Chandan Sahi
University of Delhi
Network
Latest external collaboration on country level. Dive into details by clicking on the dots.
Publication
Featured researches published by Chandan Sahi.
Functional & Integrative Genomics | 2006
Chandan Sahi; Amanjot Singh; Krishan Kumar; Eduardo Blumwald; Anil Grover
Significant progress has been made in unraveling the molecular biology of rice in the past two decades. Today, rice stands as a forerunner amongst the cereals in terms of details known on its genetics. Evidence show that salt tolerance in plants is a quantitative trait. Several traditional cultivars, landraces, and wild types of rice like Pokkali, CSR types, and Porteresia coarctata appear as promising materials for donation of requisite salt tolerance genes. A large number of quantitative trait loci (QTL) have been identified for salt tolerance in rice through generation of recombinant inbred lines and are being mapped using different types of DNA markers. Salt-tolerant transgenic rice plants have been produced using a host of different genes and transcript profiling by micro- and macroarray-based methods has opened the gates for the discovery of novel salt stress mechanisms in rice, and comparative genomics is turning out to be a critical input in this respect. In this paper, we present a comprehensive review of the genetic, molecular biology, and comparative genomics effort towards the generation of salt-tolerant rice. From the data on comprehensive transcript expression profiling of clones representing salt-stress-associated genes of rice, it is shown that transcriptional and translational machineries are important determinants in controlling salt stress response, and gene expression response in tolerant and susceptible rice plants differs mainly in quantitative terms.
Cell Stress & Chaperones | 2001
Manu Agarwal; Surekha Katiyar-Agarwal; Chandan Sahi; Daniel R. Gallie; Anil Grover
Abstract Arabidopsis thaliana, the first plant for which the entire genome sequence is available, was also among the first plant species from which Hsp100 proteins were characterized. The Athsp101 complementary DNA (cDNA) corresponds to the gene identification At1g74310 in the Arabidopsis genome sequence. Analysis of the genome revealed 7 additional proteins that are variably homologous with At1g74310 throughout the entire amino acid sequence and significant similarities or identities in the signature sequences conserved among Hsp100 proteins. Although AtHsp101 is cytoplasmic, 5 of the 7 related proteins have predicted plastidial localization signals. This complete description of the AtHsp100 family sets the stage for future research on expression and function.
Plant Science | 1999
Anil Grover; Chandan Sahi; Neeti Sanan; Anita Grover
Abstract During the last decade, major advances have been made in plant genetic engineering. The methods for stable genetic transformation as well as for regulation of introduced trans-genes have been optimised to a great deal. The major limiting factor in the widespread application of genetic engineering is the availability of the target genes. This is particularly true for engineering tolerance against abiotic stresses (such as those caused by high levels of salts in soils, reduced/excess availability of water and sub- and supra-optimal temperature regimes). In spite of this, the past 5 years (1993–1998) have witnessed significant achievements in terms of generating transgenics for enhanced tolerance to these stresses. For future work on producing plants with still higher level of tolerance, there is a need to expand the information on the stress-induced genes so that appropriate genes can be pyramided. The current upsurge in genomic research has the potential to catalyse efforts in elucidating new stress-responsive genes. There are also possibilities of engineering the whole cascade of multiple genetic changes through manipulation of the regulatory genes.
Theoretical and Applied Genetics | 2003
Chandan Sahi; Manu Agarwal; Reddy Mk; Sudhir K. Sopory; Anil Grover
Abstract.Salt stress adversely affects the growth of rice plants. To understand the molecular basis of salt-stress response, four subtracted cDNA libraries were constructed employing specific NaCl-stressed tissues from salt-tolerant (CSR 27 and Pokkali) and salt-sensitive (Pusa basmati 1) rice cultivars. An efficient PCR-based cDNA subtraction method was employed for the isolation of the salt-stress responsive cDNA clones. In all, 1,266 cDNA clones were isolated in the course of this study, out of which 85 clones were end-sequenced. Database search of the sequenced clones showed that 22 clones were homologous to genes that have earlier been implicated in stress response, 34 clones were novel with respect to their function and six clones showed no homology to sequences in any of the public database. Northern analysis showed that the transcript expression pattern of selected clones was variable amongst the cultivars tested with respect to stress-regulation.
