Your search keyword '"Hong, Huilong"' showing total 2 results

1. Development and utilization of a new chemically-induced soybean library with a high mutation density.

Author

Li, Zhongfeng, Jiang, Lingxue, Ma, Yansong, Wei, Zhongyan, Hong, Huilong, Liu, Zhangxiong, Lei, Jinhui, Liu, Ying, Guan, Rongxia, Guo, Yong, Jin, Longguo, Zhang, Lijuan, Li, Yinghui, Ren, Yulong, He, Wei, Liu, Ming, Htwe, Nang Myint Phyu Sin, Liu, Lin, Guo, Bingfu, and Song, Jian

Subjects

PLANT mutation, PLANT populations, ETHYL methanesulfonate, PLANT morphology, PLANT development

Abstract

Mutagenized populations have provided important materials for introducing variation and identifying gene function in plants. In this study, an ethyl methanesulfonate (EMS)-induced soybean ( Glycine max) population, consisting of 21,600 independent M2 lines, was developed. Over 1,000 M4 (5) families, with diverse abnormal phenotypes for seed composition, seed shape, plant morphology and maturity that are stably expressed across different environments and generations were identified. Phenotypic analysis of the population led to the identification of a yellow pigmentation mutant, g yl, that displayed significantly decreased chlorophyll (Chl) content and abnormal chloroplast development. Sequence analysis showed that gyl is allelic to MinnGold, where a different single nucleotide polymorphism variation in the Mg-chelatase subunit gene ( ChlI1a) results in golden yellow leaves. A cleaved amplified polymorphic sequence marker was developed and may be applied to marker-assisted selection for the golden yellow phenotype in soybean breeding. We show that the newly developed soybean EMS mutant population has potential for functional genomics research and genetic improvement in soybean. [ABSTRACT FROM AUTHOR]

Published

2017

2. Salinity tolerance in soybean is modulated by natural variation in Gm SALT3.

Author

Guan, Rongxia, Qu, Yue, Guo, Yong, Yu, Lili, Liu, Ying, Jiang, Jinghan, Chen, Jiangang, Ren, Yulong, Liu, Guangyu, Tian, Lei, Jin, Longguo, Liu, Zhangxiong, Hong, Huilong, Chang, Ruzhen, Gilliham, Matthew, and Qiu, Lijuan

Subjects

EFFECT of salts on plants, SOYBEAN, PLANT populations, HALOPHYTES, SOIL salinity, SODIUM ions

Abstract

The identification of genes that improve the salt tolerance of crops is essential for the effective utilization of saline soils for agriculture. Here, we use fine mapping in a soybean ( Glycine max (L.) Merr.) population derived from the commercial cultivars Tiefeng 8 and 85-140 to identify Gm SALT3 (salt tolerance-associated gene on chromosome 3), a dominant gene associated with limiting the accumulation of sodium ions (Na+) in shoots and a substantial enhancement in salt tolerance in soybean. Gm SALT3 encodes a protein from the cation/H+ exchanger family that we localized to the endoplasmic reticulum and which is preferentially expressed in the salt-tolerant parent Tiefeng 8 within root cells associated with phloem and xylem. We identified in the salt-sensitive parent, 85-140, a 3.78-kb copia retrotransposon insertion in exon 3 of Gmsalt3 that truncates the transcript. By sequencing 31 soybean landraces and 22 wild soybean ( Glycine soja) a total of nine haplotypes including two salt-tolerant haplotypes and seven salt-sensitive haplotypes were identified. By analysing the distribution of haplotypes among 172 Chinese soybean landraces and 57 wild soybean we found that haplotype 1 (H1, found in Tiefeng 8) was strongly associated with salt tolerance and is likely to be the ancestral allele. Alleles H2-H6, H8 and H9, which do not confer salinity tolerance, were acquired more recently. H1, unlike other alleles, has a wide geographical range including saline areas, which indicates it is maintained when required but its potent stress tolerance can be lost during natural selection and domestication. Gm SALT3 is a gene associated with salt tolerance with great potential for soybean improvement. [ABSTRACT FROM AUTHOR]

Published

2014