Your search keyword '"Yan, Jianbing"' showing total 23 results

1. Beyond pathways: genetic dissection of tocopherol content in maize kernels by combining linkage and association analyses.

Author

Wang, Hong, Xu, Shutu, Fan, Yaming, Liu, Nannan, Zhan, Wei, Liu, Haijun, Xiao, Yingjie, Li, Kun, Pan, Qingchun, Li, Wenqiang, Deng, Min, Liu, Jie, Jin, Min, Yang, Xiaohong, Li, Jiansheng, Li, Qing, and Yan, Jianbing

Subjects

CORN genetics, VITAMIN E content of plants, LINKAGE (Genetics), CHLOROPLASTS, FATTY acids, PHYSIOLOGY, PLANTS

Abstract

Summary: Although tocopherols play an important role in plants and animals, the genetic architecture of tocopherol content in maize kernels has remained largely unknown. In this study, linkage and association analyses were conducted to examine the genetic architecture of tocopherol content in maize kernels. Forty‐one unique quantitative trait loci (QTLs) were identified by linkage mapping in six populations of recombinant inbred lines (RILs). In addition, 32 significant loci were detected via genome‐wide association study (GWAS), 18 of which colocalized with the QTLs identified by linkage mapping. Fine mapping of a major QTL validated the accuracy of GWAS and QTL mapping results and suggested a role for nontocopherol pathway genes in the modulation of natural tocopherol variation. We provided genome‐wide evidence that genes involved in fatty acid metabolism, chlorophyll metabolism and chloroplast function may affect natural variation in tocopherols. These findings were confirmed through mutant analysis of a particular gene from the fatty acid pathway. In addition, the favourable alleles for many of the significant SNPs/QTLs represented rare alleles in natural populations. Together, our results revealed many novel genes that are potentially involved in the variation of tocopherol content in maize kernels. Pyramiding of the favourable alleles of the newly elucidated genes and the well‐known tocopherol pathway genes would greatly improve tocopherol content in maize. [ABSTRACT FROM AUTHOR]

Published

2018

2. Genome-Wide Association Study of Haploid Male Fertility in Maize (<italic>Zea Mays L</italic>.).

Author

Ma, Hailin, Li, Guoliang, Würschum, Tobias, Zhang, Yao, Zheng, Debo, Yang, Xiaohong, Li, Jiansheng, Liu, Wenxin, Yan, Jianbing, and Chen, Shaojiang

Subjects

HAPLOIDY, CORN genetics, CORN breeding

Abstract

Large-scale application of the doubled haploid (DH) technology by in vivo haploid induction has greatly improved the efficiency of maize breeding. While the haploid induction rate and the efficiency of identifying haploid plants have greatly improved in recent years, the low efficiency of doubling of haploid plants has remained and currently presents the main limitation to maize DH line production. In this study, we aimed to assess the available genetic variation for haploid male fertility (HMF), i.e., the production of fertile pollen on haploid plants, and to investigate the underlying genetic architecture. To this end, a diversity panel of 481 maize inbred lines was crossed with “Mo17” and “Zheng58,” the F1 hybrids subjected to haploid induction, and resulting haploid plants assessed for male fertility in two environments. Across both genetic backgrounds, we observed a large variation of HMF ranging from zero to ~60%, with a mean of 18%, and a heritability of 0.65. HMF was higher in the “Mo17” than in the “Zheng58” background and the correlation between both genetic backgrounds was 0.68. Genome-wide association mapping identified only few putative QTL that jointly explained 22.5% of the phenotypic variance. With the exception of one association explaining 11.77% of the phenotypic variance, all other putative QTL were of minor importance. A genome-wide prediction approach further corroborated the quantitative nature of HMF in maize. Analysis of the 14 significantly associated SNPs revealed several candidate genes. Collectively, our results illustrate the large variation of HMF that can be exploited for maize DH breeding. Owing to the apparent genetic complexity of this trait, this might best be achieved by rapid recurrent phenotypic selection coupled with marker-assisted selection for individual QTL. [ABSTRACT FROM AUTHOR]

Published

2018

3. ZmCOL3, a CCT gene represses flowering in maize by interfering with the circadian clock and activating expression of ZmCCT.

Author

Jin, Minliang, Liu, Xiangguo, Jia, Wei, Liu, Haijun, Li, Wenqiang, Peng, Yong, Du, Yanfang, Wang, Yuebin, Yin, Yuejia, Zhang, Xuehai, Liu, Qing, Deng, Min, Li, Nan, Cui, Xiyan, Hao, Dongyun, and Yan, Jianbing

Subjects

CORN genetics, GENETIC repressors, FLOWERING time, CIRCADIAN rhythms, PHYSIOLOGICAL adaptation, LOCUS (Genetics), PLANT gene mapping, PLANTS

Abstract

Abstract: Flowering time is a trait vital to the adaptation of flowering plants to different environments. Here, we report that CCT domain genes play an important role in flowering in maize (Zea mays L.). Among the 53 CCT family genes we identified in maize, 28 were located in flowering time quantitative trait locus regions and 15 were significantly associated with flowering time, based on candidate‐gene association mapping analysis. Furthermore, a CCT gene named ZmCOL3 was shown to be a repressor of flowering. Overexpressing ZmCOL3 delayed flowering time by approximately 4 d, in either long‐day or short‐day conditions. The absence of one cytosine in the ZmCOL3 3'UTR and the presence of a 551 bp fragment in the promoter region are likely the causal polymorphisms contributing to the maize adaptation from tropical to temperate regions. We propose a modified model of the maize photoperiod pathway, wherein ZmCOL3 acts as an inhibitor of flowering either by transactivating transcription of ZmCCT, one of the key genes regulating maize flowering, or by interfering with the circadian clock. [ABSTRACT FROM AUTHOR]

