Understanding the genes that govern tea plant (Camellia sinensis) architecture and response to drought stress is urgently needed to enhance breeding in tea with improved water use efficiency. Field drought is a slow mechanism and the plants go through an adaptive process in contrast to the drastic changes of rapid dehydration in case of controlled experiments. We identified a set of drought responsive genes under controlled condition using SSH, and validated the identified genes and their pattern of expression under field drought condition. The study was at three stages of water deficit stress viz., before wilting, wilting and recovery, which revealed a set of genes with higher expression at before wilting stage including dehydrin, abscissic acid ripening protein, glutathione peroxidase, cinnamoyl CoA reductase, calmodulin binding protein. The higher expression of these genes was related with increase tolerance character of DT/TS-463 before wilting, these five tolerant progenies could withstand drought stress and thus are candidates for breeding. We observed that physiological parameter like water use efficiency formed a close group with genes such as calmodulin related, DRM3, hexose transporter, hydrogen peroxide induced protein, ACC oxidase, lipase, ethylene responsive transcription factor and diaminopimelate decarboxylase, during wilting point. Our data provides valuable information for the gene components and the dynamics of gene expression in second and third leaf against drought stress in tea, which could be regarded as candidate targets potentially associated with drought tolerance. We propose that the identified five tolerant progenies on the basis of their drought tolerance can thus be utilised for future breeding programmes.
A cDNA-AFLP approach was used to identify transcript and/or genes specifically expressed in response to drought in tea. Drought was artificially induced and whole genome transcript profiling was done at three different stages-6 days before wilting, 3 days before wilting and at wilting stage of both tolerant and susceptible cultivars, and genetic differences was thus visualized as polymorphisms in the transcriptome. The cDNA-AFLP technique allowed genes and transcripts to be identified in the tolerant genotype (TV-23) whose expression is responsive to drought stress. The cluster analysis revealed two types of clustering-type I separated the tolerant and susceptible cultivar, whereas type II separated the time point of sample and this may be grouped as early and late responsive transcripts. 108 transcript derived fragments were identified as differentially expressed in tolerant genotypes of which 89 sequences could be obtained. Fifty-nine of them showed homology in the public databases. Functional ontology showed genes related to carbohydrate metabolism, response to stress, protein modification process and translation. Cluster I includes five fragments and cluster II includes 25 fragments. Other genes strongly expressed in response to drought in tolerant genotype would help us in identifying and determining the genetic basis of mechanisms involved in conferring drought tolerance in tea.
Tea is the second most consumed beverage worldwide whose cultivation is greatly challenged by a large variety of biotic and abiotic stresses. Among the biotic factors, the hemipteran pest Helopeltis theivora Waterhouse is particularly devastating in Asia and Africa, rendering the crop unsuitable for any downstream processing. The present study, for the first time, endeavors to dissect the molecular events associated with such infestations and identify potential molecular protagonists influencing Helopeltis tolerance in Assam tea. We analyzed the transcriptome of infested tea plants having contrasting responses to pest feeding by suppression subtractive hybridization and quantified the relative abundances of defense-associated transcripts. We analyzed 445 unigenes derived from 1558 expressed sequence tags (ESTs) from three different infestation conditions. Our study indicate that defense responses to the pest greatly vary in temporal and cultivar-specific manner characterized by an exclusive upregulation of specific defenseassociated genes in the tolerant cultivar. Moreover, it was observed that transcripts related to flavonoid biosynthesis, purine metabolism, formate metabolism, jasmonic acid biosynthesis and signaling, and cell wall metabolism are uniquely enriched in the same. Interestingly, those involved in caffeine biosynthesis remain comparatively low and unaltered. We report higher trichome densities on the abaxial surface of the leaf in tolerant cultivar while puncture causes their tender reorientation. SEM of the insect mouthparts reveal higher concentrations of sensilla-like structures near the distal end and tip of the proboscis which are known to act as chemoreceptors in other hemipterans. Our investigation provides the first ever glimpse of Helopeltis-induced defense gene network and provides the much needed platform for improvement of the crop for better Helopeltis tolerance through breeding and transgenic approaches. On a wider perspective, the study will augment our understanding of molecular responses to phloem herbivory in plants.
Copper-containing amine oxidase (CuAO) is the enzyme known to play diversity of function in plant responses to environmental stresses through its reaction products. Here, for the first time we report full length cDNA encoding CuAO protein from a drought tolerant tea cultivar. It was found to be 785 bp long with a 70 bp 5ʹ-UTR, 193 bp 3ʹ-UTR, 522 bp mORF and a polyA adenylational signal. It codes for a polypeptide of 173 amino acids having predicted molecular weight and isoelectric point of 19 KDa and 7.75 respectively. Heterologous expression and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analysis of the protein in Escherichia coli revealed similar size as predicted by in silico analysis. Blastp analysis and template based homology modeling in Phyre2 has identified a copper amine oxidase domain with ligand binding site for copper at residue 123 (Histidine) which suggests its probable role in plant responses to environmental stresses. Interestingly, no signal peptide sequence was detected in the predicted protein which is in contrast to the CuAO so far reported in plants. Although, in slico analysis of the protein have indicated its probable structure and functions, further functional characterization is needed to better understand its role during drought and other environmental stresses in tea.
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