Your search keyword '"Chenyang Hao"' showing total 10 results

1. Homoeologous haplotypes, expression, genetic effects and geographic distribution of the wheat yield gene TaGW2.

Author

Lin Qin, Chenyang Hao, Jian Hou, Yuquan Wang, Tian Li, Lanfen Wang, Zhengqiang Ma, and Xueyong Zhang

Subjects

*HAPLOTYPES, *GENE expression, *GENES, *WHEAT, *CODING theory

Abstract

Background TaGW2-6A, cloned in earlier research, strongly influences wheat grain width and TKW. Here, we mainly analyzed haplotypes of TaGW2-6B and their effects on TKW and interaction with haplotypes at TaGW2-6A. Results About 2.9 kb of the promoter sequences of TaGW2-6B and TaGW2-6D were cloned in 34 bread wheat cultivars. Eleven SNPs were detected in the promoter region of TaGW2-6B, forming 4 haplotypes, but no divergence was detected in the TaGW2-6D promoter or coding region. Three molecular markers including CAPS, dCAPS and ACAS, were developed to distinguish the TaGW2-6B haplotypes. Haplotype association analysis indicated that TaGW2- 6B has a stronger influence than TaGW2-6A on TKW, and Hap-6B-1 was a favored haplotype increasing grain width and weight that had undergone strong positive selection in global wheat breeding. However, clear geographic distribution differences for TaGW2-6A haplotypes were found; Hap-6A-A was favored in Chinese, Australian and Russian cultivars, whereas Hap-6A-G was preferred in European, American and CIMMYT cultivars. This difference might be caused by a flowering and maturity time difference between the two haplotypes. Hap-6A-A is the earlier type. Haplotype interaction analysis between TaGW2-6A and TaGW2-6B showed additive effects between the favored haplotypes. Hap-6A-A/Hap-6B- 1 was the best combination to increase TKW. Relative expression analysis of the three TaGW2 homoeologous genes in 22 cultivars revealed that TaGW2-6A underwent the highest expression. TaGW2-6D was the least expressed during grain development and TaGW2-6B was intermediate. Diversity of the three genes was negatively correlated with their effect on TKW. Conclusions Genetic effects, expression patterns and historic changes of haplotypes at three homoeologous genes of TaGW2 influencing yield were dissected in wheat cultivars. Strong and constant selection to favored haplotypes has been found in global wheat breeding during the past century. This research also provides a valuable case for understanding interaction of genes that control complex traits in polyploid species. [ABSTRACT FROM AUTHOR]

Published

2014

2. Association Mapping and Haplotype Analysis of a 3.1-Mb Genomic Region Involved in Fusarium Head Blight Resistance on Wheat Chromosome 3BS.

Author

Chenyang Hao, Yuquan Wang, Jian Hou, Feuillet, Catherine, Balfourier, Francois, and Xueyong Zhang

Subjects

*MOLECULAR genetics, *PLANT gene banks, *FUSARIUM diseases of plants, *DISEASE resistance of plants, *WHEAT breeding, WHEAT genetics

Abstract

A previous study provided an in-depth understanding of molecular population genetics of European and Asian wheat gene pools using a sequenced 3.1-Mb contig (ctg954) on chromosome 3BS. This region is believed to carry the Fhb1 gene for response to Fusarium head blight. In this study, 266 wheat accessions were evaluated in three environments for Type II FHB response based on the single floret inoculation method. Hierarchical clustering (UPGMA) based on a Manhattan dissimilarity matrix divided the accessions into eight groups according to five FHB-related traits which have a high correlation between them; Group VIII comprised six accessions with FHB response levels similar to variety Sumai 3. Based on the compressed mixed linear model (MLM), association analysis between five FHB-related traits and 42 molecular markers along the 3.1-Mb region revealed 12 significant association signals at a threshold of P<0.05. The highest proportion of phenotypic variation (6.2%) in number of diseased spikelets (NDS) occurred at locus cfb6059, and the physical distance was about 2.9 Kb between umn10 and this marker. Haplotype block (HapB) analysis using a sliding window LD of 5 markers, detected six HapBs in the 3.1-Mb region at r²>0.1 and P<0.001 between random closely linked markers. F-tests among Haps with frequencies .0.05 within each HapB at r²>0.1 and P<0.001 showed significant differences between the Hap carried by FHB resistant resources, such as Sumai 3 and Wangshuibai, and susceptible genotypes in HapB3 and HapB6. These results suggest that Fhb1 is located within HapB6, with the possibility that another gene is located at or near HapB3. SSR markers and Haps detected in this study will be helpful in further understanding the genetic basis of FHB resistance, and provide useful information for marker-assisted selection of Fhb1 in wheat breeding. [ABSTRACT FROM AUTHOR]