Published

2018

4. Patterns of genomic variation in Chinese maize inbred lines and implications for genetic improvement.

Author

Zhang, Renyu, Xu, Gen, Li, Jiansheng, Yan, Jianbing, Li, Huihui, and Yang, Xiaohong

Subjects

CORN breeding, CORN genetics, PLANT genomes, GERMPLASM of corn, PLANT enzymes

Abstract

Key message: Genetic relationships among Chinese maize germplasms reveal historical trends in heterotic patterns from Chinese breeding programs and identify line Dan340 as a potential genome donor for elite inbred line Zheng58.Abstract: The characterization of the genetic relationships, heterotic patterns and breeding history of lines in maize breeding programs allows breeders to efficiently use maize germplasm for line improvement over time. In this study, 269 temperate inbred lines, most of which have been widely used in Chinese maize breeding programs since the 1970s, were genotyped using the Illumina MaizeSNP50 BeadChip, which contains 56,110 single-nucleotide polymorphisms. The STRUCTURE analysis, cluster analysis and principal coordinate analysis results consistently revealed seven groups, of which five were consistent with known heterotic groups within the Chinese maize germplasm—Domestic Reid, Lancaster, Zi330, Tang SPT and Tem-tropic I (also known as “P”). These genetic relationships also allowed us to determine the historical trends in heterotic patterns during the three decades from 1970 to 2000, represented by Mo17 from Lancaster, HuangZaoSi (HZS) from Tang SPT, Ye478 from Domestic Reid and P178 from Tem-tropic I heterotic groups. Mo17-related commercial hybrids were widely used in the 1970s and 1980s, followed by the release of HZS- and Ye478-related commercial hybrids in the 1980s and 1990s, and the introduction of Tem-tropic I group in the 1990s and 2000s. Additionally, we identified inbred line Dan340 as a potential genome donor for Zheng58, which is the female parent of the most widely grown commercial hybrid ZhengDan958 in China. We also reconstructed the recombination events of elite line HZS and its 14 derived lines. These findings provide useful information to direct future maize breeding efforts. [ABSTRACT FROM AUTHOR]

Published

2018

5. An integrated multi‐layered analysis of the metabolic networks of different tissues uncovers key genetic components of primary metabolism in maize.

Author

Wen, Weiwei, Jin, Min, Li, Kun, Liu, Haijun, Xiao, Yingjie, Zhao, Mingchao, Alseekh, Saleh, Li, Wenqiang, de Abreu e Lima, Francisco, Brotman, Yariv, Willmitzer, Lothar, Fernie, Alisdair R., and Yan, Jianbing

Subjects

CORN metabolism, CORN genetics, PLANT genes, GENETIC transcription in plants, TREHALOSE

Abstract

SUMMARY: Primary metabolism plays a pivotal role in normal plant growth, development and reproduction. As maize is a major crop worldwide, the primary metabolites produced by maize plants are of immense importance from both calorific and nutritional perspectives. Here a genome‐wide association study (GWAS) of 61 primary metabolites using a maize association panel containing 513 inbred lines identified 153 significant loci associated with the level of these metabolites in four independent tissues. The genome‐wide expression level of 760 genes was also linked with metabolite levels within the same tissue. On average, the genetic variants at each locus or transcriptional variance of each gene identified here were estimated to have a minor effect (4.4–7.8%) on primary metabolic variation. Thirty‐six loci or genes were prioritized as being worthy of future investigation, either with regard to functional characterization or for their utility for genetic improvement. This target list includes the well‐known opaque 2 (O2) and lkr/sdh genes as well as many less well‐characterized genes. During our investigation of these 36 loci, we analyzed the genetic components and variations underlying the trehalose, aspartate and aromatic amino acid pathways, thereby functionally characterizing four genes involved in primary metabolism in maize. [ABSTRACT FROM AUTHOR]

Published

2018

6. Circular RNAs mediated by transposons are associated with transcriptomic and phenotypic variation in maize.

Author

Chen, Lu, Zhang, Pei, Fan, Yuan, Lu, Qiong, Li, Qing, Yan, Jianbing, Muehlbauer, Gary J., Schnable, Patrick S., Dai, Mingqiu, and Li, Lin

