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Dive into the research topics where A Ashok Kumar is active.

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Featured researches published by A Ashok Kumar.


Theoretical and Applied Genetics | 1996

PCR-based DNA markers linked to a gall midge resistance gene, Gm4t, has potential for marker-aided selection in rice

Suresh Nair; A Ashok Kumar; M. N. Srivastava; M. Mohan

Rice DNAs from a gall midge resistant variety, ‘Abhaya’, a susceptible variety, ‘Tulsi’ and their F3 progeny were screened using 500 random primers in conjunction with bulked-segregant analysis in a polymerase chain reaction (PCR) with a view to detecting random amplified polymorphic DNAs (RAPDs) linked to the gene, Gm4t, which confers resistance to gall midge, a dipteran insect pest of rice. A total of 454 primers were able to produce a distinct amplification pattern, and 3695 bands/loci were amplified between the phenotypically different parents. Of these, 304 bands were polymorphic between the parents, with 19 being phenotypespecific. One of these primers, E20, amplified 2 bands, E20570 and E20583, which are tightly linked to resistance and susceptibility, respectively. These specific bands were cloned and sequenced, and a 94% sequence homology was found between the two fragments. Two specific 20-mer oligonucleotides were synthesized, based on the sequence information of E20583, for use in PCR amplification directly from genomic DNAs. These PCR primers were able to amplify phenotype-specific bands, a 583-bp fragment in susceptible F3 lines and a 570-bp fragment in resistant F3 lines that had been derived from a cross between the parents, indicating their potential and utility for marker-aided selection of the Gm4t gene in rice. Its use would facilitate the early and efficient selection of resistant genes in plant breeding programmes and even in those areas where the insect is not known to occur. These phenotype-specific bands are single-copy sequences and are being mapped to ascertain their chromosomal location in rice.


Theoretical and Applied Genetics | 2002

Identification and mapping of an AFLP marker linked to Gm7, a gall midge resistance gene and its conversion to a SCAR marker for its utility in marker aided selection in rice

Nagesh Sardesai; A Ashok Kumar; K. R. Rajyashri; Suresh Nair; M. Mohan

Abstract.We have identified an AFLP marker SA598 that is linked to Gm7, a gene conferring resistance to biotypes 1, 2 and 4 of the gall midge (Orseolia oryzae), a major dipteran pest of rice. A set of PCR primers specific to an RFLP marker, previously identified to be linked to another gall midge resistance gene Gm2, also amplified a 1.5-kb (F8LB) fragment that is linked to Gm7. Gm7 is a dominant gene and non-allelic to Gm2. Hybridization experiments with clones from a YAC library of Nipponbare, a japonica variety, a BAC library of IR-BB21, an indica variety, and cosmid clones encompassing Gm2 from Phalguna, an indica variety, with F8LB and SA598 as probes, revealed that Gm7 is tightly linked to Gm2 and is located on chromosome 4 of rice. SA598 was sequenced and the sequence information was used to design sequence-characterized amplified region (SCAR) primers. The potential use of these SCAR primers in marker-aided selection of Gm7 in a rice breeding program has been demonstrated.


Theoretical and Applied Genetics | 1997

Molecular mapping of a resistance-specific PCR-based marker linked to a gall midge resistance gene (Gm4t) in rice

M. Mohan; P. V. Sathyanarayanan; A Ashok Kumar; M. N. Srivastava; Suresh Nair

Abstract A PCR-based marker (E20570) linked to the gene Gm4t, which confers resistance to a dipteran pest gall midge (Orseolia oryzae), has been mapped using the restriction fragment length polymorphism (RFLP) technique in rice. Gm4t is a dominant resistance gene. We initially failed to detect useful polymorphism for this marker in a F3 mapping population derived from a cross between two indica parents, ‘Abhaya’בShyamala’, with as many as 35 restriction enzymes. ‘Abhaya’ carries the resistance gene Gm4t and ‘Shyamala’ is susceptible to gall midge. Subsequently, E20570 was mapped using another mapping population represented by a F2 progeny from a cross between ‘Nipponbare’, a japonica variety, and ‘Kasalath’, an indica variety, in which the gene Gm4t was not known to be present. Gm4t mapped onto chromosome 8 between markers R1813 and S1633B. Our method, thus, presents an alternative way of mapping genes which otherwise would be difficult to map because of a lack of polymorphism between closely related parents differing in desired agronomic traits.


Theoretical and Applied Genetics | 2004

Tagging and mapping of a rice gall midge resistance gene, Gm8, and development of SCARs for use in marker-aided selection and gene pyramiding

