水稻逆境响应基因OsMsr15的表达分析与克隆

应用Affymetrix水稻表达芯片,分析了苗期和孕穗期的培矮64S水稻基因在高温、干旱和低温逆境处理条件下的表达模式,发现多个与逆境反应相关基因.其中,OsMsr15(Oryza sativa L.multiple stresses responsivegene 15)受高温、干旱和低温胁迫诱导,表达水平均显著上调.实时定量PCR分析结果与芯片数据基本吻合.序列分析表明,该基因无内含子,ORF(open reading frame)全长为717 bp,编码一个由238个氨基酸残基组成、具有典型C2H2结构域的锌指蛋白,推测相对分子质量约为2.46 kD,pI值约为8.90,蛋白分子的氨基端和羧基端分别存在一个推测的核定位信号B-box和EAR(ERF-associated amphiphilic repression)基序.对OsMsr15可能的启动子区域进行分析,发现多种与逆境诱导相关的调控元件.该基因编码的蛋白在不同物种中存在高度相似性,显示OsMsr15基因可能作为一个保守的耐逆基因,参与植物的多种耐逆反应过程.     

Quantitative proteomic analysis of cabernet sauvignon grape cells exposed to thermal stresses reveals alterations in sugar and phenylpropanoid metabolism

Grapes (Vitis vinifera) are a valuable fruit crop and wine production is a major industry. Global warming and expanded range of cultivation will expose grapes to more temperature stresses in future. Our study investigated protein level responses to abiotic stresses, with particular reference to proteomic changes induced by the impact of four different temperature stress regimes, including both hot and cold temperatures, on cultured grape cells. Cabernet Sauvignon cell suspension cultures grown at 26°C were subjected to 14 h of exposure to 34 and 42°C for heat stress, and 18 and 10°C for cold stress. Cells from the five temperatures were harvested in biological triplicates and label‐free quantitative shotgun proteomic analysis was performed. A total of 2042 non‐redundant proteins were identified from the five temperature points. Fifty‐five proteins were only detected in extreme heat stress conditions (42°C) and 53 proteins were only detected at extreme cold stress conditions (10°C). Gene Ontology (GO) annotations of differentially expressed proteins provided insights into the metabolic pathways that are involved in temperature stress in grape cells. Sugar metabolism displayed switching between alternative and classical pathways during temperature stresses. Additionally, nine proteins involved in the phenylpropanoid pathway were greatly increased in abundance at extreme cold stress, and were thus found to be cold‐responsive proteins. All MS data have been deposited in the ProteomeXchange with identifier PXD000977 ( http://proteomecentral.proteomexchange.org/dataset/PXD000977 ).     

Differential metabolic response of cultured rice (Oryza sativa) cells exposed to high‐ and low‐temperature stress

Global mean temperatures are expected to rise by 2–4.5°C by 2100, accompanied by an increase in frequency and amplitude of extreme temperature events. Greater climatic extremes and an expanded range of cultivation will expose rice to increasing stress in the future. Understanding gene expression in disparate thermal regimes is important for the engineering of cultivars with tolerance to nonoptimal temperatures. Our study investigated the proteomic responses of rice cell suspension cultures to sudden temperature changes. Cell cultures grown at 28°C were subjected to 3‐day exposure to 12 or 20°C for low‐temperature stress, and 36 or 44°C for high‐temperature stress. Quantitative label‐free shotgun proteomic analysis was performed on biological triplicates of each treatment. Over 1900 proteins were expressed in one or more temperature treatments, and, of these, more than 850 were found to be responsive to either of the temperature extremes. These temperature‐responsive proteins included more than 300 proteins which were uniquely expressed at either 12 or 44°C. Our study also identified 40 novel stress–response proteins and observed that switching between the classical and the alternative pathways of sucrose metabolism occurs in response to extremes of temperature.     

