Overexpression of GlyI and GlyII genes in transgenic tomato (Solanum lycopersicum Mill.) plants confers salt tolerance by decreasing oxidative stress

The glyoxalase system plays an important role in various physiological processes in plants, including salt stress tolerance. We report the effects of overexpressing glyoxalase I and glyoxalase II genes in transgenic tomato (Solanum lycopersicum Mill.) cv. Ailsa Craig. Stable expression of both transgenes was detected in the transformed tomato plants under salt stress. The transgenic lines overexpressing GlyI and GlyII under a high NaCl concentration (800 mM) showed reduced lipid peroxidation and the production of H₂O₂ in leaf tissues. A greater decrease in the chlorophyll a+b content in wild-type (WT) compared with transgenic lines was also observed. These results suggest that the over expression of two genes, GlyI and GlyII, may enhance salt stress tolerance by decreasing oxidative stress in transformed tomato plants. This work will help our understanding of the putative role of the glyoxalase system in the tolerance to abiotic stress in tomato plants.     

Stress-inducible overexpression of <Emphasis Type="Italic">glyoxalase I</Emphasis> is preferable to its constitutive overexpression for abiotic stress tolerance in transgenic <Emphasis Type="Italic">Brassica juncea</Emphasis>

The glyoxalase system catalyzes the conversion of cytotoxic methylglyoxal to d-lactate via the intermediate S-d-lactoylglutathione. It comprises two enzymes, Glyoxalase I (Gly I) and Glyoxalase II (Gly II), and reduced glutathione which acts as a cofactor by anchoring the substrates in the active sites of the two enzymes. The overexpression of both Gly I and Gly II, either alone or in combination, has earlier been reported to confer tolerance to multiple abiotic stresses. In the present study, we sought to evaluate the consequences of constitutive and stress-induced overexpression of Gly I on the performance and productivity of plants. Towards this end, several Gly I transgenic Brassica juncea lines (designated as R and S lines) were generated in which the glyoxalase I (gly I) gene was expressed under the control of either a stress-inducible rd29A promoter or a constitutive CaMV 35S promoter. Both the R and S lines showed enhanced tolerance to salinity, heavy metal, and drought stress when compared to untransformed control plants. However, the S lines showed yield penalty under non-stress conditions while no such negative effect was observed in the R lines. Our results indicate that the overexpression of the gly I gene under the control of stress-inducible rd29A promoter is a better option for improving salt, drought and heavy metal stress tolerance in transgenic plants.     

Enhancing salt tolerance in a crop plant by overexpression of glyoxalase II

Earlier we have shown the role of glyoxalase overexpression in conferring salinity tolerance in transgenic tobacco. We now demonstrate the feasibility of same in a crop like rice through overproduction of glyoxalase II. The rice glyoxalase II was cloned in pCAMBIA1304 and transformed into rice (Oryza sativa cv PB1) via Agrobacterium. The transgenic plants showed higher constitutive activity of glyoxalase II that increased further upon salt stress, reflecting the upregulation of endogenous glyoxalase II. The transgenic rice showed higher tolerance to toxic concentrations of methylglyoxal (MG) and NaCl. Compared with non-transgenics, transgenic plants at the T1 generation exhibited sustained growth and more favorable ion balance under salt stress conditions. Sneh L. Singla-Pareek and Sudesh Kumar Yadav have contributed equally to this work.     

Methylglyoxal levels in plants under salinity stress are dependent on glyoxalase I and glutathione

Methylglyoxal (MG), a cytotoxic by-product produced mainly from triose phosphates, is used as a substrate by glyoxalase I. In this paper, we report on the estimation of MG level in plants which has not been reported earlier. We show that MG concentration varies in the range of 30-75 microM in various plant species and it increases 2- to 6-fold in response to salinity, drought, and cold stress conditions. Transgenic tobacco underexpressing glyoxalase I showed enhanced accumulation of MG which resulted in the inhibition of seed germination. In the glyoxalase I overexpressing transgenic tobacco, MG levels did not increase in response to stress compared to the untransformed plants, however, with the addition of exogenous GSH there was a decrease in MG levels in both untransformed and transgenic plants. The exogenous application of GSH reduced MG levels in WT to 50% whereas in the transgenic plants a 5-fold decrease was observed. These studies demonstrate an important role of glyoxalase I along with GSH concentration in maintaining MG levels in plants under normal and abiotic stress conditions.     

