Your search keyword '"Jianyin Xie"' showing total 25 results

1. Large-scale genomic and transcriptomic profiles of rice hybrids reveal a core mechanism underlying heterosis

Author

Jianyin Xie, Weiping Wang, Tao Yang, Quan Zhang, Zhifang Zhang, Xiaoyang Zhu, Ni Li, Linran Zhi, Xiaoqian Ma, Shuyang Zhang, Yan Liu, Xueqiang Wang, Fengmei Li, Yan Zhao, Xuewei Jia, Jieyu Zhou, Ningjia Jiang, Gangling Li, Miaosong Liu, Shijin Liu, Lin Li, An Zeng, Mengke Du, Zhanying Zhang, Jinjie Li, Ziding Zhang, Zichao Li, and Hongliang Zhang

Subjects

Hybrid rice, Heterosis, Nonadditive, HoIIB model, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Background Heterosis is widely used in agriculture. However, its molecular mechanisms are still unclear in plants. Here, we develop, sequence, and record the phenotypes of 418 hybrids from crosses between two testers and 265 rice varieties from a mini-core collection. Results Phenotypic analysis shows that heterosis is dependent on genetic backgrounds and environments. By genome-wide association study of 418 hybrids and their parents, we find that nonadditive QTLs are the main genetic contributors to heterosis. We show that nonadditive QTLs are more sensitive to the genetic background and environment than additive ones. Further simulations and experimental analysis support a novel mechanism, homo-insufficiency under insufficient background (HoIIB), underlying heterosis. We propose heterosis in most cases is not due to heterozygote advantage but homozygote disadvantage under the insufficient genetic background. Conclusion The HoIIB model elucidates that genetic background insufficiency is the intrinsic mechanism of background dependence, and also the core mechanism of nonadditive effects and heterosis. This model can explain most known hypotheses and phenomena about heterosis, and thus provides a novel theory for hybrid rice breeding in future.

Published

2022

2. Natural variation of RGN1a regulates grain number per panicle in japonica rice

Author

Quan Zhang, Jianyin Xie, Xueqiang Wang, Miaosong Liu, Xiaoyang Zhu, Tao Yang, Najeeb Ullah Khan, Chen Sun, Jinjie Li, Zhanying Zhang, Zichao Li, and Hongliang Zhang

Subjects

GWAS, grain number per panicle, breeding, haplotype, rice, Plant culture, SB1-1110

Abstract

The grain number per panicle (GNP) is an important yield component. Identifying naturally favorable variations in GNP will benefit high-yield rice breeding. Here, we performed a genome-wide association study using a mini-core collection of 266 cultivated rice accessions with deep sequencing data and investigated the phenotype for three years. Three genes, i.e., TOTOU1 (TUT1), Grain height date 7 (Ghd7), and Days to heading 7/Grain height date 7.1/Pseudo-Response Regulator37 (DTH7/Ghd7.1/OsPRR37), which regulate GNP, were found in the quantitative trait loci (QTL) identified in this study. A stable QTL, qGNP1.3, which showed a strong correlation with variations in GNP, was repeatedly detected. After functional and transgenic phenotype analysis, we identified a novel gene, regulator of grain number 1a (RGN1a), which codes for protein kinase, controlling GNP in rice. The RGN1a mutation caused 37.2%, 27.8%, 51.2%, and 25.5% decreases in grain number, primary branch number per panicle, secondary branch number per panicle, and panicle length, respectively. Furthermore, breeding utilization analysis revealed that the additive effects of the dominant allelic variants of RGN1a and DTH7 played a significant role in increasing the grain number per panicle in japonica rice. Our findings enrich the gene pool and provide an effective strategy for the genetic improvement of grain numbers.

Published

2022

3. Genetic basis and network underlying synergistic roots and shoots biomass accumulation revealed by genome-wide association studies in rice

Author

Yan Zhao, Zhigang Yin, Xueqiang Wang, Conghui Jiang, Muhammad Mahran Aslam, Fenghua Gao, Yinghua Pan, Jianyin Xie, Xiaoyang Zhu, Luhao Dong, Yanhe Liu, Hongliang Zhang, Jinjie Li, and Zichao Li

Subjects

Medicine, Science

Abstract

Abstract Genetic basis and network studies underlying synergistic biomass accumulation of roots and shoots (SBA) are conducive for rational design of high-biomass rice breeding. In this study, association signals for root weight, shoot weight, and the ratio of root-to-shoot mass (R/S) were identified using 666 rice accessions by genome-wide association study, together with their sub-traits, root length, root thickness and shoot length. Most association signals for root weight and shoot weight did not show association with their sub-traits. Based on the results, we proposed a top-to-bottom model for SBA, i.e. root weight, shoot weight and R/S were determined by their highest priority in contributing to biomass in the regulatory pathway, followed by a lower priority pathway for their sub-traits. Owing to 37 enriched clusters with more than two association signals identified, the relationship among the six traits could be also involved in linkage and pleiotropy. Furthermore, a discrimination of pleiotropy and LD at sequencing level using the known gene OsPTR9 for root weight, R/S and root length was provided. The results of given moderate correlation between traits and their corresponding sub-traits, and moderate additive effects between a trait and the accumulation of excellent alleles corresponding to its sub-traits supported a bottom-to-top regulation model for SBA. This model depicted each lowest-order trait (root length, root thickness and shoot length) was determined by its own regulation loci, and competition among different traits, as well as the pleiotropy and LD. All above ensure the coordinated development of each trait and the accumulation of the total biomass, although the predominant genetic basis of SBA is still indistinguishable. The presentation of the above two models and evidence of this study shed light on dissecting the genetic architecture of SBA.

