Molecular cloning,functional characterization and expression analysis of a novel monosaccharide transporter gene <Emphasis Type="Italic">OsMST6</Emphasis> from rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Monosaccharides transporters play important roles in assimilate supply for sink tissue development. In this study, a new monosaccharide transporter gene OsMST6 was identified from rice (Oryza sativa L.). The predicted OsMST6 protein shows typical features of sugar transporters and shares 79.6% identity with the rice monosaccharide transporter OsMST3. Heterologous expression in yeast (Saccharomyces cerevisiae) demonstrated that OsMST6 is a broad-spectrum monosaccharide transporter, with a K (m) of 266.1 muMu for glucose. OsMST6-green fluorescent protein fusion protein is localized to the plasma membrane in plant. Semi-quantitative RT-PCR analysis exhibited that OsMST6 is expressed in all tested organs/tissues. In developing seeds, OsMST6 expression level is high at the early and middle grain filling stages and gradually declines later. Further analysis detected its expression in both maternal and filial tissues. RNA in situ hybridization analysis indicated that OsMST6 is predominantly expressed in the vascular parenchyma of the chalazal vein, cross-cells, nucellar tissue and endosperm of young seeds, in mesophyll cells of source leaf blades, and in pollens and the connective vein of anthers. In addition, OsMST6 expression is up-regulated by salt stress and sugars. The physiological role of OsMST6 for seed development and its roles in other sink and source tissues are discussed.     

Salt‐Treated Roots of Oryza australiensis Seedlings are Enriched with Proteins Involved in Energetics and Transport

Salinity is a major constraint on rice productivity worldwide. However, mechanisms of salt tolerance in wild rice relatives are unknown. Root microsomal proteins are extracted from two Oryza australiensis accessions contrasting in salt tolerance. Whole roots of 2‐week‐old seedlings are treated with 80 mM NaCl for 30 days to induce salt stress. Proteins are quantified by tandem mass tags (TMT) and triple‐stage Mass Spectrometry. More than 200 differentially expressed proteins between the salt‐treated and control samples in the two accessions (p‐value <0.05) are found. Gene Ontology (GO) analysis shows that proteins categorized as “metabolic process,” “transport,” and “transmembrane transporter” are highly responsive to salt treatment. In particular, mitochondrial ATPases and SNARE proteins are more abundant in roots of the salt‐tolerant accession and responded strongly when roots are exposed to salinity. mRNA quantification validated the elevated protein abundances of a monosaccharide transporter and an antiporter observed in the salt‐tolerant genotype. The importance of the upregulated monosaccharide transporter and a VAMP‐like protein by measuring salinity responses of two yeast knockout mutants for genes homologous to those encoding these proteins in rice are confirmed. Potential new mechanisms of salt tolerance in rice, with implications for breeding of elite cultivars are also discussed.     

Characterization and expression of monosaccharide transporters (osMSTs) in rice

This study deals with the cloning and characterization of monosaccharide transporter cDNAs in rice. OsMST1-3 (Oryza sativa monosaccharide transporters 1-3) have two sets of putative six transmembrane domains separated by a central long hydrophilic region. Heterologous expression of OsMST3 in the yeast Saccharomyces cerevisiae indicated that OsMST3 has transport activity for some monosaccharides in an energy-dependent H+ co-transport manner. Northern blot and in situ hybridization analyses showed that OsMST3 mRNA is detectable in leaf blades, leaf sheaths, calli and roots, especially the xylem as well as in sclerenchyma cells in the root. These results suggested that OsMST3 is involved in the accumulation of monosaccharides required for cell wall synthesis at the stage of cell thickening.     

