Your search keyword '"Jiang, Bingjun"' showing total 8 results

1. Field-based screening and haplotyping of J locus for long juvenile trait in tropical soybean genotypes

Author

Sapey, Enoch, Fang, Yudong, Khojely, Dalia Mohamedkheir, Song, Wenwen, Jiang, Bingjun, Yuan, Shan, Sun, Shi, and Han, Tianfu

Published

2021

2. GmTCP40 Promotes Soybean Flowering under Long-Day Conditions by Binding to the GmAP1a Promoter and Upregulating Its Expression.

Author

Zhang, Lixin, Wang, Peiguo, Wang, Miao, Xu, Xin, Jia, Hongchang, Wu, Tingting, Yuan, Shan, Jiang, Bingjun, Sun, Shi, Han, Tianfu, Wang, Liwei, and Chen, Fulu

Subjects

GENE expression, FLOWERING time, FLOWERING of plants, HAPLOTYPES, SOYBEAN, MOLECULAR cloning

Abstract

Soybean [Glycine max (L.) Merr.] is a short-day (SD) plant that is sensitive to photoperiod, which influences flowering, maturity, and even adaptation. TEOSINTE-BRANCHED1/CYCLOIDEA/PROLIFERATING CELL FACTOR (TCP) transcription factors have been shown to regulate photoperiodic flowering. However, the roles of TCPs in SD plants such as soybean, rice, and maize remain largely unknown. In this study, we cloned the GmTCP40 gene from soybean and investigated its expression pattern and function. Compared with wild-type (WT) plants, GmTCP40-overexpression plants flowered earlier under long-day (LD) conditions but not under SD conditions. Consistent with this, the overexpression lines showed upregulation of the flowering-related genes GmFT2a, GmFT2b, GmFT5a, GmFT6, GmAP1a, GmAP1b, GmAP1c, GmSOC1a, GmSOC1b, GmFULa, and GmAG under LD conditions. Further investigation revealed that GmTCP40 binds to the GmAP1a promoter and promotes its expression. Analysis of the GmTCP40 haplotypes and phenotypes of soybean accessions demonstrated that one GmTCP40 haplotype (Hap6) may contribute to delayed flowering at low latitudes. Taken together, our findings provide preliminary insights into the regulation of flowering time by GmTCP40 while laying a foundation for future research on other members of the GmTCP family and for efforts to enhance soybean adaptability. [ABSTRACT FROM AUTHOR]

Published

2024

3. Haplotype Analysis of GmSGF14 Gene Family Reveals Its Roles in Photoperiodic Flowering and Regional Adaptation of Soybean.

Author

Jiang, Liwei, Wang, Peiguo, Jia, Hongchang, Wu, Tingting, Yuan, Shan, Jiang, Bingjun, Sun, Shi, Zhang, Yuxian, Wang, Liwei, and Han, Tianfu

Subjects

GENE families, HAPLOTYPES, FLOWERING time, SOYBEAN, FRAMESHIFT mutation, DISEASE resistance of plants

Abstract

Flowering time and photoperiod sensitivity are fundamental traits that determine soybean adaptation to a given region or a wide range of geographic environments. The General Regulatory Factors (GRFs), also known as 14-3-3 family, are involved in protein–protein interactions in a phosphorylation-dependent manner, thus regulating ubiquitous biological processes, such as photoperiodic flowering, plant immunity and stress response. In this study, 20 soybean GmSGF14 genes were identified and divided into two categories according to phylogenetic relationships and structural characteristics. Real-time quantitative PCR analysis revealed that GmSGF14g, GmSGF14i, GmSGF14j, GmSGF14k, GmSGF14m and GmSGF14s were highly expressed in all tissues compared to other GmSGF14 genes. In addition, we found that the transcript levels of GmSGF14 family genes in leaves varied significantly under different photoperiodic conditions, indicating that their expression responds to photoperiod. To explore the role of GmSGF14 in the regulation of soybean flowering, the geographical distribution of major haplotypes and their association with flowering time in six environments among 207 soybean germplasms were studied. Haplotype analysis confirmed that the GmSGF14mH4 harboring a frameshift mutation in the 14-3-3 domain was associated with later flowering. Geographical distribution analysis demonstrated that the haplotypes related to early flowering were frequently found in high-latitude regions, while the haplotypes associated with late flowering were mostly distributed in low-latitude regions of China. Taken together, our results reveal that the GmSGF14 family genes play essential roles in photoperiodic flowering and geographical adaptation of soybean, providing theoretical support for further exploring the function of specific genes in this family and varietal improvement for wide adaptability. [ABSTRACT FROM AUTHOR]