Published

2021

4. Distinct nucleotide patterns among three subgenomes of bread wheat and their potential origins during domestication after allopolyploidization

Author

Yan Zhao, Luhao Dong, Conghui Jiang, Xueqiang Wang, Jianyin Xie, Muhammad Abdul Rehman Rashid, Yanhe Liu, Mengyao Li, Zhimu Bu, Hongwei Wang, Xin Ma, Silong Sun, Xiaoqian Wang, Cunyao Bo, Tingting Zhou, and Lingrang Kong

Subjects

Bread wheat, Allopolyploidization, Evolution, Base composition, Subgenome divergence, DNA repair, Biology (General), QH301-705.5

Abstract

Abstract Background The speciation and fast global domestication of bread wheat have made a great impact on three subgenomes of bread wheat. DNA base composition is an essential genome feature, which follows the individual-strand base equality rule and [AT]-increase pattern at the genome, chromosome, and polymorphic site levels among thousands of species. Systematic analyses on base compositions of bread wheat and its wild progenitors could facilitate further understanding of the evolutionary pattern of genome/subgenome-wide base composition of allopolyploid species and its potential causes. Results Genome/subgenome-wide base-composition patterns were investigated by using the data of polymorphic site in 93 accessions from worldwide populations of bread wheat, its diploid and tetraploid progenitors, and their corresponding reference genome sequences. Individual-strand base equality rule and [AT]-increase pattern remain in recently formed hexaploid species bread wheat at the genome, subgenome, chromosome, and polymorphic site levels. However, D subgenome showed the fastest [AT]-increase across polymorphic site from Aegilops tauschii to bread wheat than that on A and B subgenomes from wild emmer to bread wheat. The fastest [AT]-increase could be detected almost all chromosome windows on D subgenome, suggesting different mechanisms between D and other two subgenomes. Interestingly, the [AT]-increase is mainly contributed by intergenic regions at non-selective sweeps, especially the fastest [AT]-increase of D subgenome. Further transition frequency and sequence context analysis indicated that three subgenomes shared same mutation type, but D subgenome owns the highest mutation rate on high-frequency mutation type. The highest mutation rate on D subgenome was further confirmed by using a bread-wheat-private SNP set. The exploration of loci/genes related to the [AT] value of D subgenome suggests the fastest [AT]-increase of D subgenome could be involved in DNA repair systems distributed on three subgenomes of bread wheat. Conclusions The highest mutation rate is detected on D subgenome of bread wheat during domestication after allopolyploidization, leading to the fastest [AT]-increase pattern of D subgenome. The phenomenon may come from the joint action of multiple repair systems inherited from its wild progenitors.

Published

2020

5. Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspecies

Author

Huili Yan, Wenxiu Xu, Jianyin Xie, Yiwei Gao, Lulu Wu, Liang Sun, Lu Feng, Xu Chen, Tian Zhang, Changhua Dai, Ting Li, Xiuni Lin, Zhanying Zhang, Xueqiang Wang, Fengmei Li, Xiaoyang Zhu, Jinjie Li, Zichao Li, Caiyan Chen, Mi Ma, Hongliang Zhang, and Zhenyan He

Subjects

Science

Abstract

Grain of indica rice accumulates more toxic cadmium (Cd) than japonica, but the underlying genetic basis is unclear. Here, the authors show that natural variation of OsCd1 contributes to divergence in grain Cd accumulation and transferring japonica allele to indica rice leads to reduced Cd accumulation.

Published

2019

6. Loci and natural alleles underlying robust roots and adaptive domestication of upland ecotype rice in aerobic conditions.

Author

Yan Zhao, Hongliang Zhang, Jianlong Xu, Conghui Jiang, Zhigang Yin, Haiyan Xiong, Jianyin Xie, Xueqiang Wang, Xiaoyang Zhu, Yang Li, Weipeng Zhao, Muhammad Abdul Rehman Rashid, Jinjie Li, Wensheng Wang, Binying Fu, Guoyou Ye, Yan Guo, Zhiqiang Hu, Zhikang Li, and Zichao Li

Subjects

Genetics, QH426-470

Abstract

A robust (long and thick) root system is characteristic of upland japonica rice adapted to drought conditions. Using deep sequencing and large scale phenotyping data of 795 rice accessions and an integrated strategy combining results from high resolution mapping by GWAS and linkage mapping, comprehensive analyses of genomic, transcriptomic and haplotype data, we identified large numbers of QTLs affecting rice root length and thickness (RL and RT) and shortlisted relatively few candidate genes for many of the identified small-effect QTLs. Forty four and 97 QTL candidate genes for RL and RT were identified, and five of the RL QTL candidates were validated by T-DNA insertional mutation; all have diverse functions and are involved in root development. This work demonstrated a powerful strategy for highly efficient cloning of moderate- and small-effect QTLs that is difficult using the classical map-based cloning approach. Population analyses of the 795 accessions, 202 additional upland landraces, and 446 wild rice accessions based on random SNPs and SNPs within robust loci suggested that there could be much less diversity in robust-root candidate genes among upland japonica accessions than in other ecotypes. Further analysis of nucleotide diversity and allele frequency in the robust loci among different ecotypes and wild rice accessions showed that almost all alleles could be detected in wild rice, and pyramiding of robust-root alleles could be an important genetic characteristic of upland japonica. Given that geographical distribution of upland landraces, we suggest that during domestication of upland japonica, the strongest pyramiding of robust-root alleles makes it a unique ecotype adapted to aerobic conditions.

Published

2018

7. Genetic Basis Underlying Correlations Among Growth Duration and Yield Traits Revealed by GWAS in Rice (Oryza sativa L.)