Physiological role of rice germin-like protein 1 (OsGLP1) at early stages of growth and development in <Emphasis Type="Italic">indica</Emphasis> rice cultivar under salt stress condition

Since their discovery, germin and germin-like proteins (GLPs) were found to be associated with salt stress along with other physiological roles. Although a number of GLP family members showed spatio-temporal changes in expressional up-regulation or down-regulation upon exposure to salt stress across plant species, very little is known about any rice GLP member in relation to salt stress. Rice germin-like protein 1 (OsGLP1), belongs to “Cupin” superfamily, is a plant glycoprotein and is associated with the plant cell wall. Our previous studies on endogenous down-regulation of OsGLP1 in rice and heterologous expression in tobacco documented that the OsGLP1 possessing superoxide dismutase activity is involved in cell wall cross-linking and fungal disease resistance in plants. In the present study, the transgenic rice lines having reduced OsGLP1 expression were analyzed in advanced generation for deciphering the involvement of OsGLP1 under salt stress. OsGLP1 gene-silencing construct integated transgenic lines were confirmed by Southern hybridization and RNA-interfernce (RNAi) mediated gene-silencing of the transgenic rice lines was confirmed by northern blot analysis. The expression of endogenous OsGLP1 protein level was found to be reduced in salt sensitive indica rice cultivar Badshahbhog following salt stress. Additionally, the RNAi-mediated OsGLP1 gene-silencing in transgenic rice lines resulted improved salt tolerance as compared to the untransformed ones during seed germination, initial establishment, early seedling growth and callus proliferation. Salt tolerance nature of the OsGLP1 gene-silenced plants at early stages of growth and development depicted the negative correlation between the OsGLP1 expression and salt tolerance of rice.     

SRWD: a novel WD40 protein subfamily regulated by salt stress in rice (OryzasativaL.)

By analysis with microarray data, we found that a gene encoding a novel protein containing five WD40 repeats, was regulated by salt stress in rice and named as SRWD1 (Salt responsive WD40 protein 1). By database searching, additional four SRWD1-like genes (SRWD2-SRWD5) were found in rice genome, and these five SRWD genes formed a novel WD40 subfamily. Phylogenetic analysis showed that plant SRWD proteins divided into four groups. The significant functional divergences during SRWD evolution were found. The tissue-specific and salt responsive expression profiling for SRWD genes was investigated based on microarray data. It was found that all five SRWD genes in rice were regulated by salt stress. Further, we found that SRWD1 was regulated with different patterns by salt stress in two rice cultivars responding differently to salt stress. Our study correlates WD40 proteins with salt stress in plants and provides fundamental information for the further investigation of plant SRWD proteins.     

Characterization of rice functional monosaccharide transporter,OsMST5

cDNA of a monosaccharide transporter in rice, OsMST5 (Oryza sativa monosaccharide transporter 5) was cloned and its sugar transport activity was characterized by heterologous expression analysis. The amino acid sequence and topology were similar to the sequences and topology of other plant monosaccharide transporters. Yeast cells co-expressed with OsMST5 cDNA transported some monosaccharide substrates. The transport rate increased when ethanol as an electron donor was added, so the transporter was an energy-dependent active one. Most of the OsMST5 was expressed in panicles before pollination, indicating that it is associated with pollen development in rice.     

Proteome and phosphoproteome differential expression under salinity stress in rice (Oryza sativa) roots

Salinity stress is a major abiotic stress that limits agriculture productivity worldwide. Rice is a model plant of monocotyledons, including cereal crops. Studies have suggested a critical role of protein phosphorylation in salt stress response in plants. However, the phosphoproteome in rice, particularly under salinity stress, has not been well studied. Here, we use Pro-Q Diamond Phosphoprotein Stain to study rice phosphoproteome differential expression under salt stress. Seventeen differentially upregulated and 11 differentially downregulated putative phosphoproteins have been identified. Further analyses indicate that 10 of the 17 upregulated proteins are probably upregulated at post-translational level instead of the protein concentration. Meanwhile, we have identified 31 salt stress differentially regulated proteins using SYPRO Ruby stain. While eight of them are known salt stress response proteins, the majority has not been reported in the literature. Our studies have provided valuable new insight into plant response to salinity stress.     

