The ABA receptor-like gene VyPYL9 from drought-resistance wild grapevine confers drought tolerance and ABA hypersensitivity in Arabidopsis

Plant Cell, Tissue and Organ Culture (PCTOC) - The PYR/PYL/RCAR (hereafter referred to PYLs) proteins, which act as abscisic acid (ABA) receptors, have been reported to play a crucial role in...     

Overexpression of AtMYB52 confers ABA hypersensitivity and drought tolerance

We carried out activation tagging screen to isolate genes regulating abscisic acid (ABA) response. From the screen of approximately 10,000 plants, we isolated ca 100 ABA response mutants. We characterized one of the mutants, designated ahs1, in this study. The mutant is ABA-hypersensitive, and AtMYB52 was found to be activated in the mutant. Overexpression analysis to recapitulate the mutant phenotypes demonstrated that ATMYB confers ABA-hypersensitivity during postgermination growth. Additionally, AtMYB52 overexpression lines were drought-tolerant and their seedlings were salt-sensitive. Changes in the expression levels of a few genes involved in ABA response or cell wall biosynthesis were also observed. Together, our data suggest that AtMYB52 is involved in ABA response. Others previously demonstrated that AtMYB52 regulates cell wall biosynthesis; thus, our results imply a possible connection between ABA response and cell wall biosynthesis.     

Carotenoid deficiency impairs ABA and IAA biosynthesis and differentially affects drought and cold tolerance in rice

Plant responses to abiotic stresses are coordinated by arrays of growth and developmental programs. Phytohormones such as abscisic acid (ABA) and indole-3-acetic acid (IAA) play critical roles in developmental progresses and environmental responses through complex signalling networks. However, crosstalk between the two hormones at the biosynthesis level remains largely unknown. Here, we report that carotenoid-deficient mutants (phs1, phs2, phs3-1, phs4, and PDS-RNAi transgenic rice) were impaired in the biosynthesis of ABA and IAA. Under drought conditions, phs3-1 and PDS-RNAi transgenic rice showed larger stomata aperture and earlier wilting compared to the wild type at both seedling and panicle developmental stage. Interestingly, these carotenoid-deficient lines showed increased cold resistance, which was likely due to the combined effects of reduced IAA content, alleviated oxidative damage and decreased membrane penetrability. Furthermore, we found that IAA content was significantly declined in rice treated with fluridone (a carotenoid and ABA biosynthesis inhibitor), and expression of auxin synthesis and metabolism-related genes were altered in the fluridone-treated rice similar to that in the carotenoid-deficient mutants. In addition, exogenous IAA, but not ABA, could restore the dwarf phenotype of phs3-1 and PDS-RNAi transgenic rice. These results support a crosstalk between ABA and IAA at the biosynthesis level, and this crosstalk is involved in development and differentially affects drought and cold tolerance in rice.     

Over-expression of ArathEULS3 confers ABA sensitivity and drought tolerance in Arabidopsis

Abscisic acid (ABA) is an important phytohormone involved in the regulation of plant growth, development and adaption to various environmental challenges. Regulatory component of ABA receptor 1 (RCAR1, also known as PYL9) acts as a newly discovered ABA receptor in Arabidopsis. To identify interacting partners of RCAR1, we have carried out a yeast two-hybrid screen. One protein was identified, ArathEULS3, which belongs to the Euonymus europaeus lectin (EUL) family of plant lectins. The interaction between RCAR1 and ArathEULS3 was confirmed by GST pull-down assay. Transient expression of RCAR1-EGFP and ArathEULS3-EGFP in Arabidopsis protoplasts revealed that both proteins were mainly expressed in cytoplasm and nucleus. Real time qRT-PCR analysis showed that over-expression of RCAR1 increased the expression of ArathEULS3. Furthermore, up-regulating ArathEULS3 in Arabidopsis conferred ABA hypersensitivity during post-germination growth and enhanced drought tolerance, but did not affect the expression of RD29B, RAB18 and RD29A (ABA- and drought-responsive genes). Previously, ArathEULS3 was shown as a carbohydrate-binding plant lectin. Thus, our results reveal a direct connection between abiotic stress responses and plant lectin.     

An ER-targeted calcium-binding peptide confers salt and drought tolerance mediated by CIPK6 in Arabidopsis

Different plant organelles have high internal stores of Ca²⁺ compared to the cytoplasm and could play independent roles in stress responses or signal transduction. We used a GFP fusion with the C-domain of calreticulin, which shows low-affinity, high capacity Ca²⁺ binding in the ER, as a calcium-binding peptide (CBP) to specifically increase stores in the ER and nucleus. Despite the presence of a signal sequence and KDEL retention sequence, our work and previous studies (Brandizzi et al. Plant Journal 34:269–281, 2003) demonstrated both ER and nuclear localization of GFP-CBP. Under normal conditions, GFP-CBP-expressing lines had ~25% more total Ca²⁺ and higher levels of chlorophyll and seed yield than wild type and GFP controls. CBP-expressing plants also had better survival under intermittent drought or high salt treatments and increased root growth. One member of the CIPK (calcineurin B-like interacting protein kinase) gene family, CIPK6, was up-regulated in CBP-expressing plants, even under non-stress conditions. A null mutation in cipk6 abolished the increased stress tolerance of CBP-transgenic plants, as well as the CBP-mediated induction of two stress-associated genes, DREB1A and RD29A, under non-stress conditions. Although this suggested that it was the induction of CIPK6, rather than localized changes in Ca²⁺, that resulted in increased survival under adverse conditions, CIPK6 induction still required Ca²⁺. This work demonstrates that ER (or nuclear) Ca²⁺ can directly participate in signal transduction to alter gene expression. The discovery of a method for increasing Ca²⁺ levels without deleterious effects on plant growth may have practical applications.     