Subjects

CIRCULAR RNA, GENOMICS, TRANSPOSONS, PHENOTYPES, CORN genetics

Abstract

Summary: Circular RNAs (circRNAs) are covalently closed RNA molecules. Recent studies have shown that circRNAs can arise from the transcripts of transposons. Given the prevalence of transposons in the maize genome and dramatic genomic variation driven by transposons, we hypothesize that transposons in maize may be involved in the formation of circRNAs and further modulate phenotypic variation. We performed circRNA‐Seq on B73 seedling leaves and uncovered 2804 high‐confidence maize circRNAs, which show distinct genomic features. Comprehensive analyses demonstrated that sequences related to LINE1‐like elements (LLEs) and their Reverse Complementary Pairs (LLERCPs) are significantly enriched in the flanking regions of circRNAs. Interestingly, as the number of LLERCPs increase, the accumulation of circRNAs varies, whereas that of linear transcripts decreases. Furthermore, genes with LLERCP‐mediated circRNAs are enriched among loci that are associated with phenotypic variation. These results suggest that circRNAs are likely to be involved in the modulation of phenotypic variation by LLERCPs. Further, we showed that the presence/absence variation of LLERCPs was associated with expression variation of circRNA‐circ1690 and was related to ear height, potentially through the interplay between circRNAs and functional linear transcripts. Our first study of maize circRNAs uncovers a potential new way for transposons to modulate transcriptomic and phenotypic variations. [ABSTRACT FROM AUTHOR]

Published

2018

7. Multi-environment QTL analysis of grain morphology traits and fine mapping of a kernel-width QTL in Zheng58 × SK maize population.

Author

Raihan, Mohammad, Liu, Jie, Huang, Juan, Guo, Huan, Pan, Qingchun, and Yan, Jianbing

Subjects

CORN yields, CORN breeding, CORN genetics, PLANT morphology, LOCUS (Genetics), PLANT gene mapping

Abstract

Key message: Sixteen major QTLs regulating maize kernel traits were mapped in multiple environments and one of them, qKW - 9.2 , was restricted to 630 Kb, harboring 28 putative gene models. Abstract: To elucidate the genetic basis of kernel traits, a quantitative trait locus (QTL) analysis was conducted in a maize recombinant inbred line population derived from a cross between two diverse parents Zheng58 and SK, evaluated across eight environments. Construction of a high-density linkage map was based on 13,703 single-nucleotide polymorphism markers, covering 1860.9 cM of the whole genome. In total, 18, 26, 23, and 19 QTLs for kernel length, width, thickness, and 100-kernel weight, respectively, were detected on the basis of a single-environment analysis, and each QTL explained 3.2-23.7 % of the phenotypic variance. Sixteen major QTLs, which could explain greater than 10 % of the phenotypic variation, were mapped in multiple environments, implying that kernel traits might be controlled by many minor and multiple major QTLs. The major QTL qKW- 9.2 with physical confidence interval of 1.68 Mbp, affecting kernel width, was then selected for fine mapping using heterogeneous inbred families. At final, the location of the underlying gene was narrowed down to 630 Kb, harboring 28 putative candidate-gene models. This information will enhance molecular breeding for kernel traits and simultaneously assist the gene cloning underlying this QTL, helping to reveal the genetic basis of kernel development in maize. [ABSTRACT FROM AUTHOR]

Published

2016

8. Genome-wide association studies of drought-related metabolic changes in maize using an enlarged SNP panel.

Author

Zhang, Xuehai, Warburton, Marilyn, Setter, Tim, Liu, Haijun, Xue, Yadong, Yang, Ning, Yan, Jianbing, and Xiao, Yingjie

Subjects

EFFECT of drought on corn, CORN genetics, SINGLE nucleotide polymorphisms, CORN metabolism, ABIOTIC stress, PLANT development

Abstract

Key message: Genetic determinants of metabolites related to drought tolerance in maize. Abstract: Water deficit or drought is one of the most serious abiotic stresses of plant development and greatly reduces crop production, and the plant's response to this deficit leads to many metabolic changes. To dissect the genetic basis of these metabolic traits in maize, we performed a genome-wide association analysis of drought-related traits using 156,599 SNPs in 318 maize inbred lines. In total, 123 significant SNP/trait associations ( P ≤ 6.39E−6) involving 63 loci were identified for related metabolic and physiological traits in multiple tissues and different environments under two irrigation conditions. Of the 63, 23 loci demonstrated a significant interaction effect between QTL and water status, indicating that these metabolite-associated loci were probably related to drought stress tolerance. To evaluate the potential utility of metabolite-associated loci applied in hybrid maize breeding, we assembled two groups of hybrid entries with high or low drought tolerance and measured the metabolic and physiological traits. In the hybrid pools, a set of 10 metabolite-associated loci identified in leaf and ear were validated as responsive to drought stress. The favorable alleles of these ten loci were significantly enriched in hybrids with high drought tolerance, which jointly explained almost 18.4 % of the variation in drought tolerance using a multivariate logistic regression model. These results provide clues to understanding the genetic basis of metabolic and physiological changes related to drought tolerance, potentially facilitating the genetic improvement of varieties with high drought tolerance in maize breeding programs. [ABSTRACT FROM AUTHOR]

Published

2016

9. Genome-wide recombination dynamics are associated with phenotypic variation in maize.

Author

Pan, Qingchun, Li, Lin, Yang, Xiaohong, Tong, Hao, Xu, Shutu, Li, Zhigang, Li, Weiya, Muehlbauer, Gary J., Li, Jiansheng, and Yan, Jianbing

