Your search keyword '"Nair, Sudha"' showing total 5 results

1. Genomic regions associated with heat stress tolerance in tropical maize (Zea mays L.).

Author

Seetharam, Kaliyamoorthy, Kuchanur, Prakash H., Koirala, K. B., Tripathi, Mahendra Prasad, Patil, Ayyanagouda, Sudarsanam, Viswanadh, Das, Reshmi Rani, Chaurasia, Ramesh, Pandey, Kamal, Vemuri, Hindu, Vinayan, Madhumal Thayil, Nair, Sudha K., Babu, Raman, and Zaidi, P. H.

Subjects

CORN genetics, HIGH temperatures, INTROGRESSION (Genetics), CLIMATE change, PHYSIOLOGICAL effects of heat

Abstract

With progressive climate change and the associated increase in mean temperature, heat stress tolerance has emerged as one of the key traits in the product profile of the maize breeding pipeline for lowland tropics. The present study aims to identify the genomic regions associated with heat stress tolerance in tropical maize. An association mapping panel, called the heat tolerant association mapping (HTAM) panel, was constituted by involving a total of 543 tropical maize inbred lines from diverse genetic backgrounds, test-crossed and phenotyped across nine locations in South Asia under natural heat stress. The panel was genotyped using a genotyping-by-sequencing (GBS) platform. Considering the large variations in vapor pressure deficit (VPD) at high temperature (Tmax) across different phenotyping locations, genome-wide association study (GWAS) was conducted separately for each location. The individual location GWAS identified a total of 269 novel significant single nucleotide polymorphisms (SNPs) for grain yield under heat stress at a p value of < 10–5. A total of 175 SNPs were found in 140 unique gene models implicated in various biological pathway responses to different abiotic stresses. Haplotype trend regression (HTR) analysis of the significant SNPs identified 26 haplotype blocks and 96 single SNP variants significant across one to five locations. The genomic regions identified based on GWAS and HTR analysis considering genomic region x environment interactions are useful for breeding efforts aimed at developing heat stress resilient maize cultivars for current and future climatic conditions through marker-assisted introgression into elite genetic backgrounds and/or genome-wide selection. [ABSTRACT FROM AUTHOR]

Published

2021

2. Dissection of a major QTL qhir1 conferring maternal haploid induction ability in maize.

Author

Nair, Sudha, Molenaar, Willem, Melchinger, Albrecht, Boddupalli, Prasanna, Martinez, Leocadio, Lopez, Luis, and Chaikam, Vijay

Subjects

*HAPLOIDY, *CHROMOSOME segregation, *POLLINATION, *HAPLOTYPES, CORN genetics

Abstract

Key message: Among the qhir11 and qhir12 sub-regions of a major QTL qhir1, only qhir11 has significant effect on maternal haploid induction, segregation distortion and kernel abortion. Abstract: In vivo haploid induction in maize can be triggered in high frequencies by pollination with special genetic stocks called haploid inducers. Several genetic studies with segregating populations from non-inducer x inducer crosses identified a major QTL, qhir1, on chromosome 1.04 contributing to in vivo haploid induction. A recent Genome Wide Association Study using 51 inducers and 1482 non-inducers also identified two sub-regions within the qhir1 QTL region, named qhir11 and qhir12; qhir12 was proposed to be mandatory for haploid induction because the haplotype of qhir11 was also present in some non-inducers and putative candidate genes coding for DNA and amino acid binding proteins were identified in the qhir12 region. To characterize the effects of each sub-region of qhir1 on haploid induction rate, F recombinants segregating for one of the sub-regions and fixed for the other were identified in a cross between CML269 (non-inducer) and a tropicalized haploid inducer TAIL8. To quantify the haploid induction effects of qhir11 and qhir12, selfed progenies of recombinants between these sub-regions were genotyped. F plants homozygous for qhir11 and/or qhir12 were identified, and crossed to a ligueless tester to determine their haploid induction rates. The study revealed that only the qhir11 sub-region has a significant effect on haploid induction ability, besides causing significant segregation distortion and kernel abortion, traits that are strongly associated with maternal haploid induction. The results presented in this study can guide fine mapping efforts of qhir1 and in developing new inducers efficiently using marker assisted selection. [ABSTRACT FROM AUTHOR]

Published

2017

3. Analysis of effectiveness of R1- nj anthocyanin marker for in vivo haploid identification in maize and molecular markers for predicting the inhibition of R1- nj expression.

Author

Chaikam, Vijay, Nair, Sudha, Babu, Raman, Martinez, Leocadio, Tejomurtula, Jyothsna, and Boddupalli, Prasanna

Subjects

*ANTHOCYANINS, *HAPLOIDY, *BIOMARKERS, *PLANTS, *GENE expression in plants, *PLANT germplasm, *PHENOTYPES, CORN genetics