A. Jain; R. Ariyadasa; A Ashok Kumar; M. N. Srivastava; M. Mohan; Suresh Nair

Using amplified fragment length polymorphisms (AFLPs) and random amplified polymorphic DNAs (RAPDs), we have tagged and mapped Gm8, a gene conferring resistance to the rice gall midge (Orseolia oryzae), a major insect pest of rice, onto rice chromosome 8. Using AFLPs, two fragments, AR257 and AS168, were identified that were linked to the resistant and susceptible phenotypes, respectively. Another resistant phenotype-specific marker, AP19587, was also identified using RAPDs. SCAR primers based on the sequence of the fragments AR257 and AS168 failed to reveal polymorphism between the resistant and the susceptible parents. However, PCR using primers based on the regions flanking AR257 revealed polymorphism that was phenotype-specific. In contrast, PCR carried out using primers flanking the susceptible phenotype-associated fragment AS168 produced a monomorphic fragment. Restriction digestion of these monomorphic fragments revealed polymorphism between the susceptible and resistant parents. Nucleotide BLAST searches revealed that the three fragments show strong homology to rice PAC and BAC clones that formed a contig representing the short arm of chromosome 8. PCR amplification using the above-mentioned primers on a larger population, derived from a cross between two indica rice varieties, Jhitpiti (resistant parent) and TN1 (susceptible parent), showed that there is a tight linkage between the markers and the Gm8 locus. These markers, therefore, have potential for use in marker-aided selection and pyramiding of Gm8 along with other previously tagged gall midge resistance genes [Gm2, Gm4(t), and Gm7].


Plant Molecular Biology | 1996

Chalcone synthase in rice (Oryza sativa L.): Detection of the CHS protein in seedlings and molecular mapping of the chs locus

Arjula R. Reddy; Brian E. Scheffler; G. Madhuri; M. N. Srivastava; A Ashok Kumar; P. V. Sathyanarayanan; Suresh Nair; M. Mohan

The chalcone synthase is a key enzyme that catalyses the first dedicated reaction of the flavonoid pathway in higher plants. The chs gene and its protein product in rice has been investigated. The presence of a chalcone synthase (CHS) protein in rice seedlings and its developmental stage-specific expression has been demonstrated by western analysis. The chalcone synthase of rice was found to be immunologically similar to that of maize. A rice cDNA clone, Os-chs cDNA, encoding chalcone synthase, isolated from a leaf cDNA library of an indica rice variety Purpleputtu has been mapped to the centromeric region of chromosome 11 of rice. It was mapped between RFLP markers RG2 and RG103. RG2 is the nearest RFLP marker located at a genetic distance of 3.3 cM. Some segments of chromosome 11 of rice including chs locus are conserved on chromosome 4 of maize. The markers, including chs locus on chromosome 11 of rice are located, though not in the same order, on chromosome 4 of maize. Genetic analysis of purple pigmentation in two rice lines, Abhaya and Shyamala, used in the present mapping studies, indicated the involvement of three genes, one of which has been identified as a dominant inhibitor of leaf pigmentation. The Os-chs cDNA shows extensive sequence homology, both for DNA and protein (deduced), to that of maize, barley and also to different monocots and dicots.


Euphytica | 2003

A new gene for resistance in rice to Asian rice gall midge (Orseolia oryzae Wood Mason) biotype 1 population at Raipur, India

M. N. Shrivastava; A Ashok Kumar; Sandeep Bhandarkar; B. C. Shukla; K. C. Agrawal

The Asian rice gall midge, Orseolia oryzae Wood Mason (Diptera: Cecidomyiidae), is a major pest of rice in several South and South East Asian countries. The maggots feed internally on the growing tips of the tillers and transform them into tubular galls, onion leaf-like structures called ‘silver shoots’ resulting into severe yield loss to the rice crop. We studied the mode of inheritance and allelic relationships of the resistance genes involved in resistant donor Line 9, a sib of a susceptible cultivar ‘Madhuri’. The segregation behaviour of F1, F2 and F3 populations of the cross between Line 9 and susceptible cultivar MW10 confirmed the presence of a single dominant gene for resistance. Tests of allelism with all the known genes giving resistance to this population indicated that Line 9 possessed a new gene which was designated Gm 9


Crop Science | 2005

Genetic Analysis of Resistance Genes for the Rice Gall Midge in Two Rice Genotypes

A Ashok Kumar; Abhinav Jain; Ravi Kant Sahu; M. N. Shrivastava; Suresh Nair; M. Mohan


Archive | 2009

Sweet sorghum as a biofuel crop where are we now

Karamjit Sharma; Belum Vs Reddy; Pvln Srinivasa Rao; A Ashok Kumar; Palakolanu Sudhakar Reddy; P P Rao; M. Blümmel; Ch Ravinder Reddy


Archive | 2012

Sorghum improvement (1980–2010): Status and way forward

Belum Vs Reddy; A Ashok Kumar; Hc Sharma; P. Srinivasa Rao; M. Blümmel; Ch Ravinder Reddy; R. Sharma; Subodh Deshpande; S D Mazumdar; Elango Dinakaran


Developing a sweet sorghum ethanol value chain. | 2013

Developing a Sweet Sorghum Ethanol Value Chain

Belum Vs Reddy; A Ashok Kumar; Ch Ravinder Reddy; P P Rao; J. V. Patil

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B. V. S. Reddy

Indian Institute of Chemical Technology

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Suresh Nair

International Centre for Genetic Engineering and Biotechnology

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P. Srinivasa Rao

International Crops Research Institute for the Semi-Arid Tropics

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M. Mohan

International Centre for Genetic Engineering and Biotechnology

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G Basavaraj

International Crops Research Institute for the Semi-Arid Tropics

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M. N. Srivastava

Indira Gandhi Agricultural University

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M. N. Shrivastava

Indira Gandhi Agricultural University

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Saumya Nigam

Indian Institute of Technology Bombay

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