Project description:Chilling is a major stress which adversely decreases photosynthesis and leads to oxidative stress in thermophilic plants. The role of melatonin (MT) in stress response of plants, has so far been investigated, while the mechanisms by which MT regulate photosynthesis in chilling-sensitive cucumber under chilling stress remain unclear. In this paper, we reported MT positively regulated chilling tolerance of cucumber. Moreover, MT showed a concentration-dependent manner and 1.0 μmol·L-1 was the optimum concentration, of which the chilling injury index, EL and MDA were the lowest, while growth was the highest among all the treatments. Further studies indicated that MT triggered the activity and expression of the antioxidant enzymes, which in turn decreased ROS accumulation caused by chilling stress. Meanwhile, MT maintained a high photosynthetic carbon assimilation capacity, increased the activity of PSI reaction center, PSII reaction center and electron transfer efficiency. More importantly, the proteome analysis and western-blot data revealed that PSI-associated proteins (PsaD, PsaE, PsaF, PsaH and PsaN), PSII-associated protein D1 as well as Rubisco large subunit and RCA were significantly up-regulated in MT-treated seedlings, compared to H2O-treated seedlings under chilling stress. These results suggest that MT enhances chilling tolerance of cucumber via activating the antioxidant system as well as protein level of key PSI-, PSII-related and carbon assimilation enzymes to decrease ROS accumulation, and finally alleviates the damage to photosynthetic apparatus under chilling stress.

Project description:Improvement in the photosynthetic efficiency is a major approach to improve crop yield potential. So far, most of the demonstrated cases of photosynthesis improvement was achieved through manipulation of one or a few photosynthesis related genes. Present study found that over-expression of one maize transcription factor, mEmBP-1 gene, led to simultaneously increased expression of nearly all genes in photosynthesis pathway, including genes encoding chlorophyll a and b-binding proteins (Lhca and Lhcb), photosystem II (PsbR3 and PsbW) and PS I reaction center subunits (PsaK and PsaN), genes encoding for chloroplast ATP synthase subunit and electron transport reaction (Fd1 and PC), and also major genes in the Calvin Benson Bassham cycle, Rubisco, GAPDH, FBA, TK and PRK. This increased photosynthesis gene expression resulted in increased leaf chlorophyll pigment, photosynthetic rate, quantum yields, biomass growth and grain yield both in the greenhouse and also in natural field conditions. Using DNA-Protein binding experiment, we found that mEmBP-1a protein can directly bind to the promoter regions of photosynthesis genes, suggesting that the direct binding of mEmBP-1a to the G-box domain of photosynthetic genes upregulates expression of these genes. Hence, this study shows that mEmBP-1a is a major regulator of photosynthesis.

Project description:Understanding the molecular differences in plant genotypes contrasting for heat sensitivity can provide useful insights into the mechanisms that confer heat tolerance in plants. This study is focused on comparative physiological and proteomic analyses of heat sensitive (ICC16374) and tolerant (JG14) genotypes of chickpea (Cicer arietinum L.) when subjected to heat stress at anthesis.Comparative gel-free proteome profiles indicated differences in the expression levels and regulation of common proteins that are associated with heat tolerance in contrasting genotypes under heat stress. The differentially regulated proteins were grouped into three categories based on their involvement in the molecular functions, cellular location and biological processes. Besides the identification of heat shock proteins, other proteins such as acetyl-CoA carboxylase, pyrroline-5-carboxylate synthase (P5CS), ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCo), phenylalanine ammonia-lyase (PAL) 2, ATP synthase, glycosyltransferase, sucrose synthase and late embryogenesis abundant (LEA) proteins were strongly associated with heat tolerance in chickpea. Several crucial proteins such as cystathionine gamma-synthase, glucose-1-phosphate adenyltransferas, malate dehydrogenase, threonine synthase, and non-cyanogenic ß-glucosidase were induced by heat only in the heat tolerant genotype. Based on pathway analysis, we propose that proteins which are essentially related to the electron transport chain in photosynthesis, aminoacid biosynthesis, ribosome synthesis and secondary metabolite synthesis may play key roles in inducing tolerance to heat stress.

Project description:Increasing photosynthetic efficiency remains a major goal across the globe given its central role in CO2 assimilation. Here, we identified a nuclear genome-residing orphan gene, comprised of 3 exons, two with apparent endophytic origins and the third being a highly conserved fragment of the RIBULOSE BISPHOSPHATE CARBOXYLASE/ OXYGENASE LARGE SUBUNIT (RuBisCo). This novel gene, here-on referred to as Populus RuBisCo-like (PRL-1) gene localizes in chloroplast, endoplasmic reticulum and nuclear compartments of plant cells, acts as a transcriptional repressor and modulates adaptation to fluctuating light. P. trichocarpa genotypes with high PRL-1 expression levels quickly dissipated non-photochemical quenching (NPQ) upon transitioning from high to low light and rapidly induced NPQ upon returning to high light. The dynamic modulation of NPQ yields high quantum efficiency of linear electron transport (PSII) and 10-20% increased quantum efficiency of CO2 assimilation (CO2). The enhanced photosynthesis efficiency corresponded with increased plant height and biomass in P. trichocarpa with up to 35 % and 100% increases under field and greenhouse conditions. Transgenic Arabidopsis plants heterologously expressing the PRL-1 gene gained up to 200% in biomass and 97% in seed yield under greenhouse conditions. Taken together, PRL-1 presents a novel and trackable target for increasing photosynthetic efficiency in plants.

