Ectopic expression of SOD and APX genes in Arabidopsis alters metabolic pools and genes related to secondary cell wall cellulose biosynthesis and improve salt tolerance.

Hydrogen peroxide (H2O2) is known to accumulate in plants during abiotic stress conditions and also acts as a signalling molecule. In this study, Arabidopsis thaliana transgenics overexpressing cytosolic CuZn-superoxide dismutase (PaSOD) from poly-extremophile high-altitude Himalayan plant Potentilla atrosanguinea, cytosolic ascorbate peroxidase (RaAPX) from Rheum australe and dual transgenics overexpressing both the genes were developed and analyzed under salt stress. In comparison to wild-type (WT) or single transgenics, the performance of dual transgenics under salt stress was better with higher biomass accumulation and cellulose content. We identified genes involved in cell wall biosynthesis, including nine cellulose synthases (CesA), seven cellulose synthase-like proteins together with other wall-related genes. RNA-seq analysis and qPCR revealed differential regulation of genes (CesA 4, 7 and 8) and transcription factors (MYB46 and 83) involved in secondary cell wall cellulose biosynthesis, amongst which most of the cellulose biosynthesis gene showed upregulation in single (PaSOD line) and dual transgenics at 100 mM salt stress. A positive correlation between cellulose content and H2O2 accumulation was observed in these transgenic lines. Further, cellulose content was 1.6-2 folds significantly higher in PaSOD and dual transgenic lines, 1.4 fold higher in RaAPX lines as compared to WT plants under stress conditions. Additionally, transgenics overexpressing PaSOD and RaAPX also displayed higher amounts of phenolics as compared to WT. The novelty of present study is that H2O2 apart from its role in signalling, it also provides mechanical strength to plants and aid in plant biomass production during salt stress by transcriptional activation of cellulose biosynthesis pathway. This modulation of the cellulose biosynthetic machinery in plants has the potential to provide insight into plant growth, morphogenesis and to create plants with enhanced cellulose content for biofuel use.

The TRAF Mediated Gametogenesis Progression (TRAMGaP) Gene Is Required for Megaspore Mother Cell Specification and Gametophyte Development.

In plants, the role of TRAF-like proteins with meprin and the TRAF homology (MATH) domain is far from clear. In animals, these proteins serve as adapter molecules to mediate signal transduction from Tumor Necrosis Factor Receptor to downstream effector molecules. A seed-sterile mutant with a disrupted TRAF-like gene (At5g26290) exhibiting aberrant gametogenesis led us to investigate the developmental role of this gene in Arabidopsis (Arabidopsis thaliana). The mutation was semidominant and resulted in pleiotropic phenotypes with such features as short siliques with fewer ovules, pollen and seed sterility, altered Megaspore Mother Cell (MMC) specification, and delayed programmed cell death in megaspores and the tapetum, features that overlapped those in other well-characterized mutants. Seed sterility and reduced transmission frequency of the mutant alleles pointed to a dual role, sporophytic and gametophytic, for the gene on the male side. The mutant also showed altered expression of various genes involved in such cellular and developmental pathways as regulation of transcription, biosynthesis and transport of lipids, hormone-mediated signaling, and gametophyte development. The diverse phenotypes of the mutant and the altered expression of key genes related to gametophyte and seed development could be explained based on the functional similarly between At5g26290 and MATH-BTB domain proteins that modulate gene expression through the ubiquitin-mediated proteasome system. These results show a novel link between a TRAF-like gene and reproductive development in plants.

Biotechnological approaches to the production of shikonins: a critical review with recent updates.

