Your search keyword '"Prashant Singam"' showing total 5 results

1. Prospects for developing allergen‐depleted food crops

Author

Vadthya Lokya, Sejal Parmar, Arun K. Pandey, Hari K. Sudini, Dongxin Huai, Peggy Ozias‐Akins, Christine H. Foyer, Chogozie Victor Nwosu, Barbara Karpinska, Alison Baker, Pei Xu, Boshou Liao, Reyazul Rouf Mir, Xiaoping Chen, Baozhu Guo, Henry T. Nguyen, Rakesh Kumar, Sandeep K. Bera, Prashant Singam, Anirudh Kumar, Rajeev K. Varshney, and Manish K. Pandey

Subjects

Plant culture, SB1-1110, Genetics, QH426-470

Abstract

Abstract In addition to the challenge of meeting global demand for food production, there are increasing concerns about food safety and the need to protect consumer health from the negative effects of foodborne allergies. Certain bio‐molecules (usually proteins) present in food can act as allergens that trigger unusual immunological reactions, with potentially life‐threatening consequences. The relentless working lifestyles of the modern era often incorporate poor eating habits that include readymade prepackaged and processed foods, which contain additives such as peanuts, tree nuts, wheat, and soy‐based products, rather than traditional home cooking. Of the predominant allergenic foods (soybean, wheat, fish, peanut, shellfish, tree nuts, eggs, and milk), peanuts (Arachis hypogaea) are the best characterized source of allergens, followed by tree nuts (Juglans regia, Prunus amygdalus, Corylus avellana, Carya illinoinensis, Anacardium occidentale, Pistacia vera, Bertholletia excels), wheat (Triticum aestivum), soybeans (Glycine max), and kidney beans (Phaseolus vulgaris). The prevalence of food allergies has risen significantly in recent years including chance of accidental exposure to such foods. In contrast, the standards of detection, diagnosis, and cure have not kept pace and unfortunately are often suboptimal. In this review, we mainly focus on the prevalence of allergies associated with peanut, tree nuts, wheat, soybean, and kidney bean, highlighting their physiological properties and functions as well as considering research directions for tailoring allergen gene expression. In particular, we discuss how recent advances in molecular breeding, genetic engineering, and genome editing can be used to develop potential low allergen food crops that protect consumer health.

Published

2023

2. Genetic mapping identified major main‐effect and three co‐localized quantitative trait loci controlling high iron and zinc content in groundnut

Author

Sejal Parmar, Pasupuleti Janila, Sunil S. Gangurde, Murali T. Variath, Vinay Sharma, Deekshitha Bomireddy, Surendra S. Manohar, Rajeev K. Varshney, Prashant Singam, and Manish K. Pandey

Subjects

Plant culture, SB1-1110, Genetics, QH426-470

Abstract

Abstract Malnutrition is a major challenge globally, and groundnut is a highly nutritious self‐pollinated legume crop blessed with ample genomic resources, including the routine deployment of genomic‐assisted breeding. This study aimed to identify genomic regions and candidate genes for high iron (Fe) and zinc (Zn) content, utilizing a biparental mapping population (ICGV 00440 × ICGV 06040;). Genetic mapping and quantitative trait locus (QTL) analysis (474 mapped single‐nucleotide polymorphism loci; 1536.33 cM) using 2 seasons of phenotypic data together with genotypic data identified 5 major main‐effect QTLs for Fe content. These QTLs exhibited log‐of‐odds (LOD) scores ranging from 6.5 to 7.4, explaining phenotypic variation (PVE) ranging from 22% (qFe‐Ah01) to 30.0% (qFe‐Ah14). Likewise, four major main effect QTLs were identified for Zn content, with LOD score ranging from 4.4 to 6.8 and PVE ranging from 21.8% (qZn‐Ah01) to 32.8% (qZn‐Ah08). Interestingly, three co‐localized major and main effect QTLs (qFe‐Ah01, qZn‐Ah03, and qFe‐Ah11) were identified for both Fe and Zn contents. These genomic regions harbored key candidate genes, including zinc/iron permease transporter, bZIP transcription factor, and vacuolar iron transporter which likely play pivotal roles in the accumulation of Fe and Zn contents in seeds. The findings of this study hold potential for fine mapping and diagnostic marker development for high Fe and Zn contents in groundnut.

Published

2023

3. Whole‐genome sequencing based discovery of candidate genes and diagnostic markers for seed weight in groundnut

Author

Sunil S. Gangurde, Aamir W. Khan, Pasupuleti Janila, Murali T. Variath, Surendra S. Manohar, Prashant Singam, Annapurna Chitikineni, Rajeev K. Varshney, and Manish K. Pandey

