluorescence signal of which is blue is a tumor genotype, A genotype; the sample which is polymerized on the Y axis and the fluorescence signal of which is green is the granuloma genotype, B genotype; the samples that polymerized in the middle and the fluorescent signal was red were the interphase genotype, H genotype.

7. The detection method according to claim 5, wherein the detection method comprises performing PCR amplification detection by using a genomic DNA of Momordica charantia to be detected as a template and using a primer sequence having a nucleotide sequence shown as SEQ ID No.6-SEQ ID No. 7.

8. A bitter gourd fruit tumor character detection kit is characterized by comprising a reagent for detecting whether C-to-T mutation occurs at the 21911842 position on the chromosome 4 of a bitter gourd genome.

9. The detection kit according to claim 8, wherein the detection kit comprises a primer combination for detecting the bitter gourd KASP marker of claim 1, wherein the nucleotide sequence of the forward primer F is shown as SEQ ID No.3, the nucleotide sequence of the reverse primer R1 is shown as SEQ ID No.4, and the nucleotide sequence of the reverse primer R2 is shown as SEQ ID No. 5.

10. Use of a test kit according to any one of claims 8 to 9 in assisted breeding of momordica charantia.

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