Shikonins are commercially important secondary compounds, known for array of biological activities such as antimicrobial, insecticidal, antitumor, antioxidants, etc. These compounds are usually colored and therefore have application in food, textiles and cosmetics. Shikonin and its derivatives, which are commercially most important of the naphthoquinone pigments, are distributed among members of the family Boraginaceae. These include different species of Lithospermum, Arnebia, Alkanna, Anchusa, Echium and Onosma. The growing demand for plant-based natural products has made this group of compounds one of the enthralling targets for their in vitro production. The aim of this review is to highlight the recent progress in production of shikonins by various biotechnological means. Different methods of increasing the levels of shikonins in plant cells such as selection of cell lines, optimization of culture conditions, elicitation, in situ product removal, genetic transformation and metabolic engineering are discussed. The experience of different researchers working worldwide on this aspect is also considered. Further, to meet market demand, the needs for continuous and reliable production systems, as well as future prospects, are included.

Expression of SOD and APX genes positively regulates secondary cell wall biosynthesis and promotes plant growth and yield in Arabidopsis under salt stress.

Abiotic stresses cause accumulation of reactive oxygen species (ROS), such as hydrogen peroxide (H2O2) in plants. Sophisticated mechanisms are required to maintain optimum level of H2O2 that acts as signalling molecule regulating adaptive response to salt stress. CuZn-superoxide dismutase (CuZn-SOD) and ascorbate peroxidase (APX) constitute first line of defence against oxidative stress. In the present study, PaSOD and RaAPX genes from Potentilla atrosanguinea and Rheum australe, respectively were overexpressed individually as well as in combination in Arabidopsis thaliana. Interestingly, PaSOD and dual transgenic lines exhibit enhanced lignin deposition in their vascular bundles with altered S:G ratio under salt stress. RNA-seq analysis revealed that expression of PaSOD gene in single and dual transgenics positively regulates expression of lignin biosynthesis genes and transcription factors (NACs, MYBs, C3Hs and WRKY), leading to enhanced and ectopic deposition of lignin in vascular tissues with larger xylem fibres and alters S:G ratio, as well. In addition, transgenic plants exhibit growth promotion, higher biomass production and increased yield under salt stress as compared to wild type plants. Our results suggest that in dual transgenics, ROS generated during salt stress gets converted into H2O2 by SOD and its optimum level was maintained by APX. This basal level of H2O2 acts as messenger for transcriptional activation of lignin biosynthesis in vascular tissue, which provides mechanical strength to plants. These findings reveal an important role of PaSOD and RaAPX in enhancing salt tolerance of transgenic Arabidopsis via increased accumulation of compatible solutes and by regulating lignin biosynthesis.

Crop-ecology and nutritional variability influence growth and secondary metabolites of Stevia rebaudiana Bertoni.

BACKGROUND: Plant nutrition and climatic conditions play important roles on the growth and secondary metabolites of stevia (Stevia rebaudiana Bertoni); however, the nutritional dose is strongly governed by the soil properties and climatic conditions of the growing region. In northern India, the interactive effects of crop ecology and plant nutrition on yield and secondary metabolites of stevia are not yet properly understood. Thus, a field experiment comprising three levels of nitrogen, two levels of phosphorus and three levels of potassium was conducted at three locations to ascertain whether the spatial and nutritional variability would dominate the leaf yield and secondary metabolites profile of stevia. RESULTS: Principal component analysis (PCA) indicates that the applications of 90 kg N, 40 kg P2O5 and 40 kg K2O ha-1 are the best nutritional conditions in terms of dry leaf yield for CSIR-IHBT (Council of Scientific and Industrial Research- Institute Himalayan Bioresource Technology) and RHRS (Regional Horticultural Research Station) conditions. The spatial variability also exerted considerable effect on the leaf yield and stevioside content in leaves. Among the three locations, CSIR-IHBT was found most suitable in case of dry leaf yield and secondary metabolites accumulation in leaves. CONCLUSIONS: The results suggest that dry leaf yield and accumulation of stevioside are controlled by the environmental factors and agronomic management; however, the accumulation of rebaudioside-A (Reb-A) is not much influenced by these two factors. Thus, leaf yield and secondary metabolite profiles of stevia can be improved through the selection of appropriate growing locations and proper nutrient management.

Osmotin-expressing transgenic tea plants have improved stress tolerance and are of higher quality.