Transgenic tobacco plants overexpressing glyoxalase enzymes resist an increase in methylglyoxal and maintain higher reduced glutathione levels under salinity stress

The mechanism behind enhanced salt tolerance conferred by the overexpression of glyoxalase pathway enzymes was studied in transgenic vis-à-vis wild-type (WT) plants. We have recently documented that salinity stress induces higher level accumulation of methylglyoxal (MG), a potent cytotoxin and primary substrate for glyoxalase pathway, in various plant species [Yadav, S.K., Singla-Pareek, S.L., Ray, M., Reddy, M.K. and Sopory, S.K. (2005) MG levels in plants under salinity stress are dependent on glyoxalase I and glutathione. Biochem. Biophys. Res. Commun. 337, 61-67]. The transgenic tobacco plants overexpressing glyoxalase pathway enzymes, resist an increase in the level of MG that increased to over 70% in WT plants under salinity stress. These plants showed enhanced basal activity of various glutathione related antioxidative enzymes that increased further upon salinity stress. These plants suffered minimal salinity stress induced oxidative damage measured in terms of the lipid peroxidation. The reduced glutathione (GSH) content was high in these transgenic plants and also maintained a higher reduced to oxidized glutathione (GSH:GSSG) ratio under salinity. Manipulation of glutathione ratio by exogenous application of GSSG retarded the growth of non-transgenic plants whereas transgenic plants sustained their growth. These results suggest that resisting an increase in MG together with maintaining higher reduced glutathione levels can be efficiently achieved by the overexpression of glyoxalase pathway enzymes towards developing salinity stress tolerant plants.     

高粱ATP合成酶E亚基基因(SbATPase-E)的克隆及其抗逆功能研究

高粱是一种抗旱性较强的禾谷类作物。本研究在高粱中克隆到一个全长为693 bp的编码ATP合成酶E亚基的基因(SbATPase-E)。在高粱幼苗期,SbATPase-E基因受Na Cl和脱落酸(ABA)处理诱导上调表达。该基因在拟南芥中过量表达可提高转基因植株的耐旱性和耐盐性,在逆境胁迫条件下转基因拟南芥植株较野生型植株根系发达,可能是转基因植株耐旱性和耐盐性提高的主要原因。在干旱胁迫条件下,转基因植株中DREB2A、P5CS1、RD29A、RAB18和ABI1基因的表达量相对于野生型植株中的表达量提高更为显著;在高盐处理条件下,转基因植株中SOS1和SOS2基因的表达量也较野生型植株中的表达量明显提高。这些抗逆相关基因的上调表达可能是转基因植株抗逆性提高的主要分子机制。     

ptc-miR801人工microRNA表达载体构建及功能初步研究

在构建盐胁迫下青杨microRNA文库中发现了ptc-miR801,为探索植物在盐胁迫条件下ptc-miR801参与胁迫应答的机制,本实验构建了植物表达载体pCAM2300-ami801,经根癌农杆菌EHA105介导、花序侵染法获得拟南芥转基因植株。RT-PCR半定量结果显示ptc-miR801可以在转基因拟南芥中超表达且NaCl胁迫下ptc-miRNA801转基因植株种子萌发率和根长显著高于野生型,说明ptc-miR801超表达增强了转基因拟南芥耐盐性。该试验为进一步研究miR801在杨树胁迫应答机制中的作用奠定基础。     

Transgenic tobacco overexpressing glyoxalase pathway enzymes grow and set viable seeds in zinc-spiked soils

We reported earlier that engineering of the glyoxalase pathway (a two-step reaction mediated through glyoxalase I and II enzymes) enhances salinity tolerance. Here we report the extended suitability of this engineering strategy for improved heavy-metal tolerance in transgenic tobacco (Nicotiana tabacum). The glyoxalase transgenics were able to grow, flower, and set normal viable seeds in the presence of 5 mm ZnCl2 without any yield penalty. The endogenous ion content measurements revealed roots to be the major sink for excess zinc accumulation, with negligible amounts in seeds in transgenic plants. Preliminary observations suggest that glyoxalase overexpression could confer tolerance to other heavy metals, such as cadmium or lead. Comparison of relative tolerance capacities of transgenic plants, overexpressing either glyoxalase I or II individually or together in double transgenics, evaluated in terms of various critical parameters such as survival, growth, and yield, reflected double transgenics to perform better than either of the single-gene transformants. Biochemical investigations indicated restricted methylglyoxal accumulation and less lipid peroxidation under high zinc conditions in transgenic plants. Studies employing the glutathione biosynthetic inhibitor, buthionine sulfoximine, suggested an increase in the level of phytochelatins and maintenance of glutathione homeostasis in transgenic plants during exposure to excess zinc as the possible mechanism behind this tolerance. Together, these findings presents a novel strategy to develop multiple stress tolerance via glyoxalase pathway engineering, thus implicating its potential use in engineering agriculturally important crop plants to grow on rapidly deteriorating lands with multiple unfavorable edaphic factors.     