Abstract

Key message: R1- nj anthocyanin marker inhibition is highly frequent in tropical maize germplasm considerably affecting efficiency of haploid identification. Molecular markers reliably differentiating germplasm with anthocyanin color inhibitor have been identified in this study. Abstract: The R1- Navajo ( R1- nj) color marker facilitates easy and quick identification of haploid kernels at the seed stage during in vivo haploid induction process in maize. However, the Navajo phenotype can be completely suppressed or poorly expressed in some germplasm, making it impossible or inefficient to identify haploids at the seed stage. In this study, we characterized the expression of R1- nj marker in a large array of tropical/subtropical inbred lines, breeding populations and landraces by crossing with the R1- nj-based tropicalized haploid inducer. There was a high frequency of inhibition of the Navajo phenotype in the maize inbred lines, which are used in tropical breeding programs. Genome-wide association mapping showed that the C1 anthocyanin regulatory locus is the most significant genetic factor influencing inhibition of the Navajo phenotype. Molecular marker assays were designed based on polymorphism in the C1 vs C1- I alleles. Analysis of a set of 714 inbred lines demonstrated that a combination of two gene-specific markers-8 bp C1- I InDel and C1- I SNP-could predict with high accuracy the presence of anthocyanin color inhibition in the germplasm analyzed. Information generated in this study aids in making informed decisions on the constitution of source populations for doubled haploid (DH) line development in tropical germplasm, particularly those derived from elite maize lines from CIMMYT. The C1- I gene-specific molecular markers identified and validated will facilitate high-throughput and cost-effective evaluation of a large pool of germplasm for the presence of the dominant color inhibitor in maize germplasm. [ABSTRACT FROM AUTHOR]

Published

2015

4. Molecular mapping across three populations reveals a QTL hotspot region on chromosome 3 for secondary traits associated with drought tolerance in tropical maize.

Author

Almeida, Gustavo, Nair, Sudha, Borém, Aluízio, Cairns, Jill, Trachsel, Samuel, Ribaut, Jean-Marcel, Bänziger, Marianne, Prasanna, Boddupalli, Crossa, Jose, and Babu, Raman

Subjects

*PLANT gene mapping, *PLANT molecular genetics, *PLANT chromosomes, *EFFECT of drought on plants, *SINGLE nucleotide polymorphisms, CORN genetics

Abstract

Identifying quantitative trait loci (QTL) of sizeable effects that are expressed in diverse genetic backgrounds across contrasting water regimes particularly for secondary traits can significantly complement the conventional drought tolerance breeding efforts. We evaluated three tropical maize biparental populations under water-stressed and well-watered regimes for drought-related morpho-physiological traits, such as anthesis-silking interval (ASI), ears per plant (EPP), stay-green (SG) and plant-to-ear height ratio (PEH). In general, drought stress reduced the genetic variance of grain yield (GY), while that of morpho-physiological traits remained stable or even increased under drought conditions. We detected consistent genomic regions across different genetic backgrounds that could be target regions for marker-assisted introgression for drought tolerance in maize. A total of 203 QTL for ASI, EPP, SG and PEH were identified under both the water regimes. Meta-QTL analysis across the three populations identified six constitutive genomic regions with a minimum of two overlapping traits. Clusters of QTL were observed on chromosomes 1.06, 3.06, 4.09, 5.05, 7.03 and 10.04/06. Interestingly, a ~8-Mb region delimited in 3.06 harboured QTL for most of the morpho-physiological traits considered in the current study. This region contained two important candidate genes viz., zmm16 (MADS-domain transcription factor) and psbs1 (photosystem II unit) that are responsible for reproductive organ development and photosynthate accumulation, respectively. The genomic regions identified in this study partially explained the association of secondary traits with GY. Flanking single nucleotide polymorphism markers reported herein may be useful in marker-assisted introgression of drought tolerance in tropical maize. [ABSTRACT FROM AUTHOR]

Published

2014

5. Applications of genotyping-by-sequencing (GBS) in maize genetics and breeding.

Author

Wang, Nan, Yuan, Yibing, Wang, Hui, Yu, Diansi, Liu, Yubo, Zhang, Ao, Gowda, Manje, Nair, Sudha K., Hao, Zhuanfang, Lu, Yanli, San Vicente, Felix, Prasanna, Boddupalli M., Li, Xinhai, and Zhang, Xuecai

Subjects

CORN genetics, CORN breeding, GENOTYPES, NUCLEOTIDE sequence, SINGLE nucleotide polymorphisms, NUCLEOTIDE sequencing, POLYMERASE chain reaction

Abstract

Genotyping-by-Sequencing (GBS) is a low-cost, high-throughput genotyping method that relies on restriction enzymes to reduce genome complexity. GBS is being widely used for various genetic and breeding applications. In the present study, 2240 individuals from eight maize populations, including two association populations (AM), backcross first generation (BC1), BC1F2, F2, double haploid (DH), intermated B73 × Mo17 (IBM), and a recombinant inbred line (RIL) population, were genotyped using GBS. A total of 955,120 of raw data for SNPs was obtained for each individual, with an average genotyping error of 0.70%. The rate of missing genotypic data for these SNPs was related to the level of multiplex sequencing: ~ 25% missing data for 96-plex and ~ 55% for 384-plex. Imputation can greatly reduce the rate of missing genotypes to 12.65% and 3.72% for AM populations and bi-parental populations, respectively, although it increases total genotyping error. For analysis of genetic diversity and linkage mapping, unimputed data with a low rate of genotyping error is beneficial, whereas, for association mapping, imputed data would result in higher marker density and would improve map resolution. Because imputation does not influence the prediction accuracy, both unimputed and imputed data can be used for genomic prediction. In summary, GBS is a versatile and efficient SNP discovery approach for homozygous materials and can be effectively applied for various purposes in maize genetics and breeding. [ABSTRACT FROM AUTHOR]

Published

2020