Drought is a major stress that affects the yield and quality of tea, a widely consumed beverage crop grown in more than 20 countries of the world. Therefore, osmotin gene-expressing transgenic tea plants produced using earlier optimized conditions were evaluated for their tolerance of drought stress and their quality. Improved tolerance of polyethylene glycol-induced water stress and faster recovery from stress were evident in transgenic lines compared with the normal phenotype. Significant improvements in growth under in-vitro conditions were also observed. Besides enhanced reactive oxygen species-scavenging enzyme activity, the transgenic lines contained significantly higher levels of flavan-3-ols and caffeine, key compounds that govern quality and commercial yield of the beverage. The selected transgenic lines have the potential to meet the demands of the tea industry for stress-tolerant plants with higher yield and quality. These traits of the transgenic lines can be effectively maintained for generations because tea is commercially cultivated through vegetative propagation only.

Differential proteomics of Picrorhiza kurrooa Royle ex Benth. in response to dark stress.

Picrorhiza (Picrorhiza kurrooa Royle ex Benth.) an important medicinal herb of western Himalayan region has been used to treat various diseases and disorders. Over-harvesting and lack of cultivation has led to its entry in Red Data Book as an endangered species. Further, its very restrictive habitat and lesser biomass production are major limitations for bringing it under commercial cultivation. All these issues necessitate deeper insights into mechanisms governing its growth and interaction with the environmental cues. Light may be one of the important factors to be studied for its role in regulating growth and adaptation of Picrorhiza as in natural habitat it prefers shady niches. Keeping this in view, proteome of Picrorhiza kept under light vis-à-vis under dark was analysed and compared. Leaf as well as root proteome of Picrorhiza was studied. Denaturing two dimensional gel electrophoresis and mass spectrometry techniques were used to detect and identify differentially expressed proteins, respectively. Twenty two proteins from leaf and 25 proteins from root showed differential expression levels under dark and light conditions. Among the differentially expressed proteins, majority were those involved in metabolism, protein synthesis, and stress and defense response. Other differentially expressed proteins were those involved in photosynthetic process, photorespiration and few proteins were with unknown function indicating that many different processes work together to establish a new cellular homeostasis in response to dark and light conditions. Proteins found to be differentially expressed under light vis-à-vis dark conditions suggested a range of biochemical pathways and processes being associated with response of plant to dark conditions. The identified proteins may be utilized for developing strategies for improving the biomass production/performance of Picrorhiza under varied light/dark habitats.

A simple technique for tracking individual spore and gametophyte development in Adiantum lunulatum Burm. f. using modified extra thin alginate film technique.

A new technique was developed for accurate calculation of percent germination and tracking of individual spores from germination to gametophyte development in Adiantum lunulatum. High percentage of ETAF immobilized spore germination (72.4%) was followed by development of gametophytic clumps. The ETAF immobilized clumps were cut into pieces and multiplied en masse. Apomictic sporophytes developed from the gametophytes. This indicated the potential of ETAF for mass propagation of A. lunulatum without the need to start from spores. Since individual spores can be tracked from germination to gametophyte development, the ETAF technique has the potential to be used for (i) harvesting uniformly developed plants of similar age for extensive experimentations and commercial utilization and (ii) detailed study on developmental and reproductive biology of different ferns and fern allies.

Components of antioxidant system of Picrorhiza kurrooa exhibit different spatio-temporal behavior.