Published

2012

3. Genetic Diversity and Linkage Disequilibrium in Chinese Bread Wheat (Triticum aestivum L.) Revealed by SSR Markers.

Author

Chenyang Hao, Lanfen Wang, Hongmei Ge, Yuchen Dong, and Xueyong Zhang

Subjects

*WHEAT, *GENETIC polymorphisms, *GENOMES, *ALLELES, *GRAIN

Abstract

Two hundred and fifty bread wheat lines, mainly Chinese mini core accessions, were assayed for polymorphism and linkage disequilibrium (LD) based on 512 whole-genome microsatellite loci representing a mean marker density of 5.1 cM. A total of 6,724 alleles ranging from 1 to 49 per locus were identified in all collections. The mean PIC value was 0.650, ranging from 0 to 0.965. Population structure and principal coordinate analysis revealed that landraces and modern varieties were two relatively independent genetic sub-groups. Landraces had a higher allelic diversity than modern varieties with respect to both genomes and chromosomes in terms of total number of alleles and allelic richness. 3,833 (57.0%) and 2,788 (41.5%) rare alleles with frequencies of <5% were found in the landrace and modern variety gene pools, respectively, indicating greater numbers of rare variants, or likely new alleles, in landraces. Analysis of molecular variance (AMOVA) showed that A genome had the largest genetic differentiation and D genome the lowest. In contrast to genetic diversity, modern varieties displayed a wider average LD decay across the whole genome for locus pairs with r2>0.05 (P<0.001) than the landraces. Mean LD decay distance for the landraces at the whole genome level was <5 cM, while a higher LD decay distance of 5- 10 cM in modern varieties. LD decay distances were also somewhat different for each of the 21 chromosomes, being higher for most of the chromosomes in modern varieties (<5~25 cM) compared to landraces (<5~15 cM), presumably indicating the influences of domestication and breeding. This study facilitates predicting the marker density required to effectively associate genotypes with traits in Chinese wheat genetic resources. [ABSTRACT FROM AUTHOR]

Published

2011

4. Genetic diversity and construction of core collection in Chinese wheat genetic resources.

Author

ChenYang Hao, YuChen Dong, LanFen Wang, GuangXia You, HongNa Zhang, HongMei Ge, JiZeng Jia, and XueYong Zhang