The microRNA expression profile in porcine skeletal muscle is changed by constant heat stress

Heat stress has profound effects on animal performance and muscle function, and microRNAs (miRNAs) play a critical role in muscle development and stress responses. To characterize the changes in miRNAs in skeletal muscle responding to heat stress, the miRNA expression profiles of longissimus dorsi muscles of pigs raised under constant heat stress (30 °C; n = 8) or control temperature (22 °C; n = 8) for 21 days were analyzed by Illumina deep sequencing. A total of 58 differentially expressed miRNAs were identified with 30 down‐regulated and 28 up‐regulated, and 63 differentially expressed target genes were predicted by miRNA–mRNA joint analysis. GO and KEGG analyses showed that the genes regulated by differentially expressed miRNAs were enriched in glucose metabolism, cytoskeletal structure and function and stress response. Real‐time PCR showed that the mRNA levels of PDK4, HSP90 and DES were significantly increased, whereas those of SCD and LDHA significantly decreased by heat exposure. The protein levels of CALM1, DES and HIF1α were also significantly increased by constant heat. These results demonstrated that the change in miRNA expression in porcine longissimus dorsi muscle underlies the changes in muscle structure and metabolism in porcine skeletal muscle affected by constant heat stress.     

Proteome response of Escherichia coli fed-batch culture to temperature downshift

During fed-batch cultivation of Escherichia coli K-12, the proteomic response to a temperature downshift from 37 to 20°C was quantitatively monitored and analyzed by using two-dimensional electrophoresis. When the temperature of exponentially growing E. coli K-12 culture was downshifted to 20°C, the synthesis level of 57 intracellular proteins showed significant changes for a prolonged period of time, compared to the fed-batch culture controlled at 37°C. Thus, these proteins are regarded as important stress proteins responsive to cold shock, which were analyzed by using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and identified using the E. coli SWISS-2DPAGE database. Most of the identified proteins were shown to be involved in energy metabolism, several cellular molecule biosynthetic pathways and catabolism, cell processes, flagellar biosynthesis and motility, and protein translation and folding. The systematic approach to the monitoring of proteomic responses and the detailed analysis results reported in this article would be useful in understanding the metabolic adaptation to lowered culture temperature and designing efficient fermentation strategies for the production of recombinant proteins and metabolites using E. coli strains.     

Ethanol-response genes and their regulation analyzed by a microarray and comparative genomic approach in the nematode Caenorhabditis elegans

The nematode shows responses to acute ethanol exposure that are similar to those observed in humans, mice, and Drosophila, namely hyperactivity followed by uncoordination and sedation. We used in this report the nematode Caenorhabditis elegans as a model system to identify and characterize the genes that are affected by ethanol exposure and to link those genes functionally into an ethanol-induced gene network. By analyzing the expression profiles of all C. elegans ORFs using microarrays, we identified 230 genes affected by ethanol. While the ethanol response of some of the identified genes was significant at early time points, that of the majority was at late time points, indicating that the genes in the latter case might represent the physiological consequence of the ethanol exposure. We further characterized the early response genes that may represent those involved directly in the ethanol response. These genes included many heat shock protein genes, indicating that high concentration of ethanol acts as a strong stress to the animal. Interestingly, we identified two non-heat-shock protein genes that were specifically responsive to ethanol. glr-2 was the only glutamate receptor gene to be induced by ethanol. T28C12.4, which encodes a protein with limited homology to human neuroligin, was also specific to ethanol stress. Finally, by analyzing the promoter regions of the early response genes, we identified a regulatory element, TCTGCGTCTCT, that was necessary for the expression of subsets of ethanol response genes.     

Gene expression profiles during short‐term heat stress in the red sea coral Stylophora pistillata

During the past several decades, corals worldwide have been affected by severe bleaching events leading to wide‐spread coral mortality triggered by global warming. The symbiotic Red Sea coral Stylophora pistillata from the Gulf of Eilat is considered an opportunistic ‘r’ strategist. It can thrive in relatively unstable environments and is considered a stress‐tolerant species. Here, we used a S. pistillata custom microarray to examine gene expression patterns and cellular pathways during short‐term (13‐day) heat stress. The results allowed us to identify a two‐step reaction to heat stress, which intensified significantly as the temperature was raised to a 32 °C threshold, beyond which, coping strategies failed at 34 °C. We identified potential ‘early warning genes’ and ‘severe heat‐related genes’. Our findings suggest that during short‐term heat stress, S. pistillata may divert cellular energy into mechanisms such as the ER‐unfolded protein response (UPR) and ER‐associated degradation (ERAD) at the expense of growth and biomineralization processes in an effort to survive and subsequently recover from the stress. We suggest a mechanistic theory for the heat stress responses that may explain the success of some species which can thrive under a wider range of temperatures relative to others.     