Subjects

CORN genetics, CORN breeding, CORN farming, HYBRID corn, CHROMOSOMES

Abstract

Meiotic recombination is a major driver of genetic diversity, species evolution, and agricultural improvement. Thus, an understanding of the genetic recombination landscape across the maize ( Zea mays) genome will provide insight and tools for further study of maize evolution and improvement., Here, we used c. 50 000 single nucleotide polymorphisms to precisely map recombination events in 12 artificial maize segregating populations. We observed substantial variation in the recombination frequency and distribution along the ten maize chromosomes among the 12 populations and identified 143 recombination hot regions., Recombination breakpoints were partitioned into intragenic and intergenic events. Interestingly, an increase in the number of genes containing recombination events was accompanied by a decrease in the number of recombination events per gene. This kept the overall number of intragenic recombination events nearly invariable in a given population, suggesting that the recombination variation observed among populations was largely attributed to intergenic recombination. However, significant associations between intragenic recombination events and variation in gene expression and agronomic traits were observed, suggesting potential roles for intragenic recombination in plant phenotypic diversity., Our results provide a comprehensive view of the maize recombination landscape, and show an association between recombination, gene expression and phenotypic variation, which may enhance crop genetic improvement. [ABSTRACT FROM AUTHOR]

Published

2016

10. Genetic architecture of maize kernel row number and whole genome prediction.

Author

Liu, Lei, Du, Yanfang, Huo, Dongao, Wang, Man, Shen, Xiaomeng, Yue, Bing, Qiu, Fazhan, Zheng, Yonglian, Yan, Jianbing, and Zhang, Zuxin

Subjects

CORN genetics, KERNEL functions, PLANT genomes, PLANT yields, SINGLE nucleotide polymorphisms, QUANTITATIVE research

Abstract

Key message: Maize kernel row number might be dominated by a set of large additive or partially dominant loci and several small dominant loci and can be accurately predicted by fewer than 300 top KRN-associated SNPs. Abstract: Kernel row number (KRN) is an important yield component in maize and directly affects grain yield. In this study, we combined linkage and association mapping to uncover the genetic architecture of maize KRN and to evaluate the phenotypic predictability using these detected loci. A genome-wide association study revealed 31 associated single nucleotide polymorphisms (SNPs) representing 17 genomic loci with an effect in at least one of five individual environments and the best linear unbiased prediction (BLUP) over all environments. Linkage mapping in three F populations identified 33 KRN quantitative trait loci (QTLs) representing 21 QTLs common to several population/environments. The majority of these common QTLs that displayed a large effect were additive or partially dominant. We found 70 % KRN-associated genomic loci were mapped in KRN QTLs identified in this study, KRN-associated SNP hotspots detected in NAM population and/or previous identified KRN QTL hotspots. Furthermore, the KRN of inbred lines and hybrids could be predicted by the additive effect of the SNPs, which was estimated using inbred lines as a training set. The prediction accuracy using the top KRN-associated tag SNPs was obviously higher than that of the randomly selected SNPs, and approximately 300 top KRN-associated tag SNPs were sufficient for predicting the KRN of the inbred lines and hybrids. The results suggest that the KRN-associated loci and QTLs that were detected in this study show great potential for improving the KRN with genomic selection in maize breeding. [ABSTRACT FROM AUTHOR]

Published

2015

11. A maize wall-associated kinase confers quantitative resistance to head smut.

Author

Xu, Mingliang, Tan, Guoqing, Chen, Yongsheng, Liu, Haijun, Zuo, Weiliang, Ye, Jianrong, Zhao, Jing, Li, Bailin, Yan, Jianbing, Chao, Qing, Zhang, Nan, Zhang, Boqi, Zhao, Xianrong, Lai, Jinsheng, Xing, Yuexian, and Fengler, Kevin A

Subjects

CORN disease & pest resistance genetics, CORN disease & pest prevention, KINASE genetics, GENETIC engineering of corn, CORN genetics, CEREAL smut diseases, FUNGAL diseases of plants, PREVENTION

Abstract

Head smut is a systemic disease in maize caused by the soil-borne fungus Sporisorium reilianum that poses a grave threat to maize production worldwide. A major head smut quantitative resistance locus, qHSR1, has been detected on maize chromosome bin2.09. Here we report the map-based cloning of qHSR1 and the molecular mechanism of qHSR1-mediated resistance. Sequential fine mapping and transgenic complementation demonstrated that ZmWAK is the gene within qHSR1 conferring quantitative resistance to maize head smut. ZmWAK spans the plasma membrane, potentially serving as a receptor-like kinase to perceive and transduce extracellular signals. ZmWAK was highly expressed in the mesocotyl of seedlings where it arrested biotrophic growth of the endophytic S. reilianum. Impaired expression in the mesocotyl compromised ZmWAK-mediated resistance. Deletion of the ZmWAK locus appears to have occurred after domestication and spread among maize germplasm, and the ZmWAK kinase domain underwent functional constraints during maize evolution. [ABSTRACT FROM AUTHOR]

Published

2015

12. Genetic basis of grain yield heterosis in an 'immortalized F' maize population.

Author

Guo, Tingting, Yang, Ning, Tong, Hao, Pan, Qingchun, Yang, Xiaohong, Tang, Jihua, Wang, Jiankang, Li, Jiansheng, and Yan, Jianbing

Subjects

GRAIN yields, HETEROSIS in plants, CORN genetics, PLANT populations, PHENOTYPES, PLANT breeding, BOTANY

