CN113736903B - Molecular marker closely linked with rape selenium efficient property main effect QTL locus qSe.C03 and application - Google Patents
Molecular marker closely linked with rape selenium efficient property main effect QTL locus qSe.C03 and application Download PDFInfo
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Abstract
The invention belongs to the technical fields of molecular biology and genetic breeding, and particularly relates to a molecular marker closely linked with a rape selenium high-efficiency trait QTL (quantitative trait locus) site and application thereof. The invention obtains the stable QTL locus for controlling the high-efficiency character of the rape selenium for the first timeqSe.C03And examined a SNP (single nucleotide polymorphism) marker of 11408528 bases on the C03 chromosome of the published and published brassica napus Darmor-bzh v10 genome closely linked to the site, which can explain a phenotypic variation of 10.6%. KASP molecular marker SeC03J designed according to the mutation site, and rape selenium high-efficiency QTL site can be identified by using the markerqSe.C03And (3) rapidly and accurately screening out excellent single plants with higher selenium content.
Description
Technical Field
The invention belongs to the technical fields of molecular biology and genetic breeding, and particularly relates to a molecular marker closely linked with a major QTL locus qSe.C03 of a selenium efficient property of rape and application thereof.
Background
Selenium is an indispensable trace element in human life activities, has various important biological regulation functions, and plays an important role in enhancing organism immunity, improving male reproductive capacity, improving myocardial nutrition, preventing and resisting cancer, delaying aging and the like. The deficiency of selenium intake over a long period of time can lead to a variety of diseases such as keshan disease, osteoarthritis, multiple sclerosis, chronic pancreatitis, etc. The recommended daily selenium intake of adults by the national dietary nutrient reference intake standard (WST 578.3-2017) is 60-400 micrograms.
Selenium-containing plants are the main way for human body to ingest selenium. However, the selenium deficiency phenomenon in the soil environment of China is common, and the selenium content of the produced vegetable food is generally low. Rape has the advantages of high yield of the flowering cabbage, good taste, balanced nutrition, strong regional adaptability and the like, and has become a vegetable product popular with consumers in recent years. And the early-stage research shows that part of rape varieties have the characteristic of high selenium efficiency, namely the high selenium efficiency rape can be enriched with higher selenium content in the same tissue part under the same production environment, namely the selenium enrichment capability of the rape. The rape resources are rich, the genetic diversity is high, so that the potential of 'selenium high efficiency' of the rape is fully explored for breeding improvement, and the method is an effective means for relieving the selenium intake demands of residents in China.
The traditional breeding means is difficult to meet the current crop breeding demands due to long breeding years and low selection efficiency. With the rapid development of molecular biology and sequencing technology, the genotype selection is adopted to accelerate the breeding process, so that the method is widely applied to the breeding of finished product seeds. The molecular marker closely related to the selenium high-efficiency character in rape is detected by using molecular marker auxiliary selection, so that the difficulty in identifying the selenium content phenotype can be overcome, the precise introduction or polymerization of the character can be guided, and the breeding efficiency can be greatly improved. At present, no report that selenium enrichment or selenium high-efficiency character associated sites are identified in rape exists, and related breeding work is still mainly based on traditional large-scale phenotype screening.
The invention aims to find a main effect QTL locus with an improvement effect on the high-efficiency character of the rape selenium through the whole genome association analysis of the content of the rape seed shaft selenium, and develop practical molecular markers based on the main effect QTL locus for marker-assisted selection of the high-efficiency character of the rape selenium.
Disclosure of Invention
The invention aims at providing a molecular marker closely linked with a main effect QTL locus qSe.C03 of selenium efficient property of rape, wherein the molecular marker is an SNP marker and is positioned at 11408528 th base on a C03 chromosome of a published Darmor-bzh v10 genome of brassica napus.
The invention further aims at providing an application of a molecular marker closely linked with a main effect QTL locus qSe.C03 of the selenium-rich efficient property of the rape, and screening and breeding of the selenium-rich capability of the rape can be realized by detecting the 11408528 th base on the C03 chromosome of the Darmor-bzh v10 genome of the cabbage type rape.
In order to achieve the above object, the present invention adopts the following technical measures:
(1) 327 cabbage type rape inbred lines from various countries in the world are collected as rape association groups, individual leaves of each strain of the association groups are collected, total DNA is extracted by a CTAB method, and genotype analysis is carried out on each sample by using a rape 50K Illumina SNP chip developed by Wuhan double green source core science and technology research institute Co.