Subjects

*PLANT genetics, *CULTIVARS, *CHROMOSOMES, *PLANT chromosomes, WHEAT genetics

Abstract

Genetic diversity among 5029 accessions representing a proposed Chinese wheat core collection was analyzed using 78 pairs of fluorescent microsatellite (SSR) primers mapped to 21 chromosomes. A stepwise hierarchical sampling strategy with priority based on 4×105 SSR data-points was used to construct a core collection from the 23090 initial collections. The core collection consisted of 1160 accessions, including 762 landraces, 348 modern varieties and 50 introduced varieties. The core accounts for 23.1 % of the 5029 candidate core accessions and 5% of the 23090 initial collections, but retains 94.9% of alleles from the candidate collections and captures 91.5% of the genetic variation in the initial collections. These data indicate that it is possible to maintain genetic diversity in a core collection while retaining fewer accessions than the accepted standard, i.e., 10% of the initial collections captured more than 70% of their genetic diversity. Estimated genetic representation of the core constructed by preferred sampling (91.5%) is much higher than that by random sampling (79.8%). Both mean genetic richness and genetic diversity indices of the landraces were higher than those of the modern varieties in the core. Structure and principal coordinate analysis revealed that the landraces and the modern varieties were two relatively independent subpopulations. Strong genetic differentiation associated with ecological environments has occurred in the landraces, but was relatively weak in the modern cultivars. In addition, a mini-core collection was constructed, which consisted of 231 accessions with an estimated 70% representation of the genetic variation from the initial collections. The mini-core has been distributed to various research and breeding institutes for detailed phenotyping and breeding of genetic introgression lines. [ABSTRACT FROM AUTHOR]

Published

2008

5. The auxin response factor TaARF15-A1 negatively regulates senescence in common wheat (Triticum aestivum L.).

Author

Huifang Li, Hong Liu, Chenyang Hao, Tian Li, Yunchuan Liu, Xiaolu Wang, Yuxin Yang, Jun Zheng, and Xueyong Zhang

Abstract

Auxin plays an important role in regulating leaf senescence. Auxin response factors (ARFs) are crucial components of the auxin signaling pathway; however, their roles in leaf senescence in cereal crops are unknown. In this study, we identified TaARF15-A1 as a negative regulator of senescence in wheat (Triticum aestivum L.) by analyzing TaARF15-A1 overexpression (OE) and RNA interference lines and CRISPR/Cas9-based arf15 mutants. OE of TaARF15-A1 delayed senescence, whereas knockdown lines and knockout mutants showed accelerated leaf senescence and grain ripening. RNA-seq analysis revealed that TaARF15-A1 delays leaf senescence by negatively regulating senescence-promoting processes and positively modulating senescence-delaying genes including senescence-associated phytohormone biosynthesis and metabolism genes as well as transcription factors (TFs). We also demonstrated that TaARF15-A1 physically interacts with TaMYC2, a core jasmonic acid (JA) signaling TF that positively modulates wheat senescence. Furthermore, TaARF15-A1 suppressed the expression of TaNAM-1 (TaNAM-A1 and TaNAM-D1) via protein-protein interaction and competition with TaMYC2 for binding to its promoter to regulate senescence. Finally, we identified two haplotypes of TaARF15-A1 in global wheat collections. Association analysis revealed that TaARF15-A1-HapI has undergone strong selection during wheat breeding in China, likely owing to its earlier maturity. Thus, we identify TaARF15-A1 as a negative regulator of senescence in common wheat and present another perspective on the crosstalk between auxin and JA signaling pathways in regulating plant senescence. [ABSTRACT FROM AUTHOR]

Published

2023

6. The wheat sucrose synthase gene TaSus1 is a determinant of grain number per spike.

Author

Liping Shen, Lili Zhang, Changbin Yin, Xiaowan Xu, Yangyang Liu, Kuocheng Shen, He Wu, Zhiwen Sun, Ke Wang, Zhonghu He, Xueyong Zhang, Chenyang Hao, Jian Hou, Aoyue Bi, Xuebo Zhao, Daxing Xu, Botao Ye, Xuchang Yu, Ziying Wang, and Danni Liu

Subjects

*SUCROSE synthase, *GRAIN weights & measures, *GENOME-wide association studies, *SINGLE nucleotide polymorphisms, WHEAT genetics