Molecular identification and physiological characterization of a novel monosaccharide transporter from Arabidopsis involved in vacuolar sugar transport

The tonoplast monosaccharide transporter (TMT) family comprises three isoforms in Arabidopsis thaliana, and TMT-green fluorescent protein fusion proteins are targeted to the vacuolar membrane. TMT promoter-beta-glucuronidase plants revealed that the TONOPLAST MONOSACCHARIDE TRANSPORTER1 (TMT1) and TMT2 genes exhibit a tissue- and cell type-specific expression pattern, whereas TMT3 is only weakly expressed. TMT1 and TMT2 expression is induced by drought, salt, and cold treatments and by sugar. During cold adaptation, tmt knockout lines accumulated less glucose and fructose compared with wild-type plants, whereas no differences were observed for sucrose. Cold adaptation of wild-type plants substantially promoted glucose uptake into isolated leaf mesophyll vacuoles. Glucose uptake into isolated vacuoles was inhibited by NH(4)(+), fructose, and phlorizin, indicating that transport is energy-dependent and that both glucose and fructose were taken up by the same carrier. Glucose import into vacuoles from two cold-induced tmt1 knockout lines or from triple knockout plants was substantially lower than into corresponding wild-type vacuoles. Monosaccharide feeding into leaf discs revealed the strongest response to sugar in tmt1 knockout lines compared with wild-type plants, suggesting that TMT1 is required for cytosolic glucose homeostasis. Our results indicate that TMT1 is involved in vacuolar monosaccharide transport and plays a major role during stress responses.     

OsTIR1 and OsAFB2 downregulation via OsmiR393 overexpression leads to more tillers, early flowering and less tolerance to salt and drought in rice

The microRNA miR393 has been shown to play a role in plant development and in the stress response by targeting mRNAs that code for the auxin receptors in Arabidopsis. In this study, we verified that two rice auxin receptor gene homologs (OsTIR1 and OsAFB2) could be targeted by OsmiR393 (Os for Oryza sativa). Two new phenotypes (increased tillers and early flowering) and two previously observed phenotypes (reduced tolerance to salt and drought and hyposensitivity to auxin) were observed in the OsmiR393-overexpressing rice plants. The OsmiR393-overexpressing rice demonstrated hyposensitivity to synthetic auxin-analog treatments. These data indicated that the phenotypes of OsmiR393-overexpressing rice may be caused through hyposensitivity to the auxin signal by reduced expression of two auxin receptor genes (OsTIR1 and OsAFB2). The expression of an auxin transporter (OsAUX1) and a tillering inhibitor (OsTB1) were downregulated by overexpression of OsmiR393, which suggested that a gene chain from OsmiR393 to rice tillering may be from OsTIR1 and OsAFB2 to OsAUX1, which affected the transportation of auxin, then to OsTB1, which finally controlled tillering. The positive phenotypes (increased tillers and early flowering) and negative phenotypes (reduced tolerance to salt and hyposensitivity to auxin) of OsmiR393-overexpressing rice present a dilemma for molecular breeding.     

Overexpression of a homopeptide repeat-containing bHLH protein gene (OrbHLH001) from Dongxiang Wild Rice confers freezing and salt tolerance in transgenic Arabidopsis

Dongxiang Wild Rice (Oryza rufipogon) is the northernmost wild rice in the world known to date and has extremely high cold tolerance and many other adversity-resistant properties. To identify the genes responsible for the high stress tolerance, we isolated and characterized a basic helix-loop-helix (bHLH) protein gene OrbHLH001 from Dongxiang Wild Rice. The gene encodes an ICE1-like protein containing multiple homopeptide repeats. Expression of OrbHLH001 is induced by salt stress and is predominant in the shoots of wild rice seedlings. Overexpression of OrbHLH001 enhanced the tolerance to freezing and salt stresses in transgenic Arabidopsis. Examination of the expression of cold-responsive genes in transgenic Arabidopsis showed that the function of OrbHLH001 differs from that of ICE1 and is independent of a CBF/DREB1 cold-response pathway.     