(2) The marker heterozygosity (heterozygous rate), loss rate (transmission rate), minimum allele frequency (minor allele frequency) of the population material at each locus was calculated using Illumina BeadStudio genotyping software (http:// www.illumina.com /). Filtering SNP markers by taking the unique matching of the deletion rate of less than or equal to 0.2, the heterozygosity rate of less than or equal to 0.2, the minimum allele frequency of more than 0.05 and the SNP markers in the brassica napus Darmor genome (Chalhoub et al, 2014) as screening criteria, and finally obtaining 21,243 high-quality SNP markers for whole genome association analysis.
(3) And importing genotype data of the obtained association analysis population into STRUCTURE v.2.3.4 for population STRUCTURE analysis, and dividing 327 parts of brassica napus germplasm resources into 3 subgroups. The relative relationship between 327 parts of brassica napus germplasm resources was calculated using SPAGeDi software (Hardy and Vekemans, 2002).
(4) 327 parts of materials are respectively planted in Yang Luo test bases of the national academy of agricultural sciences in 2018 and in Yang Luo test bases of the national academy of agricultural sciences in 2019 and in Wuhan test bases of the national academy of agricultural sciences in 2020 and in 9, 3 repeats are respectively arranged in each point test, 15cm rape seed samples are collected in the period from the growth of rape to the bud period (about 40cm in height), and the selenium content of 327 parts of rape seed lines is measured. 5 strains of material were randomly selected for each sample and crushed uniformly, and the total selenium content was determined by hydride atomic fluorescence spectrometry (GB 5009.93-2017).
(5) The association analysis is carried out by using TASSEL 5.0 software (Bradbury et al, 2007) in combination with the selenium content data, genotype data and population structure of 4 test points in 3 years, the SNP marker seq-new-rs42200 which is obviously associated with the selenium content of the rape is detected on a C03 chromosome, the detection can be repeated under a plurality of environments, the highest possible interpretation of the phenotype variation is 10.6%, the obvious level is 6.24E-06, the SNP variation site (variation from C to T) is positioned at 11408528 bases of a C03 genome of the brassica napus Darmor-bzh v10 (Rousseau-Gueutin et al, 2020), and the selenium high-efficiency property main effect QTL site tightly linked with the SNP site is named as qSe.C03.
The application of the reagent for detecting 11408528 th base on C03 chromosome of the Darmor-bzhv 10 genome of brassica napus in screening and breeding of selenium enrichment capability of brassica napus belongs to the protection scope of the invention.
The application of the reagent for detecting the rape sequence containing 11408528 th base on the C03 chromosome of the Darmor-bzhv 10 genome of the brassica napus in screening and breeding of selenium enrichment capability of the rapes also belongs to the protection scope of the invention.
In the above application, it is preferable that the rape sequence is shown in SEQ ID NO. 2.
The application of the primer designed aiming at 11408528 th base on C03 chromosome of the Darmor-bzh v10 genome of the brassica napus in screening and breeding of selenium enrichment capability of the brassica napus also belongs to the protection scope of the invention.
In the above application, the applicant developed the KASP marker SeC03J based on the above SNP site, and designed the primers based on this marker were:
qSe.C03 low selenium enrichment allele specific primer SeC03J-F1: CAGTGATGCTCAAACCAACTTCAC
qSe.C03 high selenium enrichment allele specific primer SeC03J-F2: CAGTGATGCTCAAACCAACTTCAT
Reverse primer SeC03J-R: AAGTGTTAGGTTTGGATTCTGTATAGTG
The primers need to be added with universal joints marked by KASP before use according to the rule of KASP marking development.
Compared with the prior art, the invention has the following advantages:
(1) The invention obtains the main effect QTL locus qSe.C03 obviously related to the high-efficiency character of the rape selenium for the first time, can explain 10.6% of phenotype variation at the highest, can repeatedly detect in a plurality of environments, and can be effectively applied to genetic improvement of the high-efficiency character of the selenium of the rape.
(2) The first research discovers that the molecular marker SeC03J which is obviously related to the high-efficiency character of the rape selenium provides a reliable molecular marker source for the high-efficiency pre-selection of the rape selenium.
(3) The molecular marker SeC03J can be used for rapidly selecting excellent allelic variation of qSe.C03 in rape varieties or lines in the growth period of rape seedlings, so that the workload of breeding and screening can be greatly reduced, the breeding period is shortened, and the efficient breeding process of rape selenium is accelerated.