Antioxidant system is one of the important factors in regulating plant growth, development and adaptation. Thus, in order to have better insights into molecular mechanisms of growth and adaptation of a plant it is prerequisite to have known the status of various components of the antioxidant system of the plant. Here we studied the status of enzymatic and non-enzymatic components of the antioxidant system of picrorhiza (Picrorhiza kurrooa). Picrorhiza is an important medicinal herb of western Himalayan region and has been listed in the Red Data Book as an endangered species. Spatio-temporal analysis of ascorbic acid and glutathione in leaf, root and rhizome during different stages of development revealed differential status of these antioxidant molecules. Of the three tissues, ascorbic acid was found to be highest in leaves and lowest in roots. Interestingly, just opposite to that, glutathione was highest in roots and lowest in leaves. Using degenerate primers based approach followed by rapid amplification of complementary DNA (cDNA) ends method, full length cDNAs of three important genes namely Picrorhiza kurrooa ascorbate peroxidase (pkapx), Picrorhiza kurrooa monodehydroascorbate reductase (pkmdhar) and Picrorhiza kurrooa glutathione reductase (pkgr) of antioxidant system were cloned from picrorhiza. Complementary DNAs of pkapx, pkmdhar and pkgr contained 1,049, 2,016 and 1,664 bp, respectively. Expression analysis showed differential spatio-temporal expression of these genes. Expressions of all the three genes were found higher in roots as compared to rhizome and leaves. Temporal expression analysis of pkapx, pkmdhar and pkgr revealed differential transcript levels. Expression of pkapx exhibited negative correlation with the light intensity. Just opposite to the pkapx, expression pattern of pkgr revealed its positive correlation with light intensity. Expression pattern of pkmdhar revealed its light independent expression behavior. The findings may be useful to assess the role of cloned genes in picrorhiza growth, adaptation and can further be utilized for transgenic development for desired trait(s).

De novo sequencing and characterization of Picrorhiza kurrooa transcriptome at two temperatures showed major transcriptome adjustments.

BACKGROUND: Picrorhiza kurrooa Royle ex Benth. is an endangered plant species of medicinal importance. The medicinal property is attributed to monoterpenoids picroside I and II, which are modulated by temperature. The transcriptome information of this species is limited with the availability of few hundreds of expressed sequence tags (ESTs) in the public databases. In order to gain insight into temperature mediated molecular changes, high throughput de novo transcriptome sequencing and analyses were carried out at 15 °C and 25 °C, the temperatures known to modulate picrosides content. RESULTS: Using paired-end (PE) Illumina sequencing technology, a total of 20,593,412 and 44,229,272 PE reads were obtained after quality filtering for 15 °C and 25 °C, respectively. Available (e.g., De-Bruijn/Eulerian graph) and in-house developed bioinformatics tools were used for assembly and annotation of transcriptome. A total of 74,336 assembled transcript sequences were obtained, with an average coverage of 76.6 and average length of 439.5. Guanine-cytosine (GC) content was observed to be 44.6%, while the transcriptome exhibited abundance of trinucleotide simple sequence repeat (SSR; 45.63%) markers.Large scale expression profiling through "read per exon kilobase per million (RPKM)", showed changes in several biological processes and metabolic pathways including cytochrome P450s (CYPs), UDP-glycosyltransferases (UGTs) and those associated with picrosides biosynthesis. RPKM data were validated by reverse transcriptase-polymerase chain reaction using a set of 19 genes, wherein 11 genes behaved in accordance with the two expression methods. CONCLUSIONS: Study generated transcriptome of P. kurrooa at two different temperatures. Large scale expression profiling through RPKM showed major transcriptome changes in response to temperature reflecting alterations in major biological processes and metabolic pathways, and provided insight of GC content and SSR markers. Analysis also identified putative CYPs and UGTs that could help in discovering the hitherto unknown genes associated with picrosides biosynthesis.

Alpha-tubulin (CsTUA) up-regulated during winter dormancy is a low temperature inducible gene in tea [Camellia sinensis (L.) O. Kuntze].

The present manuscript describes cloning and expression characterization of alpha-tubulin (CsTUA) gene in an evergreen tree tea [Camellia sinensis (L.) O. Kuntze] in response to winter dormancy (WD), abiotic stresses (sodium chloride, polyethylene glycol, and hydrogen peroxide) and plant growth regulators [abscisic acid (ABA), gibberellic acid (GA(3)), indole-3-butyric acid (IBA), and 6-benzylaminopurine (BA)]. CsTUA encoded a putative protein of 449 amino acids with a calculated molecular weight of 49.6 kDa and an isoelectric point (pI) of 5.09. CsTUA shared 76-84 and 90-95% identity at nucleotide and amino acid level, respectively with TUA genes from other plant species. During the period of active growth (PAG), CsTUA showed maximum expression in floral buds as compared to leaf, stem, fruit and root. Though the transcript was not detectable in the younger leaf tissue during the PAG, the expression was induced within 24 h of the low temperature (LT) treatment. The expression was not modulated by the plant growth regulators either in the tissue harvested during PAG or during WD. It was interesting to record that the expression of CsTUA was up-regulated in response to sodium chloride, polyethylene glycol, and hydrogen peroxide. Data has been discussed on the possible role of CsTUA in imparting tolerance to stresses including to LT so that the tea does not exhibit deciduous nature during winters.

