Identification of candidate genes for dissecting complex branch number trait in chickpea

Bajaj, Deepak; Upadhyaya, Hari D.; Das, Shouvik; Kumar, Vinod; Gowda, C. L. L.; Sharma, Shuchi; Tyagi, Akhilesh K.; Parida, Swarup K.

doi:10.1016/j.plantsci.2016.01.004

Cited by 21 publications

(13 citation statements)

References 62 publications

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“…For GWAS of PGH traits, the genetic diversity information including phylogenetic tree, PCA (principal component analysis) and population structure among 92 chickpea accessions were obtained from our previous study (Kujur et al 2015a, c). The population structure ancestry coefficient (Q), kinship matrix (K) and PCA (P) data along with genome-wide SNP genotyping and PGH phenotyping information of 92 accessions were analysed through mixed model (P + K, K and Q + K)-based CMLM (compressed mixed linear model) and P3D (population parameters previously determined, Zhang et al 2010;Kang et al 2011)/EMMAX (efficient mixed model association eXpedited) approaches of GAPIT (Lipka et al 2012) as described previously (Kujur et al 2015a;Bajaj et al 2016;Upadhyaya et al 2015Upadhyaya et al , 2016. To ascertain the accuracy and validity of SNP marker-trait association, the observed and expected -log 10 (P) value relative distribution estimated for each PGH-associated genomic locus was compared based on quantile-quantile plot.…”

Section: Trait Association Mappingmentioning

confidence: 99%

“…To ascertain the accuracy and validity of SNP marker-trait association, the observed and expected -log 10 (P) value relative distribution estimated for each PGH-associated genomic locus was compared based on quantile-quantile plot. Subsequently, the correction of their adjusted P value threshold of significance for multiple comparison was performed by false discovery rate (FDR cut-off ≤0.05, Benjamini and Hochberg 1995) following Kujur et al (2015a), Upadhyaya et al (2015Upadhyaya et al ( , 2016 and Bajaj et al (2016). The degree of association of SNP loci with diverse PGH traits was measured by the R 2 using a model with the SNPs and adjusted P value adopting a FDR-controlling strategy.…”

Section: Trait Association Mappingmentioning

confidence: 99%

“…The SNPs revealing significant association with diverse PGH traits at a cut-off P value ≤1 × 10 −8 are marked with a dotted line Differential expression profiling (Feuillet et al 2012;Thudi et al 2014;Kujur et al 2015a;Upadhyaya et al 2015Upadhyaya et al , 2016Bajaj et al 2016;Liu et al 2016). In this perspective, a high-resolution GWAS approach deployed by us to scale down the potential genomic loci/genes governing quantitative traits of PGH at a genome-wide scale appears much expedient for understanding the complex genetic architecture of target traits in order to drive genomicsassisted crop improvement of chickpea (Kujur et al 2015a;Bajaj et al 2016;Upadhyaya et al 2015Upadhyaya et al , 2016. Four non-synonymous SNPs and one intronic SNPcontaining candidate genes (major intrinsic protein, ankyrin repeat domain containing protein, ABC transporter, sucrose non-fermenting protein and B3 transcription factor) exhibiting significant association (P = 1.37 × 10 −8 ) with PGH traits (based on our GWAS) were validated in both intra-and interspecific mapping populations contrasting for diverse PGH traits by selective genotyping (Figs.…”

Section: Gwas Of Pgh Traits In Chickpeamentioning

confidence: 99%

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Genetic dissection of plant growth habit in chickpea

Upadhyaya

Bajaj

Srivastava

et al. 2017

Funct Integr Genomics

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A combinatorial genomics-assisted breeding strategy encompassing association analysis, genetic mapping and expression profiling is found most promising for quantitative dissection of complex traits in crop plants. The present study employed GWAS (genome-wide association study) using 24,405 SNPs (single nucleotide polymorphisms) obtained with genotyping-by-sequencing (GBS) of 92 sequenced desi and kabuli accessions of chickpea. This identified eight significant genomic loci associated with erect (E)/semi-erect (SE) vs. spreading (S)/semi-spreading (SS)/prostrate (P) plant growth habit (PGH) trait differentiation regardless of diverse desi and kabuli genetic backgrounds of chickpea. These associated SNPs in combination explained 23.8% phenotypic variation for PGH in chickpea. Five PGH-associated genes were validated successfully in E/SE and SS/S/P PGH-bearing parental accessions and homozygous individuals of three intra- and interspecific RIL (recombinant inbred line) mapping populations as well as 12 contrasting desi and kabuli chickpea germplasm accessions by selective genotyping through Sequenom MassARRAY. The shoot apical, inflorescence and floral meristems-specific expression, including upregulation (seven-fold) of five PGH-associated genes especially in germplasm accessions and homozygous RIL mapping individuals contrasting with E/SE PGH traits was apparent. Collectively, this integrated genomic strategy delineated diverse non-synonymous SNPs from five candidate genes with strong allelic effects on PGH trait variation in chickpea. Of these, two vernalization-responsive non-synonymous SNP alleles carrying SNF2 protein-coding gene and B3 transcription factor associated with PGH traits were found to be the most promising in chickpea. The SNP allelic variants associated with E/SE/SS/S PGH trait differentiation were exclusively present in all cultivated desi and kabuli chickpea accessions while wild species/accessions belonging to primary, secondary and tertiary gene pools mostly contained prostrate PGH-associated SNP alleles. This indicates strong adaptive natural/artificial selection pressure (Tajima's D 3.15 to 4.57) on PGH-associated target genomic loci during chickpea domestication. These vital leads thus have potential to decipher complex transcriptional regulatory gene function of PGH trait differentiation and for understanding the selective sweep-based PGH trait evolution and domestication pattern in cultivated and wild chickpea accessions adapted to diverse agroclimatic conditions. Collectively, the essential inputs generated will be of profound use in marker-assisted genetic enhancement to develop cultivars with desirable plant architecture of erect growth habit types in chickpea.