Subjects

Plant culture, SB1-1110, Genetics, QH426-470

Abstract

Abstract Seed weight in groundnut (Arachis hypogaea L.) has direct impact on yield as well as market price because of preference for bold seeds by consumers and industry, thereby making seed‐size improvement as one of the most important objectives of groundnut breeding programs globally. Marker‐based early generation selection can accelerate the process of breeding for developing large‐seeded varieties. In this context, we deployed the quantitative trait locus‐sequencing (QTL‐seq) approach on a biparental mapping population (Chico × ICGV 02251) to identify candidate genes and develop markers for seed weight in groundnut. A total of 289.4–389.4 million reads sequencing data were generated from three libraries (ICGV 02251 and two extreme bulks) achieving 93.9–95.1% genome coverage and 8.34–9.29× average read depth. The analysis of sequencing data using QTL‐seq pipeline identified five genomic regions (three on chromosome B06 and one each on chromosomes B08 and B09) for seed weight. Detailed analysis of above associated genomic regions detected 182 single‐nucleotide polymorphisms (SNPs) in genic and intergenic regions, and 11 of these SNPs were nonsynonymous in the genomic regions of 10 candidate genes including Ulp proteases and BIG SEED locus genes. Kompetitive allele specific polymerase chain reaction (KASP) markers for 14 SNPs were developed, and four of these markers (snpAH0031, snpAH0033, snpAH0037, and snpAH0038) were successfully validated for deployment in breeding for large‐seeded groundnut varieties.

Published

2023

4. Identification and analysis of proline-rich proteins and hybrid proline-rich proteins super family genes from Sorghum bicolor and their expression patterns to abiotic stress and zinc stimuli

Author

Guddimalli Rajasheker, Marka Nagaraju, Rinku Polachirakkal Varghese, Naravula Jalaja, Anil Kumar Somanaboina, Prashant Singam, Chintala Ramakrishna, Suprasanna Penna, Nese Sreenivasulu, and P. B. Kavi Kishor

Subjects

proline-rich proteins, hybrid proline-rich proteins, gene expressions, abiotic stresses, Sorghum bicolor, Plant culture, SB1-1110

Abstract

Systematic genome-wide analysis of Sorghum bicolor revealed the identification of a total of 48 homologous genes comprising 21 proline-rich proteins (PRPs) and 27 hybrid proline-rich proteins (HyPRPs). Comprehensive scrutiny of these gene homologs was conducted for gene structure, phylogenetic investigations, chromosome mapping, and subcellular localization of proteins. Promoter analysis uncovered the regions rich with phosphorous- (BIHD), ammonium-, sulfur-responsive (SURE), and iron starvation-responsive (IRO2) along with biotic, abiotic, and development-specific cis-elements. Further, PRPs exhibit more methylation and acetylation sites in comparison with HyPRPs. miRNAs have been predicted which might play a role in cleavage and translation inhibition. Several of the SbPRP genes were stimulated in a tissue-specific manner under drought, salt, heat, and cold stresses. Additionally, exposure of plants to abscisic acid (ABA) and zinc (Zn) also triggered PRP genes in a tissue-dependent way. Among them, SbPRP17 has been found upregulated markedly in all tissues irrespective of the stress imposed. The expressions of SbHyPRPs, especially SbHyPRP2, SbHyPRP6, and SbHyPRP17 were activated under all stresses in all three tissues. On the other hand, SbHyPRP8 (root only) and SbHyPRP12 (all three tissues) were highly responsive to cold stress and ABA while SbHyPRP26 was induced by drought and Zn in the stem. Taken together, this study indicates the critical roles that SbPRPs and SbHyPRPs play during diverse abiotic stress conditions and notably the plausible roles that these genes play upon exposure to zinc, the crucial micronutrient in plants.

Published

2022

5. MutMap Approach Enables Rapid Identification of Candidate Genes and Development of Markers Associated With Early Flowering and Enhanced Seed Size in Chickpea (Cicer arietinum L.)

Author

Praveen Kumar Manchikatla, Danamma Kalavikatte, Bingi Pujari Mallikarjuna, Ramesh Palakurthi, Aamir W. Khan, Uday Chand Jha, Prasad Bajaj, Prashant Singam, Annapurna Chitikineni, Rajeev K. Varshney, and Mahendar Thudi

Subjects

MutMap, early flowering, chickpea, 100 seed weight, candidate genes and SNPs, Plant culture, SB1-1110

Abstract

Globally terminal drought is one of the major constraints to chickpea (Cicer arietinum L.) production. Early flowering genotypes escape terminal drought, and the increase in seed size compensates for yield losses arising from terminal drought. A MutMap population for early flowering and large seed size was developed by crossing the mutant line ICC4958-M3-2828 with wild-type ICC 4958. Based on the phenotyping of MutMap population, extreme bulks for days to flowering and 100-seed weight were sequenced using Hi-Seq2500 at 10X coverage. On aligning 47.41 million filtered reads to the CDC Frontier reference genome, 31.41 million reads were mapped and 332,395 single nucleotide polymorphisms (SNPs) were called. A reference genome assembly for ICC 4958 was developed replacing these SNPs in particular positions of the CDC Frontier genome. SNPs specific for each mutant bulk ranged from 3,993 to 5,771. We report a single unique genomic region on Ca6 (between 9.76 and 12.96 Mb) harboring 31, 22, 17, and 32 SNPs with a peak of SNP index = 1 for low bulk for flowering time, high bulk for flowering time, high bulk for 100-seed weight, and low bulk for 100-seed weight, respectively. Among these, 22 SNPs are present in 20 candidate genes and had a moderate allelic impact on the genes. Two markers, Ca6EF10509893 for early flowering and Ca6HSDW10099486 for 100-seed weight, were developed and validated using the candidate SNPs. Thus, the associated genes, candidate SNPs, and markers developed in this study are useful for breeding chickpea varieties that mitigate yield losses under drought stress.

Published

2021