Abstract

Key message: Genetic basis of grain yield heterosis relies on the cumulative effects of dominance, overdominance, and epistasis in maize hybrid Yuyu22. Abstract: Heterosis, i.e., when F hybrid phenotypes are superior to those of the parents, continues to play a critical role in boosting global grain yield. Notwithstanding our limited insight into the genetic and molecular basis of heterosis, it has been exploited extensively using different breeding approaches. In this study, we investigated the genetic underpinnings of grain yield and its components using 'immortalized F' and recombinant inbred line populations derived from the elite hybrid Yuyu22. A high-density linkage map consisting of 3,184 bins was used to assess (1) the additive and additive-by-additive effects determined using recombinant inbred lines; (2) the dominance and dominance-by-dominance effects from a mid-parent heterosis dataset; and (3) the various genetic effects in the 'immortalized F' population. Compared with a low-density simple sequence repeat map, the bin map identified more quantitative trait loci, with higher LOD scores and better accuracy of detecting quantitative trait loci. The bin map showed that, among all traits, dominance was more important to heterosis than other genetic effects. The importance of overdominance/pseudo-overdominance was proportional to the amount of heterosis. In addition, epistasis contributed to heterosis as well. Phenotypic variances explained by the QTLs detected were close to the broad-sense heritabilities of the observed traits. Comparison of the analyzed results obtained for the 'immortalized F' population with those for the mid-parent heterosis dataset indicated identical genetic modes of action for mid-parent heterosis and grain yield performance of the hybrid. [ABSTRACT FROM AUTHOR]

Published

2014

13. Genome Wide Association Studies Using a New Nonparametric Model Reveal the Genetic Architecture of 17 Agronomic Traits in an Enlarged Maize Association Panel.

Author

Yang, Ning, Lu, Yanli, Yang, Xiaohong, Huang, Juan, Zhou, Yang, Ali, Farhan, Wen, Weiwei, Liu, Jie, Li, Jiansheng, and Yan, Jianbing

Subjects

CORN genetics, PLANT gene mapping, SINGLE nucleotide polymorphisms, PLANT genomes, PHENOTYPES

Abstract

Association mapping is a powerful approach for dissecting the genetic architecture of complex quantitative traits using high-density SNP markers in maize. Here, we expanded our association panel size from 368 to 513 inbred lines with 0.5 million high quality SNPs using a two-step data-imputation method which combines identity by descent (IBD) based projection and k-nearest neighbor (KNN) algorithm. Genome-wide association studies (GWAS) were carried out for 17 agronomic traits with a panel of 513 inbred lines applying both mixed linear model (MLM) and a new method, the Anderson-Darling (A-D) test. Ten loci for five traits were identified using the MLM method at the Bonferroni-corrected threshold −log10 (P) >5.74 (α = 1). Many loci ranging from one to 34 loci (107 loci for plant height) were identified for 17 traits using the A-D test at the Bonferroni-corrected threshold −log10 (P) >7.05 (α = 0.05) using 556809 SNPs. Many known loci and new candidate loci were only observed by the A-D test, a few of which were also detected in independent linkage analysis. This study indicates that combining IBD based projection and KNN algorithm is an efficient imputation method for inferring large missing genotype segments. In addition, we showed that the A-D test is a useful complement for GWAS analysis of complex quantitative traits. Especially for traits with abnormal phenotype distribution, controlled by moderate effect loci or rare variations, the A-D test balances false positives and statistical power. The candidate SNPs and associated genes also provide a rich resource for maize genetics and breeding. [ABSTRACT FROM AUTHOR]

Published

2014

14. Genome-wide association analysis for nine agronomic traits in maize under well-watered and water-stressed conditions.

Author

Xue, Yadong, Warburton, Marilyn, Sawkins, Mark, Zhang, Xuehai, Setter, Tim, Xu, Yunbi, Grudloyma, Pichet, Gethi, James, Ribaut, Jean-Marcel, Li, Wanchen, Zhang, Xiaobo, Zheng, Yonglian, and Yan, Jianbing

Subjects

CORN genetics, PLANT genomes, AGRONOMY, DROUGHT tolerance of corn, PHENOTYPES, TRANSCRIPTION factors

Abstract

Drought can cause severe reduction in maize production, and strongly threatens crop yields. To dissect this complex trait and identify superior alleles, 350 tropical and subtropical maize inbred lines were genotyped using a 1536-SNP array developed from drought-related genes and an array of 56,110 random SNPs. The inbred lines were crossed with a common tester, CML312, and the testcrosses were phenotyped for nine traits under well-watered and water-stressed conditions in seven environments. Using genome-wide association mapping with correction for population structure, 42 associated SNPs ( P ≤ 2.25 × 10 0.1/ N) were identified, located in 33 genes for 126 trait × environment × treatment combinations. Of these genes, three were co-localized to drought-related QTL regions. Gene GRMZM2G125777 was strongly associated with ear relative position, hundred kernel weight and timing of male and female flowering, and encodes NAC domain-containing protein 2, a transcription factor expressed in different tissues. These results provide some good information for understanding the genetic basis for drought tolerance and further studies on identified candidate genes should illuminate mechanisms of drought tolerance and provide tools for designing drought-tolerant maize cultivars tailored to different environmental scenarios. [ABSTRACT FROM AUTHOR]

Published

2013

15. Natural variation in the sequence of PSY1 and frequency of favorable polymorphisms among tropical and temperate maize germplasm.