Detailed Description
The technical scheme of the invention is conventional in the art unless specifically stated; the reagents or materials, unless otherwise specified, are commercially available. In the present invention, unless otherwise specified, the brassica napus genome is referenced to Darmor-bzh v10 (Rousseau-Gueutein et al 2020).
Example 1:
obtaining a main effect QTL locus qSe.C03 of the selenium efficient property of the rape:
(1) 327 cabbage type rape inbred lines from various countries in the world are collected as rape association groups, individual leaves of each strain of the association groups are collected, total DNA is extracted by a CTAB method, and genotype analysis is carried out on each sample by using a rape 50K Illumina SNP chip developed by Wuhan double green source core science and technology research institute Co.
(2) The marker heterozygosity (heterozygous rate), loss rate (transmission rate), minimum allele frequency (minor allele frequency) of the population material at each locus was calculated using Illumina BeadStudio genotyping software (http:// www.illumina.com /). Filtering SNP markers by taking the unique matching of the deletion rate of less than or equal to 0.2, the heterozygosity rate of less than or equal to 0.2, the minimum allele frequency of more than 0.05 and the SNP markers in the brassica napus Darmor genome (Chalhoub et al, 2014) as screening criteria, and finally obtaining 21,243 high-quality SNP markers for whole genome association analysis.
(3) And importing genotype data of the obtained association analysis population into STRUCTURE v.2.3.4 for population STRUCTURE analysis, and dividing 327 parts of brassica napus germplasm resources into 3 subgroups. The relative relationship between 327 parts of brassica napus germplasm resources was calculated using SPAGeDi software (Hardy and Vekemans, 2002).
(4) 327 parts of materials are respectively planted in Yang Luo test bases of the national academy of agricultural sciences in 2018 and in Yang Luo test bases of the national academy of agricultural sciences in 2019 and in Wuhan test bases of the national academy of agricultural sciences in 2020 and in 9, 3 repeats are respectively arranged in each point test, 15cm rape seed samples are collected in the period from the growth of rape to the bud period (about 40cm in height), and the selenium content of 327 parts of rape seed lines is measured. 5 strains of material were randomly selected for each sample and crushed uniformly, and the total selenium content was determined by hydride atomic fluorescence spectrometry (GB 5009.93-2017).
(5) The association analysis is carried out by using TASSEL 5.0 software (Bradbury et al, 2007) in combination with the selenium content data, genotype data and population structure of 4 test points in 3 years, the SNP marker seq-new-rs42200 which is obviously associated with the selenium content of the rape is detected on a C03 chromosome, the detection can be repeated under a plurality of environments, the highest possible interpretation of the phenotype variation is 10.6%, the obvious level is 6.24E-06, the SNP variation site (variation from C to T) is positioned at 11408528 bases of a C03 genome of the brassica napus Darmor-bzh v10 (Rousseau-Gueutin et al, 2020), and the selenium high-efficiency property main effect QTL site tightly linked with the SNP site is named as qSe.C03.
Example 2:
obtaining a molecular marker primer closely linked with a rape selenium efficient main effect QTL locus qSe.C03:
(1) Extracting 100bp sequences of the 11408528 th base upstream and downstream of the brassica napus C03 chromosome, developing a KASP molecular marker SeC03J according to the design principle of a KASP (Kompetitive Allele-Specific PCR, i.e. competitive allele-Specific PCR) molecular marker, wherein the marker comprises two competitive forward primers SeC03J-F1 and SeC03J-F2, which correspond to SNP mutation C and T bases respectively, and a reverse universal primer SeC03J-R, and the primer sequences are as follows:
SeC03J-F1:CAGTGATGCTCAAACCAACTTCAC
SeC03J-F2:CAGTGATGCTCAAACCAACTTCAT
SeC03J-R:AAGTGTTAGGTTTGGATTCTGTATAGTG
the primers need to be added with universal joints marked by KASP before use according to the rule of KASP marking development.
Wherein the sequence of the adaptor added before SeC03J-F1 is GAAGGTCGGAGTCAACGGATT, seC J-F2 and the sequence of the adaptor added before SeC03J-F2 is GAAGGTGACCAAGTTCATGCT.
The amplified sequence in brassica napus 74273 (CN 110476744 a) is genotype a (i.e., genotype CC), and the sequence is shown below:
CAGTGATGCTCAAACCAACTTCACATACACTATACAGAATCCAAACCTAACACTT (SEQ ID NO. 1).