Protein dynamics during seed germination under copper stress in Arabidopsis over-expressing Potentilla superoxide dismutase.

Copper (Cu), though an essential micronutrient for plants, poses toxicity at higher concentrations possibly by inducing oxidative stress. With the background that enzyme superoxide dismutase (SOD) ameliorates oxidative stress, the present work focused on understanding physiological and proteomic response of Arabidopsis seeds constitutively over-expressing copper-zinc SOD of Potentilla atrosanguinea (PaSOD) during germination in response to varied concentrations of copper sulphate (Cu stress). Transgenics showed higher germination percentage and required less "mean time to germination" under Cu-stress. In response to Cu stress, 39 differentially expressed protein spots were detected by 2-D electrophoresis in proteins of germinating wild type (WT) and transgenic seeds, of which 14 spots appeared exclusively in transgenics. Among the rest 25 protein spots, 14 showed down-regulation, one showed up-regulation, and 10 spots disappeared. MALDI-TOF and subsequent peptide mass fingerprinting analysis revealed that the down-regulated proteins in transgenics were related to oxidative stress, detoxification, germination, intermediary metabolism and regulatory proteins. Up-regulated proteins in WT and down-regulated proteins in transgenic during Cu stress were the same. Changes in key proteins, vis-à-vis alleviation of oxidative stress in transgenic Arabidopsis over-expressing PaSOD possibly alleviated toxicity of Cu-induced stress during seed germination, resulting in higher germination rate and germination percentage.

Identification and validation of sex-linked SCAR markers in dioecious Hippophae rhamnoides L. (Elaeagnaceae).

The actinorhizal plant seabuckthorn (Hippophae rhamnoides L., Elaeagnaceae) is a wind pollinated dioecious crop. To distinguish male genotypes from female genotypes early in the vegetative growth phase, we have developed robust PCR-based marker(s). DNA bulk samples from 20 male and 20 female plants each were screened with 60 RAPD primers. Two primers, OPA-04 and OPT-06 consistently amplified female-specific (FS) polymorphic fragments of 1,164 and 868 bp, respectively, that were absent in the male samples. DNA sequence of the two markers did not exhibit significant similarity to previously characterized sequences. A sequence-characterized amplified region marker HrX1 (JQ284019) and HrX2 (JQ284020) designed for the two fragments, continued to amplify the FS allele in 120 female plants but not in 100 male plants tested in the current study. Thus, HrX1 and HrX2 are FS markers that can determine the sex of seabuckthorn plants in an early stage and expedite cultivations for industrial applications.

Producing low-caffeine tea through post-transcriptional silencing of caffeine synthase mRNA.

In this study, attempt has been made to produce a selected cultivar of tea with low-caffeine content using RNAi technology. The caffeine biosynthetic pathway in tea has been proposed to involve three N-methyltransferases such as xanthosine methyltransferase, 7-N-methylxanthine methyltransferase and 3, 7-dimethylxanthine methyltransferase. Last two steps of caffeine biosynthesis in tea have been known to be catalyzed by a bifunctional enzyme known as caffeine synthase. To suppress the caffeine synthesis in the selected tea [Camellia sinensis (L.) O. Kuntze] cv. Kangra jat, we isolated a partial fragment of caffeine synthase (CS) from the same cultivar and used to design RNAi construct (pFGC1008-CS). Somatic embryos were transformed with the developed construct using biolistic method. Transformed somatic embryos showed reduction in the levels of CS transcript expression as well as in caffeine content. Plants were regenerated from the transformed somatic embryos. Transgenic plants showed a significant suppression of CS transcript expression and also showed a reduction of 44-61% in caffeine and 46-67% in theobromine contents as compared to the controls. These results suggest that the RNAi construct developed here using a single partial fragment of CS gene reduced the expression of the targeted endogenous gene significantly. However, the reduction in theobromine content in addition to caffeine documented the involvement of this single CS in the catalysis of last two methyl transfer steps in caffeine biosynthesis of tea.