Identification of immunodominant regions of Brassica juncea glyoxalase I as potential antitumor immunomodulation targets

Glyoxalase I activity has been shown to be directly related to cancer and its inhibitors have been used as anti-cancer drugs. Immunochemical studies have shown immunochemical relatedness among animal and plant glyoxalase I, but its potential application for biomedical research has not been investigated. In order to understand the conserved immunochemical regions of the protein and to determine probable immunomodulation targets, a cellulose-bound scanning peptide library for Brassica juncea glyoxalase I was made using the spot synthesis method. Immuno-probing of the library, using B. juncea anti-glyoxalase I monospecific polyclonal antibodies, revealed three immunodominant regions, epitope I, II, and III. In the homology model of B. juncea glyoxalase I generated by threading its sequence onto the human glyoxalase I, the high accessible surface area and the hydrophilic nature of the epitopes confirmed their surface localization and hence their accessibility for antigen-antibody interaction. Epitopes I and II were specific to B. juncea glyoxalase I. Localizing the epitopes on available glyoxalase I sequences showed that epitope III containing the active site region was conserved across phyla. Therefore, this could be used as a potential immunomodulation target for cancer therapy. Moreover, as the most immunogenic epitopes were mapped on the surface of the protein, this method could be used to discover potential therapeutic targets. It is a simple and fast approach for such investigations. This study, to our knowledge, is the first in epitope mapping of glyoxalase I and has great biomedical potential.     

厚藤ASR基因克隆及功能初步分析

通过对厚藤(Ipomoea pes-caprae(Linn.)Sweet.)cDNA文库的筛选,获得了一个编码厚藤ASR(ABA-stress-ripening)基因的全长cDNA,命名为IpASR。研究结果显示,IpASR编码区全长648 bp,共编码215个氨基酸;蛋白质等电点为5.42,分子量为24.57 k D。通过在酵母中表达,发现IpASR能够提高转基因酵母的耐盐性及抗氧化能力。进一步以厚藤成年植株及幼苗为材料进行实时荧光定量PCR分析,结果表明,IpASR基因在厚藤成年植株各组织中广泛表达;高盐、甘露醇胁迫和ABA处理可诱导该基因在厚藤幼苗中的表达。结合GFP融合蛋白的亚细胞定位和生物信息学分析,发现IpASR蛋白为核蛋白,推测IpASR基因参与了厚藤生长发育的调控,并可响应ABA和非生物胁迫的诱导。     

Paclobutrazol mitigates salt stress in <Emphasis Type="Italic">indica</Emphasis> rice seedlings by enhancing glutathione metabolism and glyoxalase system

Stress-induced methylglyoxal (MG) functions as a toxic molecule, inhibiting plant physiological processes such as photosynthesis and antioxidant defense systems. In the present study, an attempt was made to investigate the MG detoxification through glutathione metabolism in indica rice [Oryza sativa L. ssp. indica cv. Pathumthani 1] under salt stress by exogenous foliar application of paclobutrazol (PBZ). Fourteen-day-old rice seedlings were pretreated with 15 mg L^?1 PBZ foliar spray. After 7 days, rice seedlings were subsequently exposed to 0 (control) or 150 mM NaCl (salt stress) for 12 days. Prolonged salt stress enhanced the production of MG molecules and the oxidation of proteins, leading to decreased activity of glyoxalase enzymes, glyoxalase I (Gly I) and glyoxalase II (Gly II). Consequently, the decreased glyoxalase activities were also associated with a decline in reduced glutathione (GSH) content and glutathione reductase (GR) activity. PBZ pretreatment of rice seedlings under salt stress significantly lowered MG production and protein oxidation, and increased the activities of both Gly I and Gly II. PBZ also increased GSH content and GR activity along with the up-regulation of glyoxalase enzymes, under salt stress. In summary, salinity induced a high level of MG and the associated oxidative damage, while PBZ application reduced the MG toxicity by up-regulating glyoxalase and glutathione defense system in rice seedlings.     