Expression of rice Ca(2+)-dependent protein kinases (CDPKs) genes under different environmental stresses

Ca(2+)-dependent protein kinases (CDPKs) play an essential role in plant Ca(2+)-mediated signal transduction. Twenty-nine CDPK genes have been identified in the rice genome through a complete search of genome and full-length cDNA databases. Eight of them were reported previously to be inducible by different stress stimuli. Sequence comparison revealed that all 29 CDPK genes (OsCPK1-29) contain multiple stress-responsive cis-elements in the promoter region (1kb) upstream of genes. Analysis of the information extracted from the Rice Expression Database indicates that 11 of the CDPK genes are regulated by chilling temperature, dehydration, salt, rice blast infection and chitin treatment. RT-PCR and RNA gel blot hybridization were performed in this study to detect the expression 19 of the CDPK genes. Twelve CDPK genes exhibited cultivar- and tissue-specific expression; four CDPK genes (OsCPK6, OsCPK13, OsCPK17 and OsCPK25) were induced by chilling temperature, dehydration and salt stresses in the rice seedlings. While OsCPK13 (OsCDPK7) was already known to be inducible by chilling temperature and high salt, this is the first report that the other three genes are stress-regulated. OsCPK6 and OsCPK25 are up-regulated by dehydration and heat shock, respectively, while OsCPK17 is down-regulated by chilling temperature, dehydration and high salt stresses. Based on this evidence, rice CDPK genes may be important components in the signal transduction pathways for stress responses. Findings from this research are important for further dissecting mechanisms of stress response and functions of CDPK genes in rice.     

A Novel Little Membrane Protein Confers Salt Tolerance in Rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Plasma membrane proteins play critical roles in sensing and responding abiotic and biotic stresses in plants. In the present study, we characterized a previously unknown gene stress associated little protein 1 (SALP1) encoding a plasma membrane protein. SALP1, a small and plant-specific membrane protein, contains only 74 amino acid residues. SALP1 was constitutively expressed in various rice tissues while highly expressed in roots, leaf blade, and immature panicles. Expression analysis indicated that SALP1 was induced by various abiotic stresses and abscisic acid (ABA). Subcellular localization assay indicated that SALP1 was localized on plasma membrane in rice protoplast cells. Overexpressing of SALP1 in rice improved salt tolerance through increasing free proline contents and the expression level of OsP5CS gene, and balancing ion contents under salt stress. Moreover, SALP1 transgenic rice showed reduced sensitivity to ABA treatment, and expression level of SALP1 is not altered by ABI5-like 1 protein. Conclusively, SALP1, a novel membrane protein, is involved in salt tolerance through an ABA-independent signaling pathway in rice.     

Cloning, Localization, and Expression Analysis of a New Tonoplast Monosaccharide Transporter from Vitis vinifera L

Tonoplast sugar transporters are important for sugar partitioning, immobilization, and accumulation during fruit development and ripening. Here we report the cloning, localization, and functional analysis of one of these transporters in grape berries (Vitis vinifera L.). This clone, named VvTMT1, encodes a 742-aa protein with a calculated molecular mass of 80.2 kDa. Predicted membrane topology and phylogenetic analysis suggest that VvTMT1 belongs to the major facilitator superfamily of membrane carriers. Semiquantitative RT-PCR suggests that VvTMT1 is a sink-specific transporter, whose expression decreases with berry development. Heterologous expression of VvTMT1 in yeast can partially restore growth of the hxt-null strain in glucose and other monosaccharide media, indicating that VvTMT1 is a functional monosaccharide transporter. Induction of VvTMT1-GFP fusion protein expression in transgenic yeast revealed its tonoplast localization. The subcellular localization of VvTMT1 in plants was shown by immunogold labeling of grape berry mesocarp cells and VvTMT1-GFP transient expression in tobacco epidermis cells. Based on the above analyses of VvTMT1, this is the first report of a functional tonoplast-localized monosaccharide transporter in grapevine.     

