The C2H2 zinc‐finger protein SlZF3 regulates AsA synthesis and salt tolerance by interacting with CSN5B

Abiotic stresses are a major cause of crop loss. Ascorbic acid (AsA) promotes stress tolerance by scavenging reactive oxygen species (ROS), which accumulate when plants experience abiotic stress. Although the biosynthesis and metabolism of AsA are well established, the genes that regulate these pathways remain largely unexplored. Here, we report on a novel regulatory gene from tomato (Solanum lycopersicum) named SlZF3 that encodes a Cys2/His2‐type zinc‐finger protein with an EAR repression domain. The expression of SlZF3 was rapidly induced by NaCl treatments. The overexpression of SlZF3 significantly increased the levels of AsA in tomato and Arabidopsis. Consequently, the AsA‐mediated ROS‐scavenging capacity of the SlZF3‐overexpressing plants was increased, which enhanced the salt tolerance of these plants. Protein–protein interaction assays demonstrated that SlZF3 directly binds CSN5B, a key component of the COP9 signalosome. This interaction inhibited the binding of CSN5B to VTC1, a GDP‐mannose pyrophosphorylase that contributes to AsA biosynthesis. We found that the EAR domain promoted the stability of SlZF3 but was not required for the interaction between SlZF3 and CSN5B. Our findings indicate that SlZF3 simultaneously promotes the accumulation of AsA and enhances plant salt‐stress tolerance.     

Genomic organization, phylogenetic comparison and expression profiles of annexin gene family in tomato (Solanum lycopersicum)

Annexins have been suggested to play pivotal roles in stress resistance and plant development. However, related studies on fruit-bearing plants, especially on fruit development, are very limited. In the present study, we provide a comprehensive overview of the annexin family in tomato, describing the gene structure, promoter cis-regulatory elements, organ expression profile, and gene expression patterns under hormone and stress treatments. Bioinformatic analysis revealed that the nine tomato annexins were structurally different from their animal counterparts, but highly conserved annexin domains were still found in most of them. Cis-regulatory element prediction showed that there were important elements in the 2kb upstream promoter regions, including stress- and hormone-responsive-related elements. The expression patterns of these genes were investigated, and the results revealed that they were regulated under developmental processes and environmental stimuli. Among them, AnnSl1.1 and AnnSl2 were highly expressed in most of the tested organs. Genes preferentially or specifically expressed in organs, such as stigma or ovary (AnnSl6), stamen (AnnSl8), and fruit pericarp (AnnSl1.2 and AnnSl9), were identified. Some annexin genes were induced by plant hormones including abscisic acid (AnnSl3, AnnSl6, AnnSl8, and AnnSl9) and gibberellic acid (AnnSl1.1, AnnSl1.2, AnnSl4, and AnnSl7). Most of these annexin genes were induced by salt, drought, wounding, and heat or cold stresses. The present study provides significant information for understanding the diverse roles of annexins in tomato growth and development.     

Molecular characterization, expression and functional analysis of the amino acid transporter gene family (OsAATs) in rice

Nitrogen (N) is one of the most important limiting factors for plant growth and development. Amino acids are the major source of organic N, which is converted from inorganic N absorbed by plant roots from the soil. Amino acid transporters are the principal mediators of organic N distribution and important regulators of resource allocation in plants. Although the complete genomic sequence of rice has already been released, there is still little known about amino acid transporter genes in rice. In this study, 79 OsAAT genes were identified by a database search of the rice genome based upon HMM profiles. A bioinformatics analysis of the complete set of OsAAT genes is presented, including chromosomal location, phylogenetic analysis, gene structure, protein analysis, conserved motifs, protein structures and cis-element analysis of the promoters. In addition, the comprehensive expression profile of OsAAT genes in rice tissues/organs under N starvation conditions was investigated by real-time PCR analysis. Diverse expression patterns of OsAAT genes indicated diverse biological functions of the amino acid transporters and the important roles of OsAAT genes in N uptake, metabolism and distribution during N starvation. The evaluation of yield and carbon (C) and N content of osaat knockout mutants also suggested the important roles of the OsAAT5, OsAAT7, OsAAT24, OsAAT49 and OsAAT60 genes in yield and biomass production and C and N metabolism and distribution in rice plants.     

Molecular analyses of tomato GS,GOGAT and GDH gene families and their response to abiotic stresses

Glutamine synthetase (GS), glutamate synthase (GOGAT) and glutamate dehydrogenase (GDH) are closely related enzymes in plant nitrogen metabolism and potential targets for improving nitrogen use efficiency. However, little research has focused on the enzyme-encoding genes in tomato. Here, a comprehensive study of these genes was conducted. Six GS genes, two GOGAT genes and five GDH genes were identified in tomato. Bioinformatics and gene expression analyses suggested that these genes evolved species-specific regulatory properties and biological functions in tomato. SlNADH-GOGAT, SlGS1.1 and SlNAD-GDHB1 were abundantly expressed in roots, SlGS1.1 can be induced by nitrogen deprivation, and SlGS1.2, SlGS1.3, SlNADH-GOGAT and SlNAD-GDHB1 can be induced by the re-supply of nitrogen after 5 days of deprivation, they may play key roles in primary nitrogen assimilation. SlFd-GOGAT, SlGS1.1 and SlNAD-GDHA1-A2 were also highly expressed in fruits, indicating their important roles in fruit development and ripening. Tomato GS, GOGAT and GDH may be involved in stress responsiveness, since most of these genes modified their expression levels under drought, cold or heat stress treatment. We believe these findings will assist in the exploration of the genes’ biological functions and regulatory mechanisms, as well as the studies to improve nitrogen use efficiency, stress resistance and fruit quality in tomato.     

Identification of drought-responsive microRNAs in tomato using high-throughput sequencing

Drought is a major abiotic stress affecting crop productivity and quality. As a class of noncoding RNA, microRNA (miRNA) plays important roles in plant growth, development, and stress response. However, their response and roles in tomato drought stress is largely unknown. Here, by using high-throughput sequencing, we compared the miRNA profiles before and after drought treatment in two tomato genotypes: M82, a drought-sensitive cultivated tomato (Solanum lycopersicum), and IL2-5, a drought-tolerant introgression line derived from M82 and the tomato wild species S. pennellii (LA0716). A total of 108 conserved and 208 novel miRNAs were identified, among them, 32 and 68 were significantly changed in expression after stress. Further, 1936 putative target genes were predicted for those differentially-expressed miRNAs. Gene ontology and pathway analysis showed that many of the target genes were involved in stress resistance, such as genes in GO terms including response to stress, defense response, response to stimulus, phosphorylation, and signal transduction. Our results suggested that miRNAs play an essential role in the drought response of tomato. This work will help to further characterize specific miRNAs functioning in drought tolerance.     

2-芳基-1,3-二氧环戊烷的合成与表征

以3-硝基-4-甲基苯甲酸为主要原料,依次通过乙硼烷还原、氯代反应将其中羧基转化为氯甲基,又经过缩争、氧化、醛基保护将甲基转化为缩醛等步骤合成了2-[2-硝基-(4-氯甲基)]苯基-1,3-二氧环戊烷.目标产物及某些重要中间体的结构已通过红外光谱、质谱、核磁共振氢谱的方法进行了表征.     

Systematic analysis and identification of regulators for SRS genes in Capsicum annuum

Plant Growth Regulation - Ethylene (ETH) is a gaseous plant growth regulator that affects grain yield and quality in rice (Oryza sativa L.). Little is known about whether and how ETH regulates...