通过标记辅助回交育种将大豆（Glycine max L. Merr.）中Kunitz胰蛋白酶抑制剂无效等位基因渗入。

Introgression of null allele of Kunitz trypsin inhibitor through marker-assisted backcross breeding in soybean (Glycine max L. Merr.).

作者信息

Maranna Shivakumar, Verma Khushbu, Talukdar Akshay, Lal Sanjay Kumar, Kumar Anil, Mukherjee Keya

机构信息

ICAR- Indian Institute of Soybean Research, Indore, MP, India.

Division of Genetics, ICAR-Indian Agricultural Research Institute, New Delhi, 110012, India.

出版信息

BMC Genet. 2016 Jul 12;17(1):106. doi: 10.1186/s12863-016-0413-2.

DOI:10.1186/s12863-016-0413-2

PMID:27407019

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4943013/

Abstract

BACKGROUND

Presence of Kunitz trypsin inhibitor (KTI) in soybean seeds necessitates pre-heat treatment of the soy-flour for its inactivation before using it in food and feed products. The heat treatment not only enhances processing costs of the soy-based foods and feeds but also affects seed-protein quality and solubility. Genetic elimination of KTI is an important and effective approach. Therefore, molecular marker-assisted backcross breeding (MABB) approach was adopted for genetic elimination of KTI from two popular soybean genotypes, DS9712 and DS9814. PI542044, an exotic germplasm line was used as donor of the kti allele which inhibits functional KTI peptide production.

RESULTS

Foreground selection for the kti allele was performed with three closely linked SSR markers while background selection was done with 93 polymorphic SSR markers. Plants in the BC1F1 generation were found to recover 70.4-87.63 % and 60.26-73.78 % of the recurrent parent genome (RPG) of DS9712 and DS9814, respectively. Similarly, selected plants in the BC2F1 generation had 93.01-98.92 % and 83.3-91.67 % recovery of their respective RPGs. Recombinant selection was performed so as to identify plants with minimal linkage drag. Biochemical analysis of the seeds of the selected plants (ktikti) confirmed absence of KTI peptides in the seeds. Phenotypically, the selected plants were comparable to the respective recurrent parent in yield and other traits.

CONCLUSIONS

MABB approach helped in speedy development of 6 KTI free breeding lines of soybean. Such lines will be suitable for the farmers and the soybean industries to use in production of soy-based foods and feeds without pre-heat treatment of the soy-flour. It would contribute towards wider acceptability of soy-based foods and feeds.

摘要

背景

大豆种子中存在库尼茨胰蛋白酶抑制剂（KTI），因此在将豆粉用于食品和饲料产品之前，需要对其进行预热处理以使其失活。热处理不仅会提高大豆基食品和饲料的加工成本，还会影响种子蛋白的质量和溶解性。从基因上消除KTI是一种重要且有效的方法。因此，采用分子标记辅助回交育种（MABB）方法从两个流行的大豆基因型DS9712和DS9814中基因消除KTI。PI542044，一个外来种质系被用作抑制功能性KTI肽产生的kti等位基因的供体。

结果

使用三个紧密连锁的SSR标记对kti等位基因进行前景选择，同时使用93个多态性SSR标记进行背景选择。发现BC1F1代植株分别恢复了DS9712和DS9814轮回亲本基因组（RPG）的70.4 - 87.63%和60.26 - 73.78%。同样，BC2F1代中所选植株分别恢复了其各自RPG的93.01 - 98.92%和83.3 - 91.67%。进行重组选择以鉴定连锁累赘最小的植株。对所选植株（ktikti）种子的生化分析证实种子中不存在KTI肽。从表型上看，所选植株在产量和其他性状方面与各自的轮回亲本相当。

结论

MABB方法有助于快速培育出6个不含KTI的大豆育种系。这些品系将适合农民和大豆产业用于生产无需对豆粉进行预热处理的大豆基食品和饲料。这将有助于大豆基食品和饲料获得更广泛的接受度。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/97e0/4943013/f1903bbb2865/12863_2016_413_Fig1_HTML.jpg

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通过标记辅助回交育种将大豆（Glycine max L. Merr.）中Kunitz胰蛋白酶抑制剂无效等位基因渗入。

Introgression of null allele of Kunitz trypsin inhibitor through marker-assisted backcross breeding in soybean (Glycine max L. Merr.).

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出版信息

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CONCLUSIONS

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