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Section: Trait Association Mappingmentioning

confidence: 99%

Section: Trait Association Mappingmentioning

confidence: 99%

Section: Gwas Of Pgh Traits In Chickpeamentioning

confidence: 99%

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Genetic dissection of plant growth habit in chickpea

Upadhyaya

Bajaj

Srivastava

et al. 2017

Funct Integr Genomics

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“…However, this strategy detects considerable number of false-positive marker trait associations due to presence of population structure among germplasm accessions used for association analysis (Breseghello and Sorrells, 2006; Sneller et al, 2009). This constraint of spurious marker-trait association can be addressed to certain extent by considering the significant effects of population structure in diverse statistical models as well-adopted by previous association mapping studies in crop plants (Kujur et al, 2015; Upadhyaya et al, 2015, 2016; Bajaj et al, 2016). Despite these efforts, association mapping result still suffers from significant degree of confounding due to strong population structure and cryptic relatedness among accessions used for association analysis.…”

Section: Introductionmentioning

confidence: 99%

Regional Association Analysis of MetaQTLs Delineates Candidate Grain Size Genes in Rice

et al. 2017

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Molecular mapping studies which aim to identify genetic basis of diverse agronomic traits are vital for marker-assisted crop improvement. Numerous Quantitative Trait Loci (QTLs) mapped in rice span long genomic intervals with hundreds to thousands of genes, which limits their utilization for marker-assisted genetic enhancement of rice. Although potent, fine mapping of QTLs is challenging task as it requires screening of large number of segregants to identify suitable recombination events. Association mapping offers much higher resolution as compared to QTL mapping, but detects considerable number of spurious QTLs. Therefore, combined use of QTL and association mapping strategies can provide advantages associated with both these methods. In the current study, we utilized meta-analysis approach to identify metaQTLs associated with grain size/weight in diverse Indian indica and aromatic rice accessions. Subsequently, attempt has been made to narrow-down identified grain size/weight metaQTLs through individual SNP- as well as haplotype-based regional association analysis. The study identified six different metaQTL regions, three of which were successfully revalidated, and substantially scaled-down along with GS3 QTL interval (positive control) by regional association analysis. Consequently, two potential candidate genes within two reduced metaQTLs were identified based on their differential expression profiles in different tissues/stages of rice accessions during seed development. The developed strategy has broader practical utility for rapid delineation of candidate genes and natural alleles underlying QTLs associated with complex agronomic traits in rice as well as major crop plants enriched with useful genetic and genomic information.

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“…Chickpea is well suited to association analysis for its selfpollination mating system [25]. Association analysis has been performed in chickpea [26][27][28][29][30][31] and QTLs controlling different traits, such as flowering time [32], branch number [33], pod and branch number/plant and plant hairiness [34], 100-seed weight and seed coat colour [35,36], seed protein content [37], resistance to Fusarium wilt and Ascochyta blight [38], as well as drought tolerance [26], have been identified.…”

Section: Introductionmentioning

confidence: 99%

Association analysis of biotic and abiotic stresses resistance in chickpea (Cicerspp.) using AFLP markers

Saeed

Darvishzadeh

2017

Biotechnology & Biotechnological Equipment

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Chickpea suffers from different biotic and abiotic stresses, which has led to considerable decreases in seed yield. Since the economic value of a cultivar is determined by its phenotypic characteristics, good knowledge of the genetic structure and identification of genomic loci associated with desired traits will facilitate crop breeding. Amplified fragment length polymorphism (AFLP) markers associated with different agro-morphological characteristics, cold and drought tolerance as well as Ascochyta blight resistance were identified in chickpea by using 44 genotypes comprising cultigens, landraces, internationally developed improved lines and wild relatives, evaluated in a randomized complete block design with three replications at the Urmia rainfed research station. Using six AFLP primer combinations, 64 clear and reproducible markers were developed. The polymorphism information content values calculated for each primer pair ranged from 0.155 (EcoR1-ACC/Mse1-CAG) to 0.270 (EcoR1-ACC/ Mse1-CTG) with an average of 0.237. Analysis of molecular variance (AMOVA) revealed that 90% of the total variance was due to differences within populations and 10% due to differences among populations. Using a general linear model and applying multiple testing corrections, 24 AFLP markers associated with genes controlling the studied traits were identified. Some identified markers were associated with more than one trait. The identified markers could be of interest in marker-assisted selection in chickpea breeding programmes.

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Identification of candidate genes for dissecting complex branch number trait in chickpea

Cited by 21 publications

References 62 publications

Genetic dissection of plant growth habit in chickpea

Genetic dissection of plant growth habit in chickpea

Regional Association Analysis of MetaQTLs Delineates Candidate Grain Size Genes in Rice

Association analysis of biotic and abiotic stresses resistance in chickpea (Cicerspp.) using AFLP markers

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