Author

Fengmei Li, Jianyin Xie, Xiaoyang Zhu, Xueqiang Wang, Yan Zhao, Xiaoqian Ma, Zhanying Zhang, Muhammad A. R. Rashid, Zhifang Zhang, Linran Zhi, Shuyang Zhang, Jinjie Li, Zichao Li, and Hongliang Zhang

Subjects

genetic correlation, genome wide association study, pleiotropic gene, pleiotropic QTL, gene interaction, Plant culture, SB1-1110

Abstract

Avoidance of disadvantageous genetic correlations among growth duration and yield traits is critical in developing crop varieties that efficiently use light and energy resources and produce high yields. To understand the genetic basis underlying the correlations among heading date and three major yield traits in rice, we investigated the four traits in a diverse and representative core collection of 266 cultivated rice accessions in both long-day and short-day environments, and conducted the genome-wide association study using 4.6 million single nucleotide polymorphisms (SNPs). There were clear positive correlation between heading date and grain number per panicle, and negative correlation between grain number per panicle and panicle number, as well as different degrees of correlations among other traits in different subspecies and environments. We detected 47 pleiotropic genes in 15 pleiotropic quantitative trait loci (pQTLs), 18 pleiotropic genes containing 37 pleiotropic SNPs in 8 pQTLs, 27 pQTLs with r2 of linkage disequilibrium higher than 0.2, and 39 pairs of interactive genes from 8 metabolic pathways that may contribute to the above phenotypic correlations, but these genetic bases were different for correlations among different traits. Distributions of haplotypes revealed that selection for pleiotropic genes or interactive genes controlling different traits focused on genotypes with weak effect or on those balancing two traits that maximized production but sometimes their utilization strategies depend on the traits and environment. Detection of pQTLs and interactive genes and associated molecular markers will provide an ability to overcome disadvantageous correlations and to utilize the advantageous correlations among traits through marker-assisted selection in breeding.

Published

2018

8. Genetic Architecture and Candidate Genes for Deep-Sowing Tolerance in Rice Revealed by Non-syn GWAS

Author

Yan Zhao, Weipeng Zhao, Conghui Jiang, Xiaoning Wang, Huaiyang Xiong, Elena G. Todorovska, Zhigang Yin, Yanfa Chen, Xin Wang, Jianyin Xie, Yinghua Pan, Muhammad A. R. Rashid, Hongliang Zhang, Jinjie Li, and Zichao Li

Subjects

deep-sowing tolerance, genome-wide association study, mesocotyl length, non-synonymous SNP, Oryza sativa, Plant culture, SB1-1110

Abstract

Dry direct-seeding of rice is rapidly increasing in China, but variable planting depth associated with machine sowing can lead to low seedling emergence rates. Phenotype analysis of 621 rice accessions showed that mesocotyl length (ML) was induced by deep soil covering and was important in deep-sowing tolerance in the field. Here, we performed and compared GWAS using three types of SNPs (non-synonymous SNP, non-synonymous SNPs and SNPs within promoters and 3 million randomly selected SNPs from the entire set of SNPs) and found that Non-Syn GWAS (GWAS using non-synonyomous SNP) decreased computation time and eliminated confounding by other loci relative to GWAS using randomly selected SNPs. Thirteen QTLs were finally detected, and two new major-effect genes, named OsML1 and OsML2, were identified by an integrated analysis. There were 2 and 7 non-synonymous SNPs in OsML1 and OsML2, respectively, from which 3 and 4 haplotypes were detected in cultivated rice. Combinations of superior haplotypes of OsML1 and OsML2 increased ML by up to 4 cm, representing high emergence rate (85%) in the field with 10 cm of soil cover. The studies provide key loci and naturally occurring alleles of ML that can be used in improving tolerance to dry direct-seeding.

Published

2018

9. Author Correction: Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspecies

Author

Huili Yan, Wenxiu Xu, Jianyin Xie, Yiwei Gao, Lulu Wu, Liang Sun, Lu Feng, Xu Chen, Tian Zhang, Changhua Dai, Ting Li, Xiuni Lin, Zhanying Zhang, Xueqiang Wang, Fengmei Li, Xiaoyang Zhu, Jinjie Li, Zichao Li, Caiyan Chen, Mi Ma, Hongliang Zhang, and Zhenyan He

Subjects

Science

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2019

10. Natural variation in Tiller Number 1 affects its interaction with <scp>TIF1</scp> to regulate tillering in rice

Author

Quan Zhang, Jianyin Xie, Xiaoyang Zhu, Xiaoqian Ma, Tao Yang, Najeeb Ullah Khan, Shuyang Zhang, Miaosong Liu, Lin Li, Yuntao Liang, Yinghua Pan, Danting Li, Jinjie Li, Zichao Li, Hongliang Zhang, and Zhanying Zhang

Subjects

Plant Science, Agronomy and Crop Science, Biotechnology

Published

2023

11. RGN1 controls grain number and shapes panicle architecture in rice

Author

Yanpei Zhang, Najeeb Ullah Khan, Haifeng Guo, Zichao Li, Yawen Xu, Xingming Sun, Jinjie Li, Jianyin Xie, Zhenyuan Wu, Xueqiang Wang, Gangling Li, Bingxia Xu, Zhanying Zhang, Wensheng Wang, Hongliang Zhang, and Jianlong Xu

Subjects

Germplasm, Molecular breeding, food and beverages, Grain number, Oryza, Regulator of Grain Number1, Plant Science, germplasm, Biology, Horticulture, Mutation, Molecular mechanism, MYB, Edible Grain, grain number per panicle, Agronomy and Crop Science, Alleles, Research Articles, Research Article, MYB transcription factor, Biotechnology, Panicle

Abstract

Summary Yield in rice is determined mainly by panicle architecture. Using map‐based cloning, we identified an R2R3 MYB transcription factor REGULATOR OF GRAIN NUMBER1 (RGN1) affecting grain number and panicle architecture. Mutation of RGN1 caused an absence of lateral grains on secondary branches. We demonstrated that RGN1 controls lateral grain formation by regulation of LONELY GUY (LOG) expression, thus controlling grain number and shaping panicle architecture. A novel favourable allele, RGN1 C, derived from the Or‐I group in wild rice affected panicle architecture by means longer panicles. Identification of RGN1 provides a theoretical basis for understanding the molecular mechanism of lateral grain formation in rice; RGN1 will be an important gene resource for molecular breeding for higher yield.