Author

Fu, Zhiyuan, Chai, Yuchao, Zhou, Yi, Yang, Xiaohong, Warburton, Marilyn, Xu, Shutu, Cai, Ye, Zhang, Dalong, Li, Jiansheng, and Yan, Jianbing

Subjects

PLANT variation, NUCLEOTIDE sequence, GENETIC polymorphisms in plants, CORN genetics, GERMPLASM of corn, PROVITAMINS, IMMUNE system

Abstract

Provitamin A (Pro-VA) is necessary for human vision and immune system health, especially in growing children. The first committed step in the maize carotenoid biosynthesis pathway is catalyzed by phytoene synthase 1 (encoded by PSY1) which controls the flux of substrates into the pathway. The flow of these substrates could be directed into production of the β-branch carotenoids (the step controlled largely by the lycopene epsilon cyclase gene), but terminated after the production of β-carotene, rather than allowing it to be converted into the next metabolite (the step controlled largely by the β- carotenoid hydroxylase gene). In this study, PSY1 was subjected to association mapping in two diverse maize populations, quantitative trait loci (QTL) mapping in one segregating population, and expression analysis of lines polymorphic for sites within PSY1. The results indicated that a 378-bp InDel upstream of the transcription start site and a SNP in the fifth exon resulting in a Thr to Asn substitution, explaining 7 and 8 % of the total carotenoid variation, respectively, may be functional sites associated with total carotenoid levels in maize grain. Analysis of the evolution of PSY1 strongly suggests that there was positive selection for these polymorphic sites after the divergence of yellow maize from white maize. [ABSTRACT FROM AUTHOR]

Published

2013

16. Validation of the effects of molecular marker polymorphisms in LcyE and CrtRB1 on provitamin A concentrations for 26 tropical maize populations.

Author

Babu, Raman, Rojas, Natalia, Gao, Shibin, Yan, Jianbing, and Pixley, Kevin

Subjects

CORN genetics, GENETIC polymorphisms in plants, GENETIC markers in plants, PROVITAMINS, PLANT population genetics, VITAMIN A deficiency, PLANT breeding, CHROMOSOME segregation

Abstract

Vitamin A deficiency (VAD) compromises immune function and is the leading cause of preventable blindness in children in many developing countries. Biofortification, or breeding staple food crops that are rich in micronutrients, provides a sustainable way to fight VAD and other micronutrient malnutrition problems. Polymorphisms, with associated molecular markers, have recently been identified for two loci, LcyE (lycopene epsilon cyclase) and CrtRB1 (β-carotene hydroxylase 1) that govern critical steps in the carotenoid biosynthetic pathway in maize endosperm, thereby enabling the opportunity to integrate marker-assisted selection (MAS) into carotenoid breeding programs. We validated the effects of 3 polymorphisms (LcyE5′TE, LcyE3′Indel and CrtRB1-3′TE) in 26 diverse tropical genetic backgrounds. CrtRB1-3′TE had a two-ten fold effect on enhancing beta-carotene (BC) and total provitamin A (proA) content. Reduced-function, favorable polymorphisms within LcyE resulted in 0-30 % reduction in the ratio of alpha- to beta-branch carotenoids, and increase in proA content (sometimes statistically significant). CrtRB1-3′TE had large, significant effect on enhancing BC and total ProA content, irrespective of genetic constitution for LcyE5′TE. Genotypes with homozygous favorable CrtRB1-3′TE alleles had much less zeaxanthin and an average of 25 % less total carotenoid than other genotypes, suggesting that feedback inhibition may be reducing the total flux into the carotenoid pathway. Because this feedback inhibition was most pronounced in the homozygous favorable LcyE (reduced-function) genotypes, and because maximum total proA concentrations were achieved in genotypes with homozygous unfavorable or heterozygous LcyE, we recommend not selecting for both reduced-function genes in breeding programs. LcyE exhibited significant segregation distortion (SD) in all the eight, while CrtRB1 in five of eight digenic populations studied, with favorable alleles of both the genes frequently under-represented. MAS using markers reported herein can efficiently increase proA carotenoid concentration in maize. [ABSTRACT FROM AUTHOR]

Published

2013

17. Genome-wide association study dissects the genetic architecture of oil biosynthesis in maize kernels.

Author

Li, Hui, Peng, Zhiyu, Yang, Xiaohong, Wang, Weidong, Fu, Junjie, Wang, Jianhua, Han, Yingjia, Chai, Yuchao, Guo, Tingting, Yang, Ning, Liu, Jie, Warburton, Marilyn L, Cheng, Yanbing, Hao, Xiaomin, Zhang, Pan, Zhao, Jinyang, Liu, Yunjun, Wang, Guoying, Li, Jiansheng, and Yan, Jianbing

Subjects

CORN seeds, CORN genetics, CORN oil, BIOSYNTHESIS, GENE expression in plants, LOCUS (Genetics), PLANT gene mapping

Abstract

Maize kernel oil is a valuable source of nutrition. Here we extensively examine the genetic architecture of maize oil biosynthesis in a genome-wide association study using 1.03 million SNPs characterized in 368 maize inbred lines, including 'high-oil' lines. We identified 74 loci significantly associated with kernel oil concentration and fatty acid composition (P < 1.8 × 10?6), which we subsequently examined using expression quantitative trait loci (QTL) mapping, linkage mapping and coexpression analysis. More than half of the identified loci localized in mapped QTL intervals, and one-third of the candidate genes were annotated as enzymes in the oil metabolic pathway. The 26 loci associated with oil concentration could explain up to 83% of the phenotypic variation using a simple additive model. Our results provide insights into the genetic basis of oil biosynthesis in maize kernels and may facilitate marker-based breeding for oil quantity and quality. [ABSTRACT FROM AUTHOR]

Published

2013

18. A transposable element insertion within ZmGE2 gene is associated with increase in embryo to endosperm ratio in maize.