OsMsr9, a novel putative rice F-box containing protein,confers enhanced salt tolerance in transgenic rice and Arabidopsis

Salinity is a major environmental stress that limits agricultural production and geographical distribution of plants. In a previous study, it has been shown that OsMsr9 was induced by cold, drought and heat stresses. However, functions of OsMsr9 at physiological and molecular levels are still unknown. Here, we report that OsMsr9 plays roles in salt tolerance in plants. Quantitative real-time PCR (qPCR) analysis revealed that OsMsr9 was also rapidly and strongly induced by salt stress. Overexpression of OsMsr9 in Arabidopsis and rice showed enhanced salt stress tolerance displaying increased shoot and root elongation, higher survival rates in transgenic plants compared with wild type. OsMsr9 might act as a positive regulator of plant salt tolerance with reinforced expression of stress-related genes, such as RD29A, DREB2A and RAB18 in transgenic plants under salt conditions. Furthermore, transgenic plants accumulated more compatible solutes (proline and soluble sugar) and low level of malondialdehyde, alleviating the changes in reactive oxygen species. These results indicate that OsMsr9 could be a useful gene in developing transgenic crops with enhanced salt tolerance.     

LRG1 maintains sterile lemma identity by regulating OsMADS6 expression in rice

正Dear Editor,Spikelet is the unique structural unit of grass panicles with florets and diverse glume-like organs. In rice, a normal spikelet usually has two pairs of glume-like organs, including a pair of sterile lemmas and a pair of rudimentary glumes.Generally, the sterile lemma is considered to be the severely degenerated bract, but its origin is still controversial.     

Over-expression of a single Ca2+-dependent protein kinase confers both cold and salt/drought tolerance on rice plants

A rice gene encoding a calcium-dependent protein kinase (CDPK), OsCDPK7, was induced by cold and salt stresses. To elucidate the physiological function of OsCDPK7, we generated transgenic rice plants with altered levels of the protein. The extent of tolerance to cold and salt/drought stresses of these plants correlated well with the level of OsCDPK7 expression. Therefore, OsCDPK7 was shown to be a positive regulator commonly involved in the tolerance to both stresses in rice. Over-expression of OsCDPK7 enhanced induction of some stress-responsive genes in response to salinity/drought, but not to cold. Thus, it was suggested that the downstream pathways leading to the cold and salt/drought tolerance are different from each other. It seems likely that at least two distinct pathways commonly use a single CDPK, maintaining the signalling specificity through unknown post-translational regulation mechanisms. These results demonstrate that simple manipulation of CDPK activity has great potential with regard to plant improvement.     

Over-expression of OSRIP18 increases drought and salt tolerance in transgenic rice plants

Both drought and high salinity stresses are major abiotic factors that limit the yield of agricultural crops. Transgenic techniques have been regarded as effective ways to improve crops in their tolerance to these abiotic stresses. Functional characterization of genes is the prerequisite to identify candidates for such improvement. Here, we have investigated the biological functions of an Oryza sativa Ribosome-inactivating protein gene 18 (OSRIP18) by ectopically expressing this gene under the control of CaMV 35S promoter in the rice genome. We have generated 11 independent transgenic rice plants and all of them showed significantly increased tolerance to drought and high salinity stresses. Global gene expression changes by Microarray analysis showed that more than 100 probe sets were detected with up-regulated expression abundance while signals from only three probe sets were down-regulated after over-expression of OSRIP18. Most of them were not regulated by drought or high salinity stresses. Our data suggested that the increased tolerance to these abiotic stresses in transgenic plants might be due to up-regulation of some stress-dependent/independent genes and OSRIP18 may be potentially useful in further improving plant tolerance to various abiotic stresses by over-expression.     

Heterologous expression of rice calnexin (OsCNX) confers drought tolerance in Nicotiana tabacum

Calnexin (CNX) is an integral membrane protein of endoplasmic reticulum (ER) and is a critical component of ER quality control machinery. It acts as a chaperone and ensures proper folding of newly synthesised glycoproteins. CNX shares a considerable homology with its luminal counterpart calreticulin (CRT). Together, they constitute CNX/CRT cycle which is imperative for proper folding of nascent proteins. CNX deficient organisms develop severe complications because of improper folding of proteins and consequently ER stress. CNX maintains calcium homeostasis by binding to the Ca²⁺ which is a central node in various signaling pathways. Phosphorylation of cytoplasmic tail of CNX controls the sarco endoplasmic reticulum calcium ATPase and thus the movement of Ca²⁺ in and out of its store-house, i.e. ER. Our studies on Oryza sativa CNX (OsCNX) reveal constitutive expression at various developmental stages and various tissues, thereby proving its requirement throughout the plant development. Further, its expression under various stress conditions gives an insight of the crosstalk existing between ER stress and abiotic stress signaling. This was confirmed by heterologous expression of OsCNX (OsCNX-HE) in tobacco and the OsCNX-HE lines were observed to exhibit better germination under mannitol stress and survival under dehydration stress conditions. The dehydration tolerance conferred by OsCNX appears to be ABA-dependent pathway.