Abstract

Some haplotypes of the sucrose synthase gene TaSus1 are associated with thousand-grain weight (TGW) in wheat (Triticum aestivum L.). However, no mutations have been identified within the gene to test this association. The effects of TaSus1 on grain number per spike (GNS) also are largely unknown. Our previous genome-wide association study identified TaSus-A1 as a candidate gene controlling fertile spikelet number per spike (FSN). In the present study, we generated two independent mutants for the three TaSus1 homoeologs by CRISPR/Cas9-mediated genome editing. The triple mutants displayed lower FSN, GNS, grain number per spikelet (GNST), and TGW than wild-type plants. In 306 hexaploid wheat accessions, two single-nucleotide polymorphisms in TaSus-A1 contributed differently to GNS. Introgression of the two alleles into a wheat genetic background confirmed their effects. The alleles differed in geographical distribution among the accessions. [ABSTRACT FROM AUTHOR]

Published

2024

7. TaGW2L, a GW2-like RING finger E3 ligase, positively regulates heading date in common wheat (Triticum aestivum L.).

Author

Daijing Zhang, Xiaoxu Zhang, Wu Xu, Tingting Hu, Jianhui Ma, Youfu Zhang, Jian Hou, Chenyang Hao, Xueyong Zhang, and Tian Li

Subjects

*PLANT development, *LIGASES, *AMINO acid sequence, *UBIQUITIN-conjugating enzymes, *CROP improvement, WHEAT genetics

Abstract

RING finger E3 ligases play an important role in regulating plant growth and development by mediating substrate degradation. In this study, we identified TaGW2L, encoding a Grain width and weight2 (GW2)- like RING finger E3 ligase, as a novel positive regulator of heading date in wheat (Triticum aestivum L.). TaGW2L exhibited high amino acid sequence similarities with TaGW2 homoeologs, particularly in the conserved RING finger domain. Expression analysis indicated that TaGW2L was constitutively expressed in various wheat tissues. TaGW2L showed transactivation activity in yeast and could interact with the ubiquitin-conjugating enzymes E2s. An in vitro ubiquitination assay verified that TaGW2L possessed a similar E3 ligase activity to TaGW2. Overexpression of the TaGW2L-7A homoeolog in wheat led to a significantly earlier heading date under both natural conditions and long-day conditions. Transcriptome analysis revealed that multiple known genes positively regulating wheat heading were significantly upregulated in the TaGW2L-7A-overexpression plants compared with the wild-type control. Together, our findings shed light on the role of TaGW2L in wheat heading date and provide potential applications of TaGW2L for the adaptation improvement of crops. [ABSTRACT FROM AUTHOR]

Published

2022

8. Global Selection on Sucrose Synthase Haplotypes during a Century of Wheat Breeding.

Author

Jian Hou, Qiyan Jiang, Chenyang Hao, Yuquan Wang, Hongna Zhang, and Xueyong Zhang

Subjects

*SUCROSE synthase, *PLANT haplotypes, *WHEAT breeding, *WHEAT yields, *ABIOTIC stress

Abstract

Spike number per unit area, number of grains per spike, and thousand kernel weight (TKW) are important yield components. In China, increases in wheat (Triticum aestivum) yields are mainly due to increases in grain number per spike and TKW. TKW mainly depends on starch content, as starch accounts for about 70% of the grain endosperm. Sucrose synthase catalysis is the first step in the conversion of sucrose to starch, that is, the conversion of sucrose to fructose and UDP-glucose by the wheat sucrose synthase genes (TaSusl1 and TaSus2) that are located on chromosomes 7A/7B/7D and 2A/2B/2D, respectively. A total of 1,520 wheat accessions were genotyped at the six loci. Two, two, five, and two haplotypes were identified at the TaSus2-2A, TaStis2-2B, TaSus1-7A, and TaSus1-7B loci, respectively. Their main variations were detected within the introns. Significant differences between the haplotypes correlated with TKW differences among 348 modern Chinese cultivars from the core collection. Frequency changes for favored haplotypes showed gradual increases in cultivars released since beginning of the last century in China, Europe, and North America. Geographic distributions and time changes of favored haplotypes were characterized in six major wheat production regions worldwide. Strong selection bottlenecks to haplotype variations occurred at polyploidization and domestication and during breeding of wheat. Genetic-effect differences between haplotypes at the same locus influence the selection time and intensity. This work shows that the endosperm starch synthesis pathway is a major target of indirect selection in global wheat breeding for higher yield. [ABSTRACT FROM AUTHOR]

Published

2014

9. Identifying Loci Influencing 1,000-Kernel Weight in Wheat by Microsatellite Screening for Evidence of Selection during Breeding.