Project description:C3-C4 intermediate Moricandia suffruticosa showed tolerance to drought and heat stresses, and high photosynthetic capacity under these abiotic stresses as comparing with C3 relative crop rapeseed (Brassica napus). In our study, systematic analysis was conducted to reveal photosynthetic difference between C3-C4 Moricandia suffruticosa and its relative C3 rapeseed from the same Brassiceae tribe. It was found that Moricandia leaf photosynthesis and anatomy were significantly changed compared to rapeseed under drought and heat stress conditions. De novo transcriptome of Moricandia was assembled by next generation sequencing, and unigenes were mapped to respective rapeseed gene locus. Then comparative transcriptome analysis was conducted in leaf tissues of Moricandia and rapeseed under both drought and heat stresses. Main pathways and candidate genes were revealed from this analysis, which may be associated with the stress induced change in Moricandia.

Project description:Effects of heat priming applied to the first generation on tolerance of the successive generation to post-anthesis high temperature stress were investigated. Compared with the progeny of non-heat primed plants (NH), the progeny of heat-primed plants (PH) presented higher grain yield, leaf photosynthesis and activities of antioxidant enzymes and lower cell membrane damage under high temperature stress. In the transcriptome profile, 1430 probes showed obvious difference in expression between PH and NH. These genes were those of signal transduction, transcription, energy, defense, and protein destination and storage, respectively.

Project description:The C4 photosynthetic pathway provided a major advantage to plants growing in hot, dry environments, including the ancestors of our most productive crops. Two traits were essential for the evolution of this pathway: increased vein density and the functionalization of bundle sheath cells for photosynthesis. Although GRAS transcriptional regulators, including SHORT ROOT (SHR), have been implicated in mediating leaf patterning in both C3 and C4 species1-4, little is known about what controls the specialized features of the cells that mediate C4 metabolism and physiology. We show in the model monocot, Setaria viridis, that SHR regulates components of multiple cell identities, including chloroplast biogenesis and photosynthetic gene expression in bundle sheath cells, a central feature of C4 plants. Furthermore, we found that it also contributes to the two-cell compartmentalization of the characteristic four-carbon shuttle pathway. Disruption of SHR function clearly reduced photosynthetic capacity and seed yield in mutant plants under heat stress. Together, these results show how cell identities are remodeled by SHR to host the suite of traits characteristic of C4 regulation, which are a main engineering target in non-C4 crops to improve climate resilience.

Project description:In addition to leaves, the main site of photosynthetic reactions, active photosynthesis also takes place in stems, siliques and tree trunks. Although non-foliar photosynthesis has a marked effect on plant growth and yield, only limited information on the expression patterns of photosynthesis-related genes and the structure of photosynthetic machinery in different plant organs has been available. Here, we report the results of transcriptomic analysis of various organs of Arabidopsis thaliana and compare the gene expression profiles of young and mature leaves with a special focus on photosynthetic genes. Further, we analyzed the composition and organization of the photosynthetic electron transfer machinery in leaves, stems and green siliques at the protein level using BN-PAGE. RNA-Seq analysis revealed unique gene expression profiles in different plant organs and showed major differences in the expression of photosynthesis-related genes in young as compared to mature rosettes. Gel-based proteomic analysis of the thylakoid protein complex organization further showed that all studied plant organs contain the necessary components of the photosynthetic electron transfer chain. Intriguingly, stems accumulate high amounts of PSI-NDH complex, which has previously been implicated in cyclic electron transfer.

Project description:The Overexpression of AtCAMTA5 leads to higher plant weight and seed weight as compare to Col-0. Under drought condition overexpression lines had reduce water loss,high water use efficiency decline in photosynthesis contributes to 95% survivability wherase Col-0 and camta5 showed enhance sensitivity.Microarray analysis revealed that AtCAMTA5 regulates genes enriched with CAMTA recognition motif like ANAC19, SPL16, aminotransferase, chitinase, MAPK7, SnRK2.2, E3-ligase, RUBISCO, PSI and PSII, etc which were involved in stress response, development, protein modification and photosynthesis. We used affymatrix expression analysis to validate role of CAMTA5 under drought stress along with physiological and biochemical assay.

Project description:Drought is a major cause of crop yield loss worldwide. Plants can adopt different mechanisms to survive under water deficit, where stomatal closure leads to CO2 limitation. This requires increased dissipation of light energy as heat by non-photochemical quenching (NPQ), changes in the structural configuration of light-harvesting complexes, or changes in the mode of photosynthetic electron flow (i.e. linear vs. cyclic). Under field conditions, where light intensity can change rapidly, this problem becomes even more challenging. Particularly the slow release from photoprotection (NPQ relaxation) was recently shown to cause significant loss of potential yield. We analyzed the acclimation of two different wheat varieties and compared their molecular acclimation strategy to Arabidopsis under moderate drought stress at a slow soil dehydration rate, mimicking realistic field conditions. We monitored their photosynthetic activity under fluctuating light intensities and integrated functional and structural data, based on a detailed analysis of photosynthetic parameters combined with biochemical analysis and unbiased shot-gun proteomics. Contrary to previous models based on the damage of photosynthetic complexes as consequence of drought, we found that plants actively preserve and fine-tune their photosynthetic machinery under drought to adjust the photosynthetic electron transfer to fast changes of light intensity. Strikingly, Arabidopsis and wheat use different molecular strategies for this acclimation. While clear differences in NPQ relaxation and phosphorylation levels of photosynthetic proteins were observed in wheat, Arabidopsis modified the light energy distribution among photosynthetic complexes without changing PSII-LHCII phosphorylation. The fine-tuning of NPQ relaxation can therefore represent a potential trait for crop breeding.