Published

2023

4. Polymorphism analysis of the chloroplast and mitochondrial genomes in soybean.

Author

Yue, Yanlei, Li, Jiawen, Sun, Xuegang, Li, Zhen, and Jiang, Bingjun

Subjects

CHLOROPLAST DNA, MITOCHONDRIAL DNA, HAPLOTYPES, ORGANELLES, CYTOPLASM

Abstract

Background: Soybean is an important protein- and oil-rich crop throughout the world. Much attention has been paid to its nuclear genome, which is bi-parentally inherited and associated with many important agronomical traits. However, less is known about the genomes of the semi-autonomous and essential organelles, chloroplasts and mitochondria, of soybean. Results: Here, through analyzing the polymorphisms of these organelles in 2580 soybean accessions including 107 wild soybeans, we found that the chloroplast genome is more variable than the mitochondrial genome in terms of variant density. Consistent with this, more haplotypes were found in the chloroplast genome (44 haplotypes) than the mitochondrial genome (30 haplotypes). These haplotypes were distributed extremely unevenly with the top two haplotypes (CT1 and CT2 for chloroplasts, MT1 and MT2 for mitochondria) accounting for nearly 70 and 18% of cultivated soybean accessions. Wild soybeans also exhibited more diversity in organelle genomes, harboring 32 chloroplast haplotypes and 19 mitochondrial haplotypes. However, only a small percentage of cultivated soybeans shared cytoplasm with wild soybeans. In particular, the two most frequent types of cytoplasm (CT1/MT1, CT2/MT2) were missing in wild soybeans, indicating that wild soybean cytoplasm has been poorly exploited during breeding. Consistent with the hypothesis that soybean originated in China, we found that China harbors the highest cytoplasmic diversity in the world. The geographical distributions of CT1–CT3 and MT1–MT3 in Northeast China were not significantly different from those in Middle and South China. Two mitochondrial polymorphism sites, p.457333 (T > C) and p.457550 (G > A), were found to be heterozygous in most soybeans, and heterozygosity appeared to be associated with the domestication of cultivated soybeans from wild soybeans, the improvement of landraces to generate elite cultivated soybeans, and the geographic adaptation of soybean. Conclusions: The haplotypes of thousands of soybean cultivars should be helpful in evaluating the impact of cytoplasm on soybean performance and in breeding cultivars with the desired cytoplasm. Mitochondrial heterozygosity might be related to soybean adaptation, and this hypothesis needs to be further investigated. [ABSTRACT FROM AUTHOR]

Published

2023

5. Genomic Dissection and Diurnal Expression Analysis Reveal the Essential Roles of the PRR Gene Family in Geographical Adaptation of Soybean.

Author

Wang, Peiguo, Wang, Liwei, Zhang, Lixin, Wu, Tingting, Sun, Baiquan, Zhang, Junquan, Sapey, Enoch, Yuan, Shan, Jiang, Bingjun, Chen, Fulu, Wu, Cunxiang, Hou, Wensheng, Sun, Shi, Bai, Jiangping, and Han, Tianfu

Subjects

GENE families, NONSENSE mutation, HAPLOTYPES, CIRCADIAN rhythms, PLANT development, DELETION mutation, CLOCK genes, SOYBEAN