Published

2021

12. Genetic basis and network underlying synergistic roots and shoots biomass accumulation revealed by genome-wide association studies in rice

Author

Yinghua Pan, Conghui Jiang, Jianyin Xie, Xiaoyang Zhu, Hongliang Zhang, Yanhe Liu, Muhammad Mahran Aslam, Xueqiang Wang, Yan Zhao, Fenghua Gao, Zichao Li, Luhao Dong, Zhigang Yin, and Jinjie Li

Subjects

0106 biological sciences, 0301 basic medicine, Genotype, Genetic Linkage, media_common.quotation_subject, Science, Quantitative Trait Loci, Genome-wide association study, Biology, 01 natural sciences, Plant Roots, Polymorphism, Single Nucleotide, Competition (biology), Article, 03 medical and health sciences, Pleiotropy, Botany, Genetics, Biomass, Allele, Gene, Alleles, media_common, Multidisciplinary, food and beverages, Oryza, Genetic architecture, Computational biology and bioinformatics, Plant Breeding, 030104 developmental biology, Shoot, Trait, Medicine, Plant sciences, Plant Shoots, 010606 plant biology & botany, Genome-Wide Association Study

Abstract

Genetic basis and network studies underlying synergistic biomass accumulation of roots and shoots (SBA) are conducive for rational design of high-biomass rice breeding. In this study, association signals for root weight, shoot weight, and the ratio of root-to-shoot mass (R/S) were identified using 666 rice accessions by genome-wide association study, together with their sub-traits, root length, root thickness and shoot length. Most association signals for root weight and shoot weight did not show association with their sub-traits. Based on the results, we proposed a top-to-bottom model for SBA, i.e. root weight, shoot weight and R/S were determined by their highest priority in contributing to biomass in the regulatory pathway, followed by a lower priority pathway for their sub-traits. Owing to 37 enriched clusters with more than two association signals identified, the relationship among the six traits could be also involved in linkage and pleiotropy. Furthermore, a discrimination of pleiotropy and LD at sequencing level using the known gene OsPTR9 for root weight, R/S and root length was provided. The results of given moderate correlation between traits and their corresponding sub-traits, and moderate additive effects between a trait and the accumulation of excellent alleles corresponding to its sub-traits supported a bottom-to-top regulation model for SBA. This model depicted each lowest-order trait (root length, root thickness and shoot length) was determined by its own regulation loci, and competition among different traits, as well as the pleiotropy and LD. All above ensure the coordinated development of each trait and the accumulation of the total biomass, although the predominant genetic basis of SBA is still indistinguishable. The presentation of the above two models and evidence of this study shed light on dissecting the genetic architecture of SBA.

Published

2021

13. High-precision early warning system for rice cadmium accumulation risk assessment

Author

Huili Yan, Hanyao Guo, Ting Li, Hezifan Zhang, Wenxiu Xu, Jianyin Xie, Xiaoyang Zhu, Yijun Yu, Jian Chen, Shouqing Zhao, Jun Xu, Minjun Hu, Yugen Jiang, Hongliang Zhang, Mi Ma, and Zhenyan He

Subjects

Soil, Environmental Engineering, Environmental Chemistry, Soil Pollutants, Oryza, Pollution, Waste Management and Disposal, Risk Assessment, Cadmium

Abstract

Rapid global industrialization has resulted in widespread cadmium contamination in agricultural soils and products. A considerable proportion of rice consumers are exposed to Cd levels above the provisional safe intake limit, raising widespread environmental concerns on risk management. Therefore, a generalized approach is urgently needed to enable correct evaluation and early warning of cadmium contaminants in rice products. Combining big data and computer science together, this study developed a system named "SMART Cd Early Warning", which integrated 4 modules including genotype-to-phenotype (G2P) modelling, high-throughput sequencing, G2P prediction and rice Cd contamination risk assessment, for rice cadmium accumulation early warning. This system can rapidly assess the risk of rice cadmium accumulation by genotyping leaves at seeding stage. The parameters including statistical methods, population size, training population-testing population ratio, SNP density were assessed to ensure G2P model exhibited superior performance in terms of prediction precision (up to 0.76 ± 0.003) and computing efficiency (within 2 h). In field trials of cadmium-contaminated farmlands in Wenling and Fuyang city, Zhejiang Province, "SMART Cd Early Warning" exhibited superior capability for identification risk rice varieties, suggesting a potential of "SMART Cd Early-Warning system" in OsGCd risk assessment and early warning in the age of smart.

Published

2022

14. Distinct nucleotide patterns among three subgenomes of bread wheat and their potential origins during domestication after allopolyploidization

Author

Lingrang Kong, Xin Ma, Cunyao Bo, Mengyao Li, Muhammad Abdul Rehman Rashid, Hongwei Wang, Yanhe Liu, Yan Zhao, Tingting Zhou, Jianyin Xie, Xueqiang Wang, Xiaoqian Wang, Silong Sun, Luhao Dong, Conghui Jiang, and Zhimu Bu

Subjects

0106 biological sciences, Mutation rate, Allopolyploidization, Physiology, Evolution, DNA repair, Plant Science, Biology, Bread wheat, 01 natural sciences, Genome, General Biochemistry, Genetics and Molecular Biology, Domestication, Evolution, Molecular, Polyploidy, 03 medical and health sciences, Intergenic region, Structural Biology, Aegilops tauschii, Gene, lcsh:QH301-705.5, Triticum, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Base composition, Genetics, 0303 health sciences, Nucleotides, Chromosome, food and beverages, Cell Biology, biology.organism_classification, lcsh:Biology (General), Subgenome divergence, Ploidy, General Agricultural and Biological Sciences, Genome, Plant, Research Article, 010606 plant biology & botany, Developmental Biology, Biotechnology, Reference genome