Author

Zhang, Pan, Allen, William, Nagasawa, Nobuhiro, Ching, Ada, Heppard, Elmer, Li, Hui, Hao, Xiaomin, Li, Xiaowei, Yang, Xiaohong, Yan, Jianbing, Nagato, Yasuo, Sakai, Hajime, Shen, Bo, and Li, Jiansheng

Subjects

CORN genetics, TRANSPOSONS, DNA insertion elements, PLANT embryology, ENDOSPERM, LINKAGE (Genetics), GENE mapping

Abstract

Most of the maize kernel oil is located in the embryo while the majority of starch is located in the endosperm. Maize kernel composition and value are affected significantly by the ratio of the embryo size to the endosperm size; however, the genetic regulation of embryo to endosperm ratio (EER) in maize is unknown. Here we identified ZmGE2 gene, which encodes a cytochrome p450 protein, as a gene associated with EER variation in maize. We first expressed rice Giant Embryo ( GE) gene driven by oleosin promoter in maize and detected a 23.2 % reduction in EER in transgenic seeds, demonstrating the existence of evolutionarily conserved mechanisms for EER determination in rice and maize. We next identified maize GE2, a homolog of rice GE sharing 70 % identity in amino sequence, as a candidate based on the similar expression pattern and co-localization with a previously detected QTL for EER. Followed by linkage and association mapping, a 247-bp transposable element (TE) insertion in 3′-untranslated region of ZmGE2 gene was identified to be associated with increase in EER and kernel oil content. Expression level of the favorable ZmGE2 allele containing the 247-bp TE insertion was strongly reduced. In addition, the 247-bp TE insertion site was a selection target during the artificial long-term selection for the high EER trait in a high oil population. This is the first report that demonstrates an association of ZmGE2 with EER variation in maize and identifies ZmGE2 gene as a promising target for manipulation of EER and grain composition by either transgenic approach or molecular breeding in maize. [ABSTRACT FROM AUTHOR]

Published

2012

19. Characterization of QTL for oil content in maize kernel.

Author

Yang, Xiaohong, Ma, Hailin, Zhang, Pan, Yan, Jianbing, Guo, Yuqiu, Song, Tongming, and Li, Jiansheng

Subjects

COMPOSITION of corn, CORN genetics, FATS & oils, PLANT metabolism, PLANT physiology, LOCUS in plant genetics, PLANT populations

Abstract

Kernel oil content in maize is a complex quantitative trait. Phenotypic variation in kernel oil content can be dissected into its component traits such as oil metabolism and physical characteristics of the kernel, including embryo size and embryo-to-endosperm weight ratio (EEWR). To characterize quantitative trait loci (QTL) for kernel oil content, a recombinant inbred population derived from a cross between normal line B73 and high-oil line By804 was genotyped using 228 molecular markers and phenotyped for kernel oil content and its component traits [embryo oil content, embryo oil concentration, EEWR, embryo volume, embryo width, embryo length, and embryo width-to-length ratio (EWLR)]. A total of 58 QTL were identified for kernel oil content and its component traits in 26 genomic regions across all chromosomes. Eight main-effect QTL were identified for kernel oil content, embryo oil content, embryo oil concentration, EEWR, embryo weight, and EWLR, each accounting for over 10 % of the phenotypic variation in six genomic regions. Over 90 % of QTL identified for kernel oil content co-localized with QTL for component traits, validating their molecular contribution to kernel oil content. On chromosome 1, the QTL that had the largest effect on kernel oil content ( qKO1- 1) was associated with embryo width; on chromosome 9, the QTL for kernel oil content ( qKO9) was related to EEWR ( qEEWR9). Embryo oil concentration and embryo width were identified as the most important component traits controlling the second largest QTL for kernel oil content on chromosome 6 ( qKO6) and a minor QTL for kernel oil content on chromosome 5 ( qKO5- 2), respectively. The dissection of kernel oil QTL will facilitate future cloning and/or functional validation of kernel oil content, and help to elucidate the genetic basis of kernel oil content in maize. [ABSTRACT FROM AUTHOR]

Published

2012

20. Genetic Characterization of a Core Set of a Tropical Maize Race Tuxpeño for Further Use in Maize Improvement.

Author

Wen, Weiwei, Franco, Jorge, Chavez-Tovar, Victor H., Yan, Jianbing, and Taba, Suketoshi

Subjects

GERMPLASM of corn, PLANT germplasm, SINGLE nucleotide polymorphisms, GENOTYPE-environment interaction, CORN genetics