Abstract

Pseudo-response regulator (PRR) family members serve as key components of the core clock of the circadian clock, and play important roles in photoperiodic flowering, stress tolerance, growth, and the development of plants. In this study, 14 soybean PRR genes were identified, and classified into three groups according to phylogenetic analysis and structural characteristics. Real-time quantitative PCR analysis revealed that 13 GmPRRs exhibited obvious rhythmic expression under long-day (LD) and short-day (SD) conditions, and the expression of 12 GmPRRs was higher under LD in leaves. To evaluate the effects of natural variations in GmPRR alleles on soybean adaptation, we examined the sequences of GmPRRs among 207 varieties collected across China and the US, investigated the flowering phenotypes in six environments, and analyzed the geographical distributions of the major haplotypes. The results showed that a majority of non-synonymous mutations in the coding region were associated with flowering time, and we found that the nonsense mutations resulting in deletion of the CCT domain were related to early flowering. Haplotype analysis demonstrated that the haplotypes associated with early flowering were mostly distributed in Northeast China, while the haplotypes associated with late flowering were mostly cultivated in the lower latitudes of China. Our study of PRR family genes in soybean provides not only an important guide for characterizing the circadian clock-controlled flowering pathway but also a theoretical basis and opportunities to breed varieties with adaptation to specific regions and farming systems. [ABSTRACT FROM AUTHOR]

Published

2022

6. Soybean adaption to high‐latitude regions is associated with natural variations of GmFT2b, an ortholog of FLOWERING LOCUS T.

Author

Chen, Li, Cai, Yupeng, Qu, Mengnan, Wang, Liwei, Sun, Hongbo, Jiang, Bingjun, Wu, Tingting, Liu, Luping, Sun, Shi, Wu, Cunxiang, Yao, Weiwei, Yuan, Shan, Han, Tianfu, and Hou, Wensheng

Subjects

FLOWERING time, SOYBEAN, GENETIC mutation, HAPLOTYPES, GENE families, GERMPLASM, ARABIDOPSIS thaliana

Abstract

Day length has an important influence on flowering and growth habit in many plant species. In crops such as soybean, photoperiod sensitivity determines the geographical range over which a given cultivar can grow and flower. The soybean genome contains ~10 genes homologous to FT, a central regulator of flowering from Arabidopsis thaliana. However, the precise roles of these soybean FTs are not clearly. Here we show that one such gene, GmFT2b, promotes flowering under long‐days (LDs). Overexpression of GmFT2b upregulates expression of flowering‐related genes which are important in regulating flowering time. We propose a 'weight' model for soybean flowering under short‐day (SD) and LD conditions. Furthermore, we examine GmFT2b sequences in 195 soybean cultivars, as well as flowering phenotypes, geographical distributions and maturity groups. We found that Hap3, a major GmFT2b haplotype, is associated with significantly earlier flowering at higher latitudes. We anticipate our assay to provide important resources for the genetic improvement of soybean, including new germplasm for soybean breeding, and also increase our understanding of functional diversity in the soybean FT gene family. In an effort to understand the molecular genetic basis of flowering time in soybean, we have isolated and characterized GmFT2b, a soybean FT gene homolog. We used overexpression and CRISPR/Cas9‐induced targeted gene mutations to show that GmFT2b regulates flowering in soybean, but only under long days. We also sequenced this gene from 195 soybean cultivars in different maturity groups (MGs). Our analysis showed that one GmFT2b haplotype, Hap3, is found only in early‐maturing cultivars in MGs 0–2, and correlates with their ability to flower in environments located at high latitudes in northeastern China. [ABSTRACT FROM AUTHOR]

Published

2020

7. Mutagenesis of GmFT2a and GmFT5a mediated by CRISPR/Cas9 contributes for expanding the regional adaptability of soybean.