Abstract

Background The speciation and fast global domestication of bread wheat have made a great impact on three subgenomes of bread wheat. DNA base composition is an essential genome feature, which follows the individual-strand base equality rule and [AT]-increase pattern at the genome, chromosome, and polymorphic site levels among thousands of species. Systematic analyses on base compositions of bread wheat and its wild progenitors could facilitate further understanding of the evolutionary pattern of genome/subgenome-wide base composition of allopolyploid species and its potential causes. Results Genome/subgenome-wide base-composition patterns were investigated by using the data of polymorphic site in 93 accessions from worldwide populations of bread wheat, its diploid and tetraploid progenitors, and their corresponding reference genome sequences. Individual-strand base equality rule and [AT]-increase pattern remain in recently formed hexaploid species bread wheat at the genome, subgenome, chromosome, and polymorphic site levels. However, D subgenome showed the fastest [AT]-increase across polymorphic site from Aegilops tauschii to bread wheat than that on A and B subgenomes from wild emmer to bread wheat. The fastest [AT]-increase could be detected almost all chromosome windows on D subgenome, suggesting different mechanisms between D and other two subgenomes. Interestingly, the [AT]-increase is mainly contributed by intergenic regions at non-selective sweeps, especially the fastest [AT]-increase of D subgenome. Further transition frequency and sequence context analysis indicated that three subgenomes shared same mutation type, but D subgenome owns the highest mutation rate on high-frequency mutation type. The highest mutation rate on D subgenome was further confirmed by using a bread-wheat-private SNP set. The exploration of loci/genes related to the [AT] value of D subgenome suggests the fastest [AT]-increase of D subgenome could be involved in DNA repair systems distributed on three subgenomes of bread wheat. Conclusions The highest mutation rate is detected on D subgenome of bread wheat during domestication after allopolyploidization, leading to the fastest [AT]-increase pattern of D subgenome. The phenomenon may come from the joint action of multiple repair systems inherited from its wild progenitors.

Published

2020

15. Selective and comparative genome architecture of Asian cultivated rice (Oryza sativa L.) attributed to domestication and modern breeding

Author

Xueqiang Wang, Wensheng Wang, Shuaishuai Tai, Min Li, Qiang Gao, Zhiqiang Hu, Wushu Hu, Zhichao Wu, Xiaoyang Zhu, Jianyin Xie, Fengmei Li, Zhifang Zhang, Linran Zhi, Fan Zhang, Xiaoqian Ma, Ming Yang, Jiabao Xu, Yanhong Li, Wenzhuo Zhang, Xiyu Yang, Ying Chen, Yan Zhao, Binying Fu, Xiuqin Zhao, Jinjie Li, Miao Wang, Zhen Yue, Xiaodong Fang, Wei Zeng, Ye Yin, Gengyun Zhang, Jianlong Xu, Hongliang Zhang, Zichao Li, and Zhikang Li

Subjects

Multidisciplinary

Abstract

Rice, Oryza sativa L. (Os), is one of the oldest domesticated cereals that has also gone through extensive improvement in modern breeding.How rice was domesticated and impacted by modern breeding.We performed comprehensive analyses of genomic sequences of 504 accessions of Os and 456 accessions of O. rufipogon/O. nivara (Or).The natural selection on Or before domestication and the natural and artificial selection during domestication together shaped the well-differentiated genomes of two subspecies, geng(j) (japonica) and xian(i) (indica), while breeding has made apparent genomic imprints between landrace and modern varieties of each subspecies, and also between primary modern and advanced modern varieties of xian(i). Selection during domestication and breeding left genome-wide selective signals covering ∼ 22.8 % and ∼ 8.6 % of the Os genome, significantly reduced within-population genomic diversity by ∼ 22 % in xian(i) and ∼ 53 % in geng(j) plus more pronounced subspecific differentiation. Only ∼ 10 % reduction in the total genomic diversity was observed between the Os and Or populations, indicating domestication did not suffer severe genetic bottleneck.Our results revealed clear differentiation of the Or accessions into three large populations, two of which correspond to the well-differentiated Os subspecies, geng(j) and xian(i). Improved productivity and common changes in the same suit of adaptive traits in xian(i) and geng(j) during domestication and breeding resulted apparently from compensatory and convergent selections for different genes/alleles acting in the common KEGG terms and/or same gene families, and thus maintaining or even increasing the within population diversity and subspecific differentiation of Os, while more genes/alleles of novel function were selected during domestication than modern breeding. Our results supported the multiple independent domestication of Os in Asia and suggest the more efficient utilization of the rich diversity within Os by exploiting inter-subspecific and among population diversity in future rice improvement.

Published

2022

16. GWAS-assisted genomic prediction of cadmium accumulation in maize kernel with machine learning and linear statistical methods

Author

Huili Yan, Hanyao Guo, Wenxiu Xu, Changhua Dai, Wilson Kimani, Jianyin Xie, Hezifan Zhang, Ting Li, Feng Wang, Yijun Yu, Mi Ma, Zhuanfang Hao, and Zhenyan He

Subjects

Environmental Engineering, Health, Toxicology and Mutagenesis, Environmental Chemistry, Pollution, Waste Management and Disposal

Published

2023

17. Large scale genomic and transcriptomic profiles of rice hybrids revealed a novel universal mechanism underlying yield heterosis

Author

Xueqiang Wang, Yan Zhao, Jianyin Xie, Linran Zhi, Hongliang Zhang, Tao Yang, Zhanying Zhang, Quan Zhang, Xiaoyang Zhu, Ziding Zhang, Feimei Li, Zhifang Zhang, Xiaoqian Ma, Yan Liu, Weiping Wang, Xuewei Jia, Shuyang Zhang, Ninjia Jiang, Gangling Li, Jieyu Zhou, Ni Li, Jinjie Li, and Zichao Li

Subjects

Transcriptome, Mechanism (biology), Heterosis, Yield (chemistry), food and beverages, Computational biology, Biology, Hybrid

Abstract

The utilization of heterosis (or hybrid vigor) is a revolutionary technology in agricultural. However, its genetic mechanisms are still unclear in plants. Here we develop, sequence and record the phenotypes of 418 hybrids from crosses between two testers and a diverse mini core collection. Phenotypic analysis showed that heterosis is an extensive but not necessary phenomenon, which varied by combinations and environments. Evidence from both GWAS on the 418 hybrids and their parents and transcriptomics of the traditional rice hybrid Liangyoupei 9, indicated that dominance and overdominance are the main genetic contributions to heterosis. Furthermore, cumulation or complementation of repulsive genetic factors may account for 37.8% of the overdominant QTL and nearly half of the genes with overdominant expression pattern. We systematically compared non-additive and additive factors and observed a common phenomenon that non-additive factors are more sensitive to background than that of additive ones across species, phenotypes, QTLs and transcription levels, further evidence from both simulations and experiment demonstrated a novel universal molecular mechanism underlying heterosis, i.e. homo-insufficiency under insufficient background (HoIIB), which expounds that heterosis in most cases is not the heterozygote advantage but the homozygote disadvantage under the insufficient genetic background. The HoIIB model can explain most known hypotheses and phenomena about heterosis, thus provides a novel theory for future hybrid rice breeding.