Transgenic Medicago truncatula plants that accumulate proline display nitrogen-fixing activity with enhanced tolerance to osmotic stress

Legume root nodule nitrogen-fixing activity is severely affected by osmotic stress. Proline accumulation has been shown to induce tolerance to salt stress, and transgenic plants over-expressing Delta(1)-pyrroline-5-carboxylate synthetase (P5CS), which accumulates high levels of proline, display enhanced osmotolerance. Here, we transformed the model legume Medicago truncatula with the P5CS gene from Vigna aconitifolia, and nodule activity was evaluated under osmotic stress in transgenic plants that showed high proline accumulation levels. Nitrogen fixation was significantly less affected by salt treatment compared to wild-type (WT) plants. To our knowledge, this is the first time that transgenic legumes have been produced that display nitrogen-fixing activity with enhanced tolerance to osmotic stress. We studied the expression of M. truncatula proline-related endogenous genes M. truncatulaDelta(1)-pyrroline-5-carboxylate synthetase 1 (MtP5CS1), M. truncatulaDelta(1)-pyrroline-5-carboxylate synthetase 2 (MtP5CS2), M. truncatula ornithine delta-aminotransferase (MtOAT), M. truncatula proline dehydrogenase (MtProDH) and a proline transporter gene in both WT and transgenic plants. Our results indicate that proline metabolism is finely regulated in response to osmotic stress in an organ-specific manner. The transgenic model allowed us to analyse some of the biochemical and molecular mechanisms that are activated in the nodule in response to high salt conditions, and to ascertain the essential role of proline in the maintenance of nitrogen-fixing activity under osmotic stress.     

Molecular cloning and characterization of a novel glyoxalase I gene <Emphasis Type="Italic">TaGly I</Emphasis> in wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Methylglyoxal is a kind of poisonous metabolite that can react with RNA, DNA and protein, which generally results in a number of side advert effects to cell. Glyoxalase I is a member of glyoxalase system that can detoxify methylglyoxal. An EST encoding a glyoxalase I was isolated from a SSH (suppression subtractive hybridization)-cDNA library of wheat spike inoculated by Fusarium graminearum. The corresponding full length gene, named TaGly I, was cloned, sequenced and characterized. Its genomic sequence consists of 2,719 bp, including seven exons and six introns, and its coding sequence is 929 bp with an open reading frame encoding 291 amino acids. Sequence alignment showed that there were two glyoxalase I domains in the deduced protein sequence. By using specific primers, TaGly I was mapped to chromosome 7D of wheat via a set of durum wheat ‘Langdon’ D-genome disomic-substitution lines. The result of Real-time quantitative polymerase chain reaction demonstrated that TaGly I was induced by the inoculation of Fusarium graminearum in wheat spikes. Additionally, it was also induced by high concentration of NaCl and ZnCl₂. When TaGly I was overexpressed in tobacco leaves via Agrobacterium tumefaciens infection, the transgenic tobacco showed stronger tolerance to ZnCl₂ stress relative to transgenic control with GFP. The above facts indicated that TaGly I might play a role in response to diverse stresses in plants.     

NRRB在水稻应答高盐和干旱胁迫中的功能解析

为研究NRRB在水稻抗逆反应中的作用,通过重叠延伸PCR扩增NRRB基因编码区,构建超量表达载体,并转化水稻愈伤组织获得超量表达转基因水稻植株。鉴定结果表明,该基因已被整合到水稻基因组中,并实现超量表达;同时构建了抑制表达载体,获得转基因株系,PCR检测结果证实NRRB基因在转基因水稻中受到明显抑制。对T1代转基因植株进行抗旱性、耐盐性分析,结果显示,超量表达NRRB基因增强了转基因水稻对干旱的抗性,抑制表达NRRB基因的转基因水稻对干旱的敏感性增强,表明NRRB正调控水稻对干旱的抗性;耐盐性分析表明,NRRB基因的抑制表达降低了植株对盐的敏感性。