Identification and cross-species transferability of 112 novel unigene-derived microsatellite markers in tea (Camellia sinensis).

PREMISE OF THE STUDY: Tea Unigene-derived MicroSatellite (TUGMS) markers were identified from the publicly available EST data in Camellia sinensis for characterization and future genome mapping studies in tea. METHODS AND RESULTS: One hundred twelve novel TUGMS markers were identified from 4356 unigenes derived by clustering of 12788 random ESTs in C. sinensis. Amplification-based validation of the TUGMS loci proved them to be highly polymorphic [an average (av.) of 5.24 alleles], heterozygous (H(E), av. 0.746; H(o), av. 0.566) and informative (PIC, av. 0.392). TUGMS loci were 100% transferable in cultivated C. assamica and C. assamica subsp. lasiocalyx and highly cross-transferrable to the related species C. japonica, C. rosiflora, and C. sasanqua. CONCLUSIONS: These 112 novel highly polymorphic TUGMS markers with proven cross-species transferability will facilitate the future genetic diversity and genome mapping studies in tea.

Abscisic acid response element binding factor 1 is required for establishment of Arabidopsis seedlings during winter.

Abscisic acid (ABA) plays a crucial role in abiotic stress response apart from its influence on growth and development of a plant. Our studies on abscisic acid response element binding factor 1 (ABF1) gene in Arabidopsis demonstrate that it is required for seedling establishment during winter. ABF1 is also involved in regulating seed dormancy and seed germination to some extent. Analysis of transcriptional activity of ABF1 promoter reveals that ABF1 expresses specifically in trichomes of young leaves and constitutively in cotyledons, roots, older leaves and flowers. The expression is induced upon exposure to ABA, cold and heat. The alignment of cDNAs of ABF1 (At1g49720) and At1g49730 (encodes a protein kinase of unknown function), reveals an overlap of 88 bp at their 3' UTR region suggesting that they can potentially form natural cis-antisense mRNAs pair in a tail-to-tail manner. Analysis by Genevestigator microarray stress response viewer further supports the regulatory role of these genes. An inverse proportion is observed in the transcription the two loci in number of stress responses. The abf1 mutants do not show any seedling establishment defects when grown under standard growth conditions. The mutant seedlings exhibit growth defects during winter in the western Himalayan region. Our study also signifies the importance of functional analysis for mutant phenotypes in natural habitats by reverse genetic approaches, in order to identify specific function of particular gene/s whose expression level is altered upon exposure to changes in environmental cues such as temperature and light.

Light and temperature regulated terpene biosynthesis: hepatoprotective monoterpene picroside accumulation in Picrorhiza kurrooa.

Picrorhiza (Picrorhiza kurrooa) is an endangered medicinal plant with well-known hepatoprotective activity attributed to monoterpenoid picrosides. The present article details on regulatory genes of terpenoid metabolism, 3-hydroxy-3-methylglutaryl coenzyme A reductase (pkhmgr) and 1-deoxy-D-xylulose-5-phosphate synthase (pkdxs) from picrorhiza. Since no molecular information was available, these genes were cloned to full-length by degenerate primers and rapid amplification of cDNA ends, followed by cloning of the upstream sequences that showed the presence of core sequences for light and temperature responsiveness. Electrophoretic mobility shift assay confirmed binding of protein to these motifs. Expression of pkhmgr and pkdxs was up-regulated at 15 degrees C as compared to at 25 degrees C as well as under light as compared to dark conditions. Picrosides content exhibited the trend similar to gene expression. To rule out the possible limitation of carbon pool under dark condition, plantlets of picrorhiza were raised in vitro in Murashige and Skoog medium supplemented with 3% sucrose. Results showed similar up-regulation of both the genes and the higher picrosides content in in vitro raised plantlets in the presence of light. Data suggested the important roles played by light and temperature in regulating pkhmgr and pkdxs, and the picrosides level in picrorhiza.