Published

2021

18. Genetic architecture to cause dynamic change in tiller and panicle numbers revealed by genome-wide association study and transcriptome profile in rice

Author

Jianyin Xie, Xiaoyang Zhu, Xiaoqian Ma, Hongliang Zhang, Haifeng Guo, Zhanying Zhang, Quan Zhang, Najeeb Ullah Khan, Fengmei Li, Zichao Li, Xueqiang Wang, and Jinjie Li

Subjects

0106 biological sciences, 0301 basic medicine, Candidate gene, Quantitative Trait Loci, Genome-wide association study, Plant Science, Flowers, Biology, Quantitative trait locus, Genes, Plant, 01 natural sciences, Transcriptome, 03 medical and health sciences, Quantitative Trait, Heritable, Gene Expression Regulation, Plant, Genetics, Gene, Panicle, Genetic association, Plant Stems, Chromosome Mapping, Oryza, Cell Biology, Genetic architecture, 030104 developmental biology, 010606 plant biology & botany, Genome-Wide Association Study

Abstract

Panicle number (PN) is one of the three yield components in rice. As one of the most unstable traits, the dynamic change in tiller number (DCTN) may determine the final PN. However, the genetic basis of DCTN and its relationship with PN remain unclear. Here, 377 deeply re-sequenced rice accessions were used to perform genome-wide association studies (GWAS) for tiller/PN. It was found that the DCTN pattern rather than maximum tiller number or effective tiller ratio is the determinant factor of high PN. The DCTN pattern that affords more panicles exhibits a period of stable tillering peak between 30 and 45 days after transplant (called DT30 and DT45, respectively), which was believed as an ideal pattern contributing to the steady transition from tiller development to panicle development (ST-TtP). Consistently, quantitative trait loci (QTL) expressed near DT30-DT45 were especially critical to the rice DCTN and in supporting the ST-TtP. The spatio-temporal expression analysis showed that the expression pattern of keeping relatively high expression in root at 24:00 (R24-P2) from about DT30 to DT45 is a typical expression pattern of cloned tiller genes, and the candidate genes with R24-P2 can facilitate the prediction of PN. Moreover, gene OsSAUR27 was identified by an integrated approach combining GWAS, bi-parental QTL mapping and transcription. These findings related to the genetic basis underlying the DCTN will provide the genetic theory in making appropriate decisions on field management, and in developing new varieties with high PN and ideal dynamic plant architecture.

Published

2020

19. Identifying natural genotypes of grain number per panicle in rice (Oryza sativa L.) by association mapping

Author

Zhifang Zhang, Hongliang Zhang, Xiaoqian Ma, Xiaoyang Zhu, Quan Zhang, Jianyin Xie, Jinjie Li, Shuyang Zhang, Zhanying Zhang, Fengmei Li, Najeeb Ullah Khan, Zichao Li, Xueqiang Wang, and Yan Zhao

Subjects

0106 biological sciences, 0301 basic medicine, Genotype, Quantitative Trait Loci, Biology, Quantitative trait locus, complex mixtures, 01 natural sciences, Biochemistry, Japonica, 03 medical and health sciences, Genetics, Cultivar, Association mapping, Molecular Biology, Ecosystem, Panicle, Oryza sativa, fungi, food and beverages, Oryza, biology.organism_classification, Genotype frequency, Plant Breeding, Horticulture, 030104 developmental biology, Edible Grain, Genome-Wide Association Study, 010606 plant biology & botany

Abstract

As one of the main yield components, grain number per panicle (GNP) played critical role in the rice yield improvement. The identification of natural advantageous variations under different situations will promote the sustainable genetic improvement in rice yield. This study was designed to identify natural genotypes in a rice mini-core collection, to examine the genotypic effects across the indica and japonica genetic background in different environments, and excavating the superior genotypes that had drove the modern genetic improvement. The association mapping of GNP was carried out using a mini-core collection including 154 indica and 119 japonica accessions in seven different environments. Genotypic effects of each genotype for each QTL were calculated and genotype frequency distortion between the commercial rice cultivars and landraces was screened by χ2-test. In total, 74 QTLs containing stable and sensitive QTLs in various environments were detected. Within them, 20 positive and 24 negative genotypes in indica, and 24 positive and 16 negative genotypes in japonica were identified. When checking the accumulation of positive genotypes identified in indica across cultivars in each of the two subspecies, it indicated that increased number of positive genotypes identified in indica results in the substantially increased GNP in both indica and japonica across all of the environments, while this trend was not obvious for the positive genotypes identified in japonica especially in short day environments. Moreover, the positive and negative genotype frequency distortion between the landraces and commercial rice cultivars indicated that both positive selection of positive genotypes and negative selection of negative genotypes had driven the genetic improvement on GNP. Our findings suggested that the accumulation of positive genotypes and purifying negative genotypes played equivalently important roles in the improvement of rice yield, but the efficient use for some QTLs or genotypes depends on the comprehensive evaluation of their effect under diverse genetic backgrounds and environments.

