Rajeev Kumar Varshney
Overview
Explore the profile of Rajeev Kumar Varshney including associated specialties, affiliations and a list of published articles.
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26
Citations
479
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Recent Articles
1.
Jan F, M P, Kaur S, Khan M, Sheikh F, Wani F, et al.
Plant Physiol Biochem
. 2024 Dec;
219:109259.
PMID: 39626524
Wheat stripe rust (Puccinia striiformis f. sp. tritici, Pst) is the most damaging wheat disease, causing substantial losses in global wheat production and productivity. Our study aimed to unravel the...
2.
Rehman S, Gul S, Parthiban M, Isha I, Reddy M, Chitikineni A, et al.
Plant Genome
. 2024 Jul;
17(3):e20483.
PMID: 38965817
Helicoverpa armigera (also known as gram pod borer) is a serious threat to chickpea production in the world. A set of 173 chickpea genotypes were evaluated for H. armigera resistance,...
3.
Shafi S, Khan M, Wani F, Sheikh F, Ganai S, Mughal N, et al.
Physiol Mol Biol Plants
. 2024 Jan;
29(12):2005-2020.
PMID: 38222272
Anthracnose (ANT) caused by is the most devastating seed-borne fungal disease of common bean. In response to fungal infections, it is hypothesized that pathogen-plant interactions typically cause hypersensitive reactions by...
4.
Danakumara T, Kumar T, Kumar N, Patil B, Bharadwaj C, Patel U, et al.
Plants (Basel)
. 2023 Nov;
12(21).
PMID: 37960048
Identifying a congenially targeted production environment and understanding the effects of genotype by environmental interactions on the adaption of chickpea genotypes is essential for achieving an optimal yield stability. Different...
5.
Ye J, Liang H, Zhao X, Li N, Song D, Zhan J, et al.
Plant Biotechnol J
. 2023 May;
21(7):1479-1495.
PMID: 37170717
Heterosis refers to the better performance of cross progeny compared with inbred parents, and its utilization contributes greatly to agricultural production. Several hypotheses have been proposed to explain heterosis mainly...
6.
Rasool B, Summuna B, Djalovic I, Shah T, Sheikh P, Gupta S, et al.
Phytopathology
. 2023 Feb;
113(5):836-846.
PMID: 36734935
Fusarium wilt (FW) caused by f. sp. is a devastating disease of chickpea (). To identify promising resistant genotypes and genomic loci for FW resistance, a core set of 179...
7.
Shafi S, Saini D, Khan M, Bawa V, Choudhary N, Dar W, et al.
Front Plant Sci
. 2022 Sep;
13:966339.
PMID: 36092444
Anthracnose, caused by the fungus , is one of the devastating disease affecting common bean production and productivity worldwide. Several quantitative trait loci (QTLs) for anthracnose resistance have been identified....
8.
Fayaz H, Tyagi S, Wani A, Pandey R, Akhtar S, Bhat M, et al.
Sci Rep
. 2022 Sep;
12(1):11357.
PMID: 36064952
Chickpea is the most important nutrient-rich grain legume crop in the world. A diverse core set of 147 chickpea genotypes was genotyped with a Axiom(®)50K CicerSNP array and trait phenotyped...
9.
Agarwal C, Chen W, Varshney R, Vandemark G
Front Genet
. 2022 Sep;
13:945787.
PMID: 36046237
The soilborne oomycete plant pathogen causes seed rot and pre-emergence damping-off of chickpea ( L). The pathogen has been controlled for several decades using the fungicide metalaxyl as seed treatment...
10.
Mir A, Bhat M, Fayaz H, Wani A, Dar S, Maqbool S, et al.
Mol Biol Rep
. 2022 Aug;
49(12):11469-11479.
PMID: 36006503
Background: The exploration of genetic diversity is the key source of germplasm conservation and potential to broaden its genetic base. The globally growing demand for chickpea suggests superior/climate-resilient varieties, which...