Proteomics Reveals New Salt Responsive Proteins Associated with Rice Plasma Membrane

The signaling processes in plants that initiate cellular responses to biotic and abiotic factors are believed to be located in the plasma membrane (PM). A better understanding of the PM proteome response to environmental stresses might lead to new strategies for improving stress-tolerant crops. A sub-cellular proteomics approach was applied to monitor changes in abundance of PM-associated protein in response to salinity, a key abiotic stress affecting rice productivity worldwide. Proteome was extracted from a root plasma-membrane-rich fraction of a rice salt tolerant variety, IR651, grown under saline and normal conditions. Comparative two-dimensional electrophoresis revealed that 24 proteins were differentially expressed in response to salt stress. From these, eight proteins were identified by mass spectrometry analysis. Most of the proteins identified are likely to be PM-associated and are known to be involved in several important mechanisms of plant adaptation to salt stress. These include regulation of PM pumps and channels, membrane structure, oxidative stress defense, signal transduction, protein folding, and the methyl cycle. To investigate the correlation between mRNA and protein level in response to salinity, we performed quantitative Real-Time PCR analysis of three genes that were salt responsive at the protein level, including 1,4-Benzoquinone reductase, a putative remorin and a hypersensitive induced response protein. No concordance was detected between the changes in levels of gene and protein expression. Our results indicate that the proteomics approach is suitable for expression analysis of membrane associated proteins under salt stress.     

Proteomics reveals new salt responsive proteins associated with rice plasma membrane

The signaling processes in plants that initiate cellular responses to biotic and abiotic factors are believed to be located in the plasma membrane (PM). A better understanding of the PM proteome response to environmental stresses might lead to new strategies for improving stress-tolerant crops. A sub-cellular proteomics approach was applied to monitor changes in abundance of PM-associated protein in response to salinity, a key abiotic stress affecting rice productivity worldwide. Proteome was extracted from a root plasma-membrane-rich fraction of a rice salt tolerant variety, IR651, grown under saline and normal conditions. Comparative two-dimensional electrophoresis revealed that 24 proteins were differentially expressed in response to salt stress. From these, eight proteins were identified by mass spectrometry analysis. Most of the proteins identified are likely to be PM-associated and are known to be involved in several important mechanisms of plant adaptation to salt stress. These include regulation of PM pumps and channels, membrane structure, oxidative stress defense, signal transduction, protein folding, and the methyl cycle. To investigate the correlation between mRNA and protein level in response to salinity, we performed quantitative Real-Time PCR analysis of three genes that were salt responsive at the protein level, including 1,4-Benzoquinone reductase, a putative remorin and a hypersensitive induced response protein. No concordance was detected between the changes in levels of gene and protein expression. Our results indicate that the proteomics approach is suitable for expression analysis of membrane associated proteins under salt stress.     

一个水稻多逆境响应基因OsMsr3克隆与表达分析

为深入探讨水稻对逆境的反应机理并寻找新的植物耐逆基因,采用Affymetrix水稻表达芯片(含51279个转录本)分析了培矮64S全基因组在不同逆境(高温、干旱、低温)胁迫下、不同生育时期叶片和穗中的表达谱,从中筛选出一个受多种逆境诱导表达的基因OsMsr3(Oryza sativa L.multiple stresses responsive gene3,GenBank登陆号为 FJ383169).定量实时PCR分析结果进一步证实了此基因在逆境条件下的诱导表达模式.用 RT-PCR方法扩增获得了包含其完整开放阅读框的cDNA克隆,序列分析表明,其ORF大小为480 bp,编码一个具有160个氨基酸残基的低分子量热激蛋白,推测分子量约为18.0 kD;pI约为6.8.对其编码的蛋白质进行分析,发现其羧基端存在一个HSP20的蛋白保守结构域,与其他植物中的低分子量热激蛋白的相似性介于33.7%～97.5%.对其可能的启动子序列分析,发现6类与逆境反应有关的顺式作用元件.推测该基因在逆境反应中起着重要的作用,进一步的研究正在进行中.