Published

2018

20. Author Correction: Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspecies

Author

Xiaoyang Zhu, Zhenyan He, Jianyin Xie, Xiuni Lin, Xu Chen, Yiwei Gao, Fengmei Li, Lulu Wu, Caiyan Chen, Mi Ma, Huili Yan, Wenxiu Xu, Xueqiang Wang, Tian Zhang, Liang Sun, Lu Feng, Zichao Li, Jinjie Li, Changhua Dai, Hongliang Zhang, Ting Li, and Zhanying Zhang

Subjects

Genetics, Cadmium, Multidisciplinary, Science, General Physics and Astronomy, chemistry.chemical_element, General Chemistry, Biology, Subspecies, General Biochemistry, Genetics and Molecular Biology, Major facilitator superfamily, Variation (linguistics), chemistry, lcsh:Q, lcsh:Science, Gene, Differential (mathematics)

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2019

21. Loci and natural alleles underlying robust roots and adaptive domestication of upland ecotype rice in aerobic conditions

Author

Haiyan Xiong, Guoyou Ye, Yan Zhao, Xueqiang Wang, Zhiqiang Hu, Wensheng Wang, Zhikang Li, Yan Guo, Jianyin Xie, Conghui Jiang, Jinjie Li, Yang Li, Zichao Li, Zhao Weipeng, Binying Fu, Jianlong Xu, Muhammad Rashid, Xiaoyang Zhu, Hongliang Zhang, and Zhigang Yin

Subjects

0106 biological sciences, 0301 basic medicine, Cancer Research, Heredity, Protein Expression, 01 natural sciences, Plant Roots, Japonica, Nucleotide diversity, Domestication, Gene Frequency, Genetics (clinical), Phylogeny, Genetics, education.field_of_study, biology, Ecotype, food and beverages, Eukaryota, Chromosome Mapping, Genomics, Gene Pool, Plants, Adaptation, Physiological, Genetic Mapping, Phenotypes, Experimental Organism Systems, Gene pool, Research Article, DNA, Bacterial, lcsh:QH426-470, Population, Quantitative Trait Loci, Quantitative trait locus, Research and Analysis Methods, Polymorphism, Single Nucleotide, 03 medical and health sciences, Genetic linkage, Plant and Algal Models, Exome Sequencing, Genome-Wide Association Studies, Gene Expression and Vector Techniques, Grasses, education, Molecular Biology Techniques, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Alleles, Genetic Association Studies, Evolutionary Biology, Molecular Biology Assays and Analysis Techniques, Population Biology, Haplotype, Organisms, Biology and Life Sciences, Computational Biology, Human Genetics, Oryza, biology.organism_classification, Genome Analysis, lcsh:Genetics, 030104 developmental biology, Haplotypes, Genetic Loci, Rice, Population Genetics, 010606 plant biology & botany

Abstract

A robust (long and thick) root system is characteristic of upland japonica rice adapted to drought conditions. Using deep sequencing and large scale phenotyping data of 795 rice accessions and an integrated strategy combining results from high resolution mapping by GWAS and linkage mapping, comprehensive analyses of genomic, transcriptomic and haplotype data, we identified large numbers of QTLs affecting rice root length and thickness (RL and RT) and shortlisted relatively few candidate genes for many of the identified small-effect QTLs. Forty four and 97 QTL candidate genes for RL and RT were identified, and five of the RL QTL candidates were validated by T-DNA insertional mutation; all have diverse functions and are involved in root development. This work demonstrated a powerful strategy for highly efficient cloning of moderate- and small-effect QTLs that is difficult using the classical map-based cloning approach. Population analyses of the 795 accessions, 202 additional upland landraces, and 446 wild rice accessions based on random SNPs and SNPs within robust loci suggested that there could be much less diversity in robust-root candidate genes among upland japonica accessions than in other ecotypes. Further analysis of nucleotide diversity and allele frequency in the robust loci among different ecotypes and wild rice accessions showed that almost all alleles could be detected in wild rice, and pyramiding of robust-root alleles could be an important genetic characteristic of upland japonica. Given that geographical distribution of upland landraces, we suggest that during domestication of upland japonica, the strongest pyramiding of robust-root alleles makes it a unique ecotype adapted to aerobic conditions., Author summary Asian cultivated rice is well-known for its rich-within-species diversity with two major subspecies, indica and japonica and subpopulation differentiation. A robust (long and thick) root system that is characteristic of upland japonica rice represents a predominant ecotype grown under aerobic and rain-fed conditions. In this study, we identified candidate genes for root length and root thickness, and validated five root length candidates by T-DNA insertional mutations. Further analyses of an Asian cultivated and wild rice population were performed based on random SNPs and SNPs within robust loci. The findings hold promise for application in improving drought resistance and also reveal the adaptive domestication history of upland rice as a unique Asian cultivated rice ecotype.

Published

2018

22. Genetic Basis Underlying Correlations Among Growth Duration and Yield Traits Revealed by GWAS in Rice (Oryza sativa L.)

Author

Zichao Li, Jianyin Xie, Xiaoyang Zhu, Zhanying Zhang, Muhammad Rashid, Xueqiang Wang, Shuyang Zhang, Zhifang Zhang, Xiaoqian Ma, Yan Zhao, Linran Zhi, Hongliang Zhang, Jinjie Li, and Fengmei Li

Subjects

0301 basic medicine, Genetics, Linkage disequilibrium, pleiotropic gene, gene interaction, Single-nucleotide polymorphism, Genome-wide association study, Plant Science, lcsh:Plant culture, Quantitative trait locus, Biology, pleiotropic QTL, genetic correlation, Genetic correlation, 03 medical and health sciences, 030104 developmental biology, Gene interaction, lcsh:SB1-1110, Gene, genome wide association study, Original Research, Panicle

Abstract

Avoidance of disadvantageous genetic correlations among growth duration and yield traits is critical in developing crop varieties that efficiently use light and energy resources and produce high yields. To understand the genetic basis underlying the correlations among heading date and three major yield traits in rice, we investigated the four traits in a diverse and representative core collection of 266 cultivated rice accessions in both long-day and short-day environments, and conducted the genome-wide association study using 4.6 million single nucleotide polymorphisms (SNPs). There were clear positive correlation between heading date and grain number per panicle, and negative correlation between grain number per panicle and panicle number, as well as different degrees of correlations among other traits in different subspecies and environments. We detected 47 pleiotropic genes in 15 pleiotropic quantitative trait loci (pQTLs), 18 pleiotropic genes containing 37 pleiotropic SNPs in 8 pQTLs, 27 pQTLs with r2 of linkage disequilibrium higher than 0.2, and 39 pairs of interactive genes from 8 metabolic pathways that may contribute to the above phenotypic correlations, but these genetic bases were different for correlations among different traits. Distributions of haplotypes revealed that selection for pleiotropic genes or interactive genes controlling different traits focused on genotypes with weak effect or on those balancing two traits that maximized production but sometimes their utilization strategies depend on the traits and environment. Detection of pQTLs and interactive genes and associated molecular markers will provide an ability to overcome disadvantageous correlations and to utilize the advantageous correlations among traits through marker-assisted selection in breeding.