Author

Lanfen Wang, Hongmei Ge, Chenyang Hao, Yushen Dong, and Xueyong Zhang

Subjects

*WHEAT, *MICROSATELLITE repeats, *CHROMOSOMES, *REPEATED sequence (Genetics), *LOCUS (Genetics)

Abstract

Chinese wheat mini core collection (262 accessions) was genotyped at 531 microsatellite loci representing a mean marker density of 5.1 cM. One-thousand-kernel weights (TKW) of lines were measured in five trials (three environments in four growing seasons). Structure analysis based on 42 unlinked SSR loci indicated that the materials formed two subpopulations, viz., landraces and modern varieties. A large difference in TKW (7.08 g, P<0.001) was found between the two sub-groups. Therefore, TKW is a major yield component that was improved in the past 6 decades; it increased from a mean 31.5 g in the 1940s to 44.64 g in the 2000s, representing a 2.19 g increase in each decade. Analyses based on a mixed linear model (MLM), population structure (Q) and relative kinship (K) revealed 22 SSR loci that were significantly associated with mean TKW (MTKW) of the five trials estimated by the best linear unbiased predictor (BLUP) method. They were mainly distributed on chromosomes of homoeologous groups 1, 2, 3, 5 and 7. Six loci, cfa2234-3A, gwm156-3B, barc56-5A, gwm234- 5B, wmc17-7A and cfa2257-7A individually explained more than 11.84% of the total phenotypic variation. Favored alleles for breeding at the 22 loci were inferred according to their estimated effects on MTKW based on mean difference of varieties grouped by genotypes. Statistical simulation showed that these favored alleles have additive genetic effects. Frequency changes of alleles at loci associated with TKW are much more dramatic than those at neutral loci between the sub-groups. The numbers of favored alleles in modern varieties indicate there is still considerable genetic potential for their use as markers for genome selection of TKW in wheat breeding. Alleles that can be used globally to increase TKW were inferred according to their distribution by latitude and frequency of changes between landraces and the modern varieties. [ABSTRACT FROM AUTHOR]

Published

2012

10. Genome Selection Sweep and Association Analysis Shed Light on Future Breeding by Design in Wheat.

Author

Hongmei Ge, Guangxia You, Lanfen Wang, Chenyang Hao, Yushen Dong, Zhensheng Li, and Xueyong Zhang

Subjects

*WHEAT, *GENOMICS, *MICROSATELLITE repeats, *CULTIVARS, *PLANT breeding

Abstract

Two sets of bread wheat (Triticum aestivum L.) varieties and their respective founder parents (St2422/464 and Abbondanza) in China were genotyped at 481 microsatellite loci. The selection sweeps detected almost completely overlapped with one another across the two sets on the 21 chromosomes although a cluster analysis showed that they do represent distinct subpopulations with Fst = 0.0734 (minor allele frequency [MAF] = 0.1, -log10p = 5). About 38.7% of the loci appeared to have experienced some selection sweep. Important agronomic traits were usually associated with these selection sweep valleys. The alleles present at key loci in these valleys were often in common between the two founders. Markertrait association based on three seasons of field data suggested the association of one, four, and six loci with, respectively, the number of fertile tillers per plant, grain number per spike, and thousand grain weight. Five, 14, and 21 loci were associated with the three yield components in two of the three seasons. We suggest that the breeding potential of a line can be predicted from its allelic state at certain critical marker loci, which represent major targets for breeding by design in wheat. Genotypic descriptions of major cultivars and the analytical approach we have described here provide a path toward the a priori selection of favorable breeding parents. [ABSTRACT FROM AUTHOR]

Published

2012