Molecular Genetics and Genomics | 2008
Neha Nigam; Amanjot Singh; Chandan Sahi; Anupama Chandramouli; Anil Grover
We report an in-depth characterization of two major stress proteins namely SUMO-conjugating enzyme (Sce) and peptidyl prolyl cis-trans isomerase (PPIase) in rice (Oryza sativa L.). Sce mediates addition of SUMO group to various cell proteins, through process referred to as SUMOylation. Rice nuclear genome has two putative genes encoding the Sce protein (OsSce1 and OsSce2). PCR-amplified full-length OsSce1 cDNA functionally complemented the growth defect in yeast cells lacking the equivalent Ubc9 protein (ScΔubc9). RT-PCR analysis showed that transcript levels of OsSce1 and OsSce2 in rice seedlings were regulated by temperature stress. OsSce1 protein was localized to the nucleus in onion epidermal cells as evidenced by the transient GFP expression analysis following micro-projectile gun-based shooting of an OsSce1-GFP fusion construct. PPIase proteins assist molecular chaperones in reactions associated with protein folding and protein transport across membrane. There are 23 putative genes encoding for FK506-binding proteins (FKBPs; specific class of PPIase) in rice genome. OsFKBP20 cDNA was isolated as a stress-inducible EST clone. Largest ORF of 561 bases in OsFKBP20 showed characteristic FK506-binding domain at N-terminus and a coiled-coil motif at C-terminus. RNA expression analysis indicated that OsFKBP20 transcript is heat-inducible. OsFKBP20 over-expression in yeast endowed capacity of high temperature tolerance to yeast cells. Yeast two-hybrid analysis showed that OsSce1 protein physically interacts with the OsFKBP20 protein. It is thus proposed that OsSce1 and OsFKBP20 proteins in concert mediate the stress response of rice plants.
Gene | 2009
Amanjot Singh; Chandan Sahi; Anil Grover
Protease inhibitors play important roles in stress and developmental responses of plants. Rice genome contains 17 putative members in chymotrypsin protease inhibitor (ranging in size from 7.21 to 11.9 kDa) gene family with different predicted localization sites. Full-length cDNA encoding for a putative subtilisin-chymotrypsin protease inhibitor (OCPI2) was obtained from Pusa basmati 1 (indica) rice seedlings. 620 bp-long OCPI2 cDNA contained 219 bp-long ORF, coding for 72 amino acid-long 7.7 kDa subtilisin-chymotrypsin protease inhibitor (CPI) cytoplasmic protein. Expression analysis by semi-quantitative RT-PCR analysis showed that OCPI2 transcript is induced by varied stresses including salt, ABA, low temperature and mechanical injury in both root and shoot tissues of the seedlings. Transgenic rice plants produced with OCPI2 promoter-gus reporter gene showed that this promoter directs high salt- and ABA-regulated expression of the GUS gene. Another CPI gene (OCPI1) upstream to OCPI2 (with 1126 bp distance between the transcription initiation sites of the two genes; transcription in the reverse orientation) was noted in genome sequence of rice genome. A vector that had GFP and GUS reporter genes in opposite orientations driven by 1881 bp intergenic sequence between the OCPI2 and OCPI1 (encompassing the region between the translation initiation sites of the two genes) was constructed and shot in onion epidermal cells by particle bombardment. Expression of both GFP and GUS from the same epidermal cell showed that this sequence represents a bidirectional promoter. Examples illustrating gene pairs showing co-expression of two divergent neighboring genes sharing a bidirectional promoter have recently been extensively worked out in yeast and human systems. We provide an example of a gene pair constituted of two homologous genes showing co-expression governed by a bidirectional promoter in rice.
Plant Physiology and Biochemistry | 2011
Manu Agarwal; Amanjot Singh; Dheeraj Mittal; Chandan Sahi; Anil Grover
Rice seedlings subjected to heat shock show rapid and transient induction of Oshsp17.4-CI, Oshsp17.9A-CI and OsClpB-cyt/hsp100 transcripts. When the seedlings were pre-treated with protein synthesis inhibitor cycloheximide, levels of the above transcripts during heat shock were more elevated than those seen with heat shock alone. Heat stress and cycloheximide co-treatment resulted in higher transcript accumulation in comparison to cycloheximide pre-treatment followed by heat stress. In transgenic plants raised with OsClpB-cyt/hsp100 promoter driving expression of the reporter gus gene, expression of the gus transcript was subjected to similar superinduction event as was seen with native OsClpB-cyt/hsp100 transcripts in untransformed plants. Yeast cells transformed with variably-sized rice ClpB-cyt/hsp100 promoter driving expression of the lacZ reporter transcript showed that specific sequences of the promoter region may be implicated in superinduction.
Physiologia Plantarum | 2006
Chandan Sahi; Amanjot Singh; Eduardo Blumwald; Anil Grover
Current Science | 2001
Anil Grover; Avnish Kapoor; O. Satya Lakshmi; Sangeeta Agarwal; Chandan Sahi; Surekha Katiyar-Agarwal; Manu Agarwal; Himanshu Dubey
Plant Molecular Biology | 2003
Manu Agarwal; Chandan Sahi; Surekha Katiyar-Agarwal; Sangeeta Agarwal; Todd E. Young; Daniel R. Gallie; Vishva Mitra Sharma; K. Ganesan; Anil Grover