Published

2018

23. Genetic Architecture and Candidate Genes for Deep-Sowing Tolerance in Rice Revealed by Non-syn GWAS

Author

Yanfa Chen, Muhammad Rashid, Conghui Jiang, Xin Wang, Yan Zhao, Hongliang Zhang, Zichao Li, Jianyin Xie, Yinghua Pan, Zhao Weipeng, Elena Todorovska, Xiaoning Wang, Huaiyang Xiong, Zhigang Yin, and Jinjie Li

Subjects

0106 biological sciences, 0301 basic medicine, Candidate gene, Oryza sativa, Single-nucleotide polymorphism, Genome-wide association study, Plant Science, lcsh:Plant culture, Biology, mesocotyl length, 01 natural sciences, 03 medical and health sciences, SNP, lcsh:SB1-1110, Allele, Original Research, Genetics, genome-wide association study, Haplotype, food and beverages, deep-sowing tolerance, Genetic architecture, 030104 developmental biology, non-synonymous SNP, 010606 plant biology & botany

Abstract

Dry direct-seeding of rice is rapidly increasing in China, but variable planting depth associated with machine sowing can lead to low seedling emergence rates. Phenotype analysis of 621 rice accessions showed that mesocotyl length (ML) was induced by deep soil covering and was important in deep-sowing tolerance in the field. Here, we performed and compared GWAS using three types of SNPs (non-synonymous SNP, non-synonymous SNPs and SNPs within promoters and 3 million randomly selected SNPs from the entire set of SNPs) and found that Non-Syn GWAS (GWAS using non-synonyomous SNP) decreased computation time and eliminated confounding by other loci relative to GWAS using randomly selected SNPs. Thirteen QTLs were finally detected, and two new major-effect genes, named OsML1 and OsML2, were identified by an integrated analysis. There were 2 and 7 non-synonymous SNPs in OsML1 and OsML2, respectively, from which 3 and 4 haplotypes were detected in cultivated rice. Combinations of superior haplotypes of OsML1 and OsML2 increased ML by up to 4 cm, representing high emergence rate (85%) in the field with 10 cm of soil cover. The studies provide key loci and naturally occurring alleles of ML that can be used in improving tolerance to dry direct-seeding.

Published

2018

24. Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspecies

Author

Tian Zhang, Hongliang Zhang, Xueqiang Wang, Jianyin Xie, Changhua Dai, Xiaoyang Zhu, Ting Li, Huili Yan, Lu Feng, Yiwei Gao, Zhenyan He, Zhanying Zhang, Xiuni Lin, Lulu Wu, Xu Chen, Wenxiu Xu, Fengmei Li, Zichao Li, Caiyan Chen, Liang Sun, Jinjie Li, and Mi Ma

Subjects

0301 basic medicine, General Physics and Astronomy, 02 engineering and technology, Subspecies, Plant Roots, Genome-wide association studies, Japonica, Plant breeding, Soil Pollutants, Cultivar, lcsh:Science, Phylogeny, Cadmium, Multidisciplinary, food and beverages, Valine, 021001 nanoscience & nanotechnology, Asparagine, 0210 nano-technology, Agricultural genetics, Science, Mutation, Missense, chemistry.chemical_element, Biology, Polymorphism, Single Nucleotide, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Phylogenetics, Botany, parasitic diseases, Humans, Allele, Author Correction, Gene, Alleles, Abiotic, fungi, Cell Membrane, Membrane Proteins, Oryza, General Chemistry, biology.organism_classification, Major facilitator superfamily, 030104 developmental biology, chemistry, lcsh:Q, Edible Grain

Abstract

Cadmium (Cd) accumulation in rice grain poses a serious threat to human health. While several transport systems have been reported, the complicity of rice Cd transport and accumulation indicates the necessity of identifying additional genes, especially those that are responsible for Cd accumulation divergence between indica and japonica rice subspecies. Here, we show that a gene, OsCd1, belonging to the major facilitator superfamily is involved in root Cd uptake and contributes to grain accumulation in rice. Natural variation in OsCd1 with a missense mutation Val449Asp is responsible for the divergence of rice grain Cd accumulation between indica and japonica. Near-isogenic line tests confirm that the indica variety carrying the japonica allele OsCd1V449 can reduce the grain Cd accumulation. Thus, the japonica allele OsCd1V449 may be useful for reducing grain Cd accumulation of indica rice cultivars through breeding., Grain of indica rice accumulates more toxic cadmium (Cd) than japonica, but the underlying genetic basis is unclear. Here, the authors show that natural variation of OsCd1 contributes to divergence in grain Cd accumulation and transferring japonica allele to indica rice leads to reduced Cd accumulation.

Published

2017

25. A New Integrated Algorithm of Structure Determination and Parameter Estimation for Nonlinear Systems Identification

Author

Jianyin Xie and Wang Xiao Wang

Subjects

Nonlinear system, Identification (information), Estimation theory, Computer science, Structure (category theory), Algorithm

Abstract

A new integrated algorithm of structure determination and parameter estimation is proposed for nonlinear systems identification in this paper, which is based on the Householder Transformation (HT), Givens and Modified Gram-Schmidt (MGS) algorithms. While being used for the polynomial and rational NARMAX model identification, it can select the model terms while deleting the unimportant ones from the assumed full model, avoiding the storage difficulty as the CGS identification algorithm does which is proposed by Billings et. al., and is numerically more stable. Combining the H algorithm with the modified bidiagonalization least squares (MBLS) algorithm and the singular value decomposition (SVD) method respectively, two algorithms referred to as the MBLSHT and SVDHT ones are proposed for the polynomial and rational NARMAX model identification. They are all numerically more stable than the HT or Givens or MGS algorithm given in this paper, and the MBLSHT algorithm has the best performance. A higher precision for the parameter estimation can thus be obtained by them, as supported b simulation results.

Published

1999