Author

Cai, Yupeng, Wang, Liwei, Chen, Li, Wu, Tingting, Liu, Luping, Sun, Shi, Wu, Cunxiang, Yao, Weiwei, Jiang, Bingjun, Yuan, Shan, Han, Tianfu, and Hou, Wensheng

Subjects

SOYBEAN, FLOWERING time, HAPLOTYPES, MUTAGENESIS, PHANEROGAMS, WILD plants

Abstract

Summary: Flowering time is a key agronomic trait that directly influences the successful adaptation of soybean (Glycine max) to diverse latitudes and farming systems. GmFT2a and GmFT5a have been extensively identified as flowering activators and integrators in soybean. Here, we identified two quantitative trait loci (QTLs) regions harbouring GmFT2a and GmFT5a, respectively, associated with different genetic effects on flowering under different photoperiods. We analysed the flowering time of transgenic plants overexpressing GmFT2a or GmFT5a, ft2a mutants, ft5a mutants and ft2aft5a double mutants under long‐day (LD) and short‐day (SD) conditions. We confirmed that GmFT2a and GmFT5a are not redundant, they collectively regulate flowering time, and the effect of GmFT2a is more prominent than that of GmFT5a under SD conditions whereas GmFT5a has more significant effects than GmFT2a under LD conditions. GmFT5a, not GmFT2a, was essential for soybean to adapt to high latitude regions. The ft2aft5a double mutants showed late flowering by about 31.3 days under SD conditions and produced significantly increased numbers of pods and seeds per plant compared to the wild type. We speculate that these mutants may have enormous yield potential for the tropics. In addition, we examined the sequences of these two loci in 202 soybean accessions and investigated the flowering phenotypes, geographical distributions and maturity groups within major haplotypes. These results will contribute to soybean breeding and regional adaptability. [ABSTRACT FROM AUTHOR]

Published

2020

8. Natural variations of FT family genes in soybean varieties covering a wide range of maturity groups.

Author

Jiang, Bingjun, Zhang, Shouwei, Song, Wenwen, Khan, Mohammad Abdul Awal, Sun, Shi, Zhang, Chengsheng, Wu, Tingting, Wu, Cunxiang, and Han, Tianfu

Subjects

*SOYBEAN, *FLOWERING of plants, *HAPLOTYPES, *GENETIC polymorphisms, *PLANT genes, *PLANT gene mapping

Abstract

Background: Flowering time and maturity are among the most important adaptive traits in soybean (Glycine max (L.) Merill). Flowering Locus T (FT) family genes function as key flowering integrators, with flowering-promoting members GmFT2a/GmFT5a and flowering-inhibiting members GmFT4/GmFT1a antagonistically regulating vegetative and reproductive growth. However, to date, the relations between natural variations of FT family genes and the diversity of flowering time and maturity in soybean are not clear. Therefore, we conducted this study to discover natural variations in FT family genes in association with flowering time and maturity. Results: Ten FT family genes, GmFT1a, GmFT1b, GmFT2a, GmFT2b, GmFT3a, GmFT3b, GmFT4, GmFT5a, GmFT5b and GmFT6, were cloned and sequenced in the 127 varieties evenly covering all 14 known maturity groups (MG0000-MGX). They were diversified at the genome sequence polymorphism level. GmFT3b and GmFT5b might have experienced breeding selection in the process of soybean domestication and breeding. Haplotype analysis showed that a total of 17 haplotypes had correlative relationships with flowering time and maturity among the 10 FT genes, namely, 1a-H3, 1b-H1, 1b-H6, 1b-H7, 2a-H1, 2a-H3, 2a-H4, 2a-H9, 2b-H3, 2b-H4, 2b-H6, 2b-H7, 3b-H4, 5a-H1, 5a-H2, 5a-H4 and 5b-H1. Based on the association analysis, 38 polymorphic sites had a significant association with flowering time at the level of p < 0.01. Conclusions: Some natural variations exist within the 10 FT family genes, which might be involved in soybean adaptation to different environments and have an influence on diverse flowering time and maturity. This study will facilitate the understanding of the roles of FTs in flowering and maturity. [ABSTRACT FROM AUTHOR]

Published

2019