The amplified sequence in double 11 in brassica napus is genotype B (i.e., genotype TT), and the sequence is shown as follows: CAGTGATGCTCAAACCAACTTCATATACACTATACAGAATCCAAACCTAACACTT (SEQ ID NO. 2).
(2) Genotyping the markers in the rape-associated population by adopting a competitive allele-specific PCR technology, and using a five-primer amplified blocked mutation system (PAMS) as an amplification kit, designing a 10uL reaction system according to the instruction of a PAMS pro SNP Gentyping PCR mix kit: 2 XPARMS master mix 5. Mu.L, allle X primer (10. Mu.M) 0.15. Mu.L, allle Y primer (10. Mu.M) 0.15. Mu.L, common R primer (10. Mu.M) 0.4. Mu.L, rape genomic DNA 10-100ng. The amplification procedure was: 94 ℃ for 15min;94 ℃ for 20s,65-57 ℃ (Touch-down) for 1min, and 10 times of circulation; cycling for 30 times at 94 ℃ for 20s and 57 ℃ for 1 min; and collecting 1 fluorescence signal and outputting genotype result. And performing association analysis by using Tassel software to confirm that the marker is obviously associated with the high-efficiency main effect QTL locus qSe.C03 of the brassica napus.
Example 3:
the application of the primer designed based on 11408528 th base of rape C03 chromosome in screening and breeding rape selenium high-efficiency characteristics comprises the following steps:
(1) 32 parts of materials with higher selenium content and lower selenium content, which are homozygous through multi-generation selfing, in 327 parts of materials are selected, 32 parts of materials with higher selenium content and lower selenium content are planted in a male patrol test base of oil crop institute of China academy of agricultural sciences in 9 months in 2020, the selenium content in the soil of the base is about 0.163mg/kg, 3 repeats are arranged for each material, the materials are sampled in a bud period, and the total selenium content of a sample is determined by utilizing a hydride atomic fluorescence spectrometry (GB 5009.93-2017).
(2) Examination of the distribution of the two genotypes of the molecular marker SeC03J in the above-mentioned materials having a high selenium content and a low selenium content revealed that the genotypes of the molecular marker SeC03J were A in 4 parts and B in 28 parts in 32 parts of the materials having a high selenium content, and that the genotypes of the molecular marker SeC03J were A in 22 parts and B in 10 parts in 32 parts of the materials having a low selenium content (Table 1).
(3) The T test result shows that the genotypes A and B detected by the molecular marker SeC03J have extremely obvious difference (P < 0.01) in the selenium content of the rape bolt.
The above results are sufficient to indicate that the prepared molecular marker SeC03J is highly correlated with the selenium content of the brassica napus, so that the method can be used for molecular marker assisted selection of the high-efficiency character of the brassica napus selenium.
Table 1: genotype of molecular marker SeC03J in selenium content extreme material of rape young leaf
Sequence listing
<110> institute of oil crop and oil crop at national academy of agricultural sciences
<120> molecular marker closely linked with main effect QTL locus qSe.C03 of rape selenium high-efficiency character and application thereof
<160> 7
<170> SIPOSequenceListing 1.0
<210> 1
<211> 55
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 1
cagtgatgct caaaccaact tcacatacac tatacagaat ccaaacctaa cactt 55
<210> 2
<211> 55
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 2
cagtgatgct caaaccaact tcatatacac tatacagaat ccaaacctaa cactt 55
<210> 3
<211> 24
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 3
cagtgatgct caaaccaact tcac 24
<210> 4
<211> 24
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 4
cagtgatgct caaaccaact tcac 24
<210> 5
<211> 28
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 5
aagtgttagg tttggattct gtatagtg 28
<210> 6
<211> 21
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 6
gaaggtcgga gtcaacggat t 21
<210> 7
<211> 21
<212> DNA
<213> Artificial sequence (Artificial Sequence)
<400> 7
gaaggtgacc aagttcatgc t 21
Claims (2)
1. Application of primer designed aiming at 11408528bp base on C03 chromosome of cabbage type rape Darmor-bzh v10 genome in screening and breeding of rape selenium enrichment capability.
2. The use according to claim 1, wherein the primers are: seC03J-F1: CAGTGATGCTCAAACCAACTTCAC, seC03J-F2: CAGTGATGCTCAAACCAACTTCAT and SeC03J-R: AAGTGTTAGGTTTGGATTCTGTATAGTG.
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