Isolation and characterization of a new Na+/H+ antiporter gene OsNHA1 from rice (Oryza sativa L.).

The full-length cDNA (3612 bp) of OsNHA1 was cloned by RT-PCR approach from rice (Oryza sativa L.), which encodes a putative plasma membrane Na+/H+ antiporter. Its deduced protein, OsNHA1, has 11 transmembrane domains and a significant similarity to a plasma membrane Na+/H+ antiporter AtNHA1 from Arabidopsis thaliana. Phylogenetic analysis showed that the OsNHA1 clusters with the plasma membrane Na+/H+ antiporters from various organisms. The semi-quantitative RT-PCR assay revealed that the expression of OsNHA1 was up-regulated in both shoots and roots of rice seedlings under salt stress, whereas it was not induced in the rice seedlings treated by drought stress.     

转反义OsRACK1 基因增强水稻抗旱能力

RACK1是一种多功能支架蛋白, 广泛参与植物生长发育过程的调节。利用反义RNA技术抑制水稻(Oryz a sativa)RACK1基因的表达, 分析了RACK1基因在响应干旱胁迫中的功能。采用实时定量PCR对获得的转基因植株的RACK1基因表达进行分析, 结果表明转基因水稻RACK1基因表达受抑制程度达到50%左右。与非转基因水稻(对照)相比, 转基因水稻耐干旱能力强, 膜脂过氧化程度低且丙二醛的含量少, SOD活性高。这些结果表明, RACK1蛋白负调节水稻对干旱胁迫的耐受过程, 并且这种调节作用在很大程度上与植株体内的氧化还原系统有关。     

转反义OsRACK1基因增强水稻抗旱能力

RAC1是一种多功能支架蛋白,广泛参与植物生长发育过程的调节。利用反义RNA技术抑制水稻（Oryzasativa）RACK1基因的表达,分析了RACK1基因在响应干旱胁迫中的功能。采用实时定量PCR对获得的转基因植株的RACK1基因表达进行分析,结果表明转基因水稻RACK1基因表达受抑制程度达到50％左右。与非转基因水稻（对照）相比,转基因水稻耐干旱能力强,膜脂过氧化程度低且丙二醛的含量少,SOD活性高。这些结果表明,RACK1蛋白负调节水稻对干旱胁迫的耐受过程,并且这种调节作用在很大程度上与植株体内的氧化还原系统有关。     

Ectopic expression of PgRab7 in rice plants (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) results in differential tolerance at the vegetative and seed setting stage during salinity and drought stress

In this work, we have overexpressed a vesicle trafficking protein, Rab7, from a stress-tolerant plant, Pennisetum glaucum, in a high-yielding but stress-sensitive rice variety Pusa Basmati-1 (PB-1). The transgenic rice plants were tested for tolerance against salinity and drought stress. The transgenic plants showed considerable tolerance at the vegetative stage against both salinity (200 mM NaCl) and drought stress (up to 12 days after withdrawing water). The protection against salt and drought stress may be by regulating Na⁺ ion homeostasis, as the transgenic plants showed altered expression of multiple transporter genes, including OsNHX1, OsNHX2, OsSOS1, OsVHA, and OsGLRs. In addition, decreased generation and maintenance of lesser reactive oxygen species (ROS), with maintenance of chloroplast grana and photosynthetic machinery was observed. When evaluated for reproductive growth, 89–96 % of seed setting was maintained in transgenic plants during drought stress; however, under salt stress, a 33–53 % decrease in seed setting was observed. These results indicate that PgRab7 overexpression in rice confers differential tolerance at the seed setting stage during salinity and drought stress and could be a favored target for raising drought-tolerant crops.