Direct shoot regeneration from intact leaves of Arnebia euchroma (Royle) Johnston using thidiazuron.

The present study highlights the importance of preculture time and concentration of TDZ (thidiazuron) for direct regeneration from in vitro leaves (attached to shoots) in Arnebia euchroma. Shoot buds proliferated to form multiple shoots on MS medium (Murashige and Skoog medium) with 5.0 microM Kn. Different additives viz. ascorbic acid, PVP (polyvinylpyrrolidone), PVPP (polyvinylpolypyrrolidone) or activated charcoal (50, 100 and 250 mg/l each) were used to check the phenolic exudations. Direct shoot regeneration was obtained when shoots were initially precultured for 40 days on medium with a higher concentration of TDZ (20.0 muM) and then transferred to a lower concentration (5.0 microM TDZ). The identity of shoot buds was confirmed by histological studies. Regenerated shoots were cultured for 30 days on medium containing Kn (5.0 microM) for proliferation and then transferred to IBA (0.25 microM)-containing medium for rooting. Rooted plantlets were transferred to greenhouse with 45-50% survival.

Early low-temperature responsive mitogen activated protein kinases RaMPK1 and RaMPK2 from Rheum australe D. Don respond differentially to diverse stresses.

Rheum grows luxuriantly in a niche of low temperature (LT) at high altitudes in Himalayan belt. The plant is expected to harbor novel genes particularly for tolerance to LT. Using differential display, two cDNAs RaMPK1 and RaMPK2, showing homology to mitogen-activated protein kinases (MAPKs) were isolated. As compared to RaMPK1, RaMPK2 exhibited strong up-regulation in response to LT. RaMPK1 was novel in terms of possessing a small glutamine and proline rich region at the N-terminal end. Secondly, though RaMPK1 showed homology with salicylic acid (SA) responsive MAPKs, the gene was down-regulated by SA but activated by jasmonate (JA). Abscisic acid (ABA) and polyethylene glycol (PEG) also down-regulated RaMPK1. RaMPK2 showed down-regulation within 5 min of exposure to JA and SA treatments, followed by gradual increase in expression. Expression of RaMPK2 was wavy in response to ABA and PEG treatment. Results are discussed in light of the novelty of these MAPKs.

Characterization of gene expression of QM from Caragana jubata, a plant species that grows under extreme cold.

Caragana [Caragana jubata (Pall.) Poir] is a temperate plant that thrives well under extremes of cold in high altitude of Himalaya and hence the plant is expected to be a source of genes that might play an important role in tolerance to low temperature (LT). In order to identify LT inducible gene(s), differential display of mRNA (DD) was performed using the apical buds growing under snow as well as growing in the near vicinity without snow, and a LT inducible QM gene (CjQM) homologue was identified. Realizing the importance of QM gene (which encodes human Wilms' tumor suppressor QM protein) in aggregation of 40 and 60S ribosomal subunit and that not much has been reported on this gene in plant systems in relation to its relationship with LT, full length cDNA of CjQM was cloned through rapid amplification of cDNA ends. The gene (977 bp), encoded by small gene family, had an open reading frame of 651 bp and was found to be intronless. The gene exhibited up-regulation within 20 min of exposure to LT and abscisic acid (ABA), but no significant change in gene expression was observed in response to drought stress (DS), salicylic acid (SA) and methyl jasmonate (MJ) application. Up-regulation of CjQM was obtained in the tissues growing in situ under snow. Non-responsiveness of CjQM towards DS, SA and MJ, but up-regulation in response to LT and ABA suggested a specific regulation of the gene in Caragana under varied cues.