Abstract

The tropical maize race Tuxpeño is a well-known race of Mexican dent germplasm which has greatly contributed to the development of tropical and subtropical maize gene pools. In order to investigate how it could be exploited in future maize improvement, a panel of maize germplasm accessions was assembled and characterized using genome-wide Single Nucleotide Polymorphism (SNP) markers. This panel included 321 core accessions of Tuxpeño race from the International Maize and Wheat Improvement Center (CIMMYT) germplasm bank collection, 94 CIMMYT maize lines (CMLs) and 54 U.S. Germplasm Enhancement of Maize (GEM) lines. The panel also included other diverse sources of reference germplasm: 14 U.S. maize landrace accessions, 4 temperate inbred lines from the U.S. and China, and 11 CIMMYT populations (a total of 498 entries with 795 plants). Clustering analyses (CA) based on Modified Rogers Distance (MRD) clearly partitioned all 498 entries into their corresponding groups. No sub clusters were observed within the Tuxpeño core set. Various breeding strategies for using the Tuxpeño core set, based on grouping of the studied germplasm and genetic distance among them, were discussed. In order to facilitate sampling diversity within the Tuxpeño core, a minicore subset of 64 Tuxpeño accessions (20% of its usual size) representing the diversity of the core set was developed, using an approach combining phenotypic and molecular data. Untapped diversity represents further use of the Tuxpeño landrace for maize improvement through the core and/or minicore subset available to the maize community. [ABSTRACT FROM AUTHOR]

Published

2012

21. Identification and characterization of CACTA transposable elements capturing gene fragments in maize.

Author

Li Qing, Li Lin, Dai JingRui, Li JianSheng, and Yan JianBing

Subjects

TRANSPOSONS, NUCLEOTIDE sequence, CORN genetics, VITAMIN E, GENOMES

Abstract

Transposable elements (TEs)-mediated gene sequence movement is thought to play an important role in genome expansion and origin of genes with novel functions. In this study, a gene, HGGT, involved in vitamin E synthesis was used in a case study to discover and characterize transposons carrying gene fragments in maize. A total of 69 transposons that are distributed across the 10 chromosomes and have an average length of 3689 bp were identified from the maize sequence database by using the BLAST search algorithm. Three of these carry gene fragments from the progenitor HGGT gene, while the rest (66) contain gene fragments from other cellular genes. Nine of the 69 transposons conthin fragments derived from two locations in the genome. By querying the maize Expressed Sequence Tag (EST) database, we found that at least thirteen out of the 69 TEs had corresponding transcripts. More interestingly, two transposons that carry gene fragments from two different chromosomal loci, could be expressed as chimeric transcripts. [ABSTRACT FROM AUTHOR]

Published

2009

22. Intraspecific variation of residual heterozygosity and its utility for quantitative genetic studies in maize.

Author

Liu, Nannan, Liu, Jianxiao, Li, Wenqiang, Pan, Qingchun, Liu, Jie, Yang, Xiaohong, Yan, Jianbing, and Xiao, Yingjie

Subjects

CORN genetics, HETEROZYGOSITY, QUANTITATIVE genetics, LOCUS in plant genetics, PLANT genomes, PLANTS

Abstract

Background: Residual heterozygosity (RH) in advanced inbred lines of plants benefits quantitative trait locus (QTL) mapping studies. However, knowledge of factors affecting the genome-wide distribution of RH remains limited. Results: A set of 2196 heterogeneous inbred family (HIF) maize lines derived from 12 recombinant inbred line (RIL) populations was genotyped using the Maize50K SNP chip. A total of 18,615 unique RH intervals were identified, ranging from 505 to 2095 intervals per population, with average maize genome coverage of 94.8%. Across all populations, there were 8.6 RH intervals per HIF line on average, ranging from 1.8 to 14 intervals; the average size of an RH interval was approximately 58.7 Mb, ranging from 7.2 to 74.1 Mb. A given RH region was present in an average of 5 different individuals within a population. Seven RH hotspots, where RH segments were enriched in the genome, were found to be subject to selection during population development. The RH patterns varied significantly across populations, presumably reflecting differences in the genetic background of each population, and 8 QTLs were found to affect heterozygosity levels in the RH hotspots. The potential use of this HIF library for the fine mapping of QTLs was assessed based on publicly available QTL information, achieving a ≤ 1 Mb resolution on average. Conclusion: The examined library of HIF lines offers insight into the RH landscape and its intraspecific variation and provides a useful resource for the QTL cloning of important agronomic traits in maize. [ABSTRACT FROM AUTHOR]

Published

2018

23. Broadening Our Portfolio in the Genetic Improvement of Maize Chemical Composition.

Author

Wen, Weiwei, Brotman, Yariv, Willmitzer, Lothar, Yan, Jianbing, and Fernie, Alisdair R.

Subjects

*COMPOSITION of corn, *CROP improvement, *INTROGRESSION (Genetics), *GENE mapping, *ESSENTIAL amino acids, *METABOLOMICS, CORN genetics

Abstract

The adoption of recombinant inbred line and introgression line populations, as well as the study of association mapping panels, has greatly accelerated our ability to identify the genes underlying plant phenotypic variance. In tandem, the development of metabolomics approaches has greatly enhanced our ability to comprehensively define cellular chemical composition. As a consequence, breeding for chemical composition is being extended beyond our traditional targets of oil and protein to include components such as essential amino acids, vitamins, and antioxidant secondary metabolites with considerable purported consequences for human health. Here, we review the above-mentioned developments paying particular attention to the genetic architecture of metabolic traits as well as updating the perspective for utilizing metabolomics in maize improvement. [ABSTRACT FROM AUTHOR]

Published

2016