拟南芥AtJ50基因表达特性的研究

以拟南芥野生型和AtJ50∷GUS转基因株系为材料,通过半定量RT-PCR和GUS组织化学染色法探索AtJ50基因的时空表达特性.结果表明:(1)AtJ50基因在根、茎、叶、花和果实中都有表达,花和叶中表达最高,茎和根中次之,成熟的长角果中几乎没有表达;随着植株的成熟和衰老,AtJ50基因的表达量逐渐下降.(2)半定量RT-PCR法分析结果表明,AtJ50基因表达受0.2 mol·L-1的NaCl诱导,随着NaCl处理时间的延长表达量增加,12 h后表达量达到最高,24 h后又有所下降;水分胁迫也可诱导AtJ50基因的表达,水分胁迫0.5 h后AtJ50基因表达量开始增加,1 h后达到最高,2 h后又开始下降.     

AtsHsp17.6-CⅠ和AtsHsp17.6-CⅡ基因对非生物胁迫的应答研究

小分子热激蛋白是植物受到热胁迫后的主要表达产物之一,与植物细胞耐热有密切关系。该研究发现,拟南芥小分子热激蛋白基因AtsHsp17.6-CⅠ和AtsHsp17.6-CⅡ 除热激之外,重金属离子Ni⁺、Pb²⁺、Cu²⁺、Zn²⁺和Al³⁺均能诱导这2个热激蛋白基因的表达;氧化胁迫和渗透胁迫同样也能诱导它们表达。该研究将由CaMV35S启动子驱动的这2个小分子热激蛋白基因导入拟南芥,RT-PCR分析表明,2个小分子热激蛋白基因在转基因植物中呈现组成型表达。实验结果表明,组成型表达小分子热激蛋白基因AtsHsp17.6-CⅠ的转基因植物表现出对6 μmol·L^-1 Cd²⁺胁迫、0.4% NaCl胁迫的耐受性。研究表明,这2个小分子热激蛋白基因可能参与着多种抗逆途径,推测其能够减轻或抵抗逆境胁迫引起的伤害并对其进行修复。     

拟南芥AtJ3通过核质转运调控植物质膜H~+-ATPase活性与ABA响应

拟南芥AtJ3(Arabidopsis thaliana Dna J homolog 3)为一蛋白分子伴侣,在植物体内可通过与PKS5(SOS2-like protein kinase 5)蛋白激酶形成复合物来抑制PKS5的活性;同时AtJ3-PKS5复合物可对质膜上H~+-ATPase质子转运活性进行正向调节,并参与对外源ABA的响应。为揭示AtJ3-PKS5复合物参与质膜H~+-ATPase活性调节及对外源ABA响应中的作用,本研究以拟南芥AtJ3、PKS5不同突变体为材料,在盐及ABA共同处理下对AtJ3-PKS5复合物的功能及作用机制进行了探讨。结果显示,在2种因素共同处理下,AtJ3-PKS5复合物可同时对处理因素进行响应。即AtJ3-PKS5复合物可对质膜上H~+-ATPase质子转运活性进行调节,并使细胞内p H值发生变化,同时还可诱导ABI5下游ABA响应基因的表达;外源ABA可引起AtJ3从细胞核向细胞质的转运,从而增强了AtJ3对H~+-ATPase活性的调节。说明AtJ3-PKS5复合物在对H~+-ATPase活性调节及对外源ABA响应的交互代谢途径中起着关键调节子的作用。     

马铃薯StSnRK2家族转录表达对渗透胁迫的响应及生理指标相关性分析

蔗糖非酵解相关蛋白激酶家族2(Sucrose Non-Fermenting Related protein Kinases 2,Sn RK2)是一类植物中高度保守的蛋白激酶,也是植物响应干旱、盐碱等导致渗透性胁迫的主要调控原件。本研究以马铃薯品种‘陇薯3号’为材料,观察试管苗在0、25、50、100、200 mmol/L Na Cl 2周、4周和6周盐胁迫下和0、2%、4%、6%、8%PEG 2周、4周和6周干旱胁迫下马铃薯地上部分组织中StSnRK2基因的表达模式。结果显示,盐和干旱胁迫下马铃薯StSnRK2基因表达模式不尽相同:在盐胁迫下StSnRK2.4和StSnRK2.6表达均上调;干旱胁迫下StSnRK2.3的表达量上升,而且随PEG浓度的增加StSnRK2.3表达量也随之增高;同一基因在不同胁迫处理下表达趋势也有差异,StSnRK2.5基因在盐胁迫下表达下调,在干旱胁迫下StSnRK2.5基因表达量高于对照;不同胁迫处理下基因的表达与生理指标的相关性也不同,盐胁迫下,StSnRK2.6基因与CAT和SOD活性呈极显著正相关,与气孔面积呈显著负相关,干旱胁迫下,StSnRK2.6基因的表达量与脯氨酸含量呈显著正相关。本文通过研究不同渗透胁迫条件下StSnRK2基因的表达模式,进一步解析了马铃薯对盐及干旱胁迫响应的机理,可为马铃薯抗逆品种的选育提供依据。     

拟南芥DTX31基因表达研究

以模式植物拟南芥为材料,通过PCR和RT-PCR在DNA和RNA水平上筛选鉴定了DTX31基因对应的T-DNA插入突变体,对其表型变化进行了观察.通过半定量RT-PCR分析检测了DTX31基因在拟南芥不同器官及环境胁迫响应中的表达情况,结果发现:DTX31基因在根中表达最高,而在茎、叶、叶柄、花中的表达则较弱;盐和赤霉素使DTX31基因的表达迅速升高,盐胁迫2 h后的表达量达到最高峰,GA处理1 h时就达到最高峰,热激使DTX31基因的表达变化不明显.因此,推测该基因可能是盐和GA信号传导通路中的一个重要调控因子.     

盐芥热激同源蛋白70基因(Thhsc70)的分子克隆及鉴定

热激蛋白70(hsp70s)具有分子伴侣的功能,其中在非胁迫条件下表达的hsp70s称为热激同源蛋白70(hsc70).为更好地了解hsc70基因的特性,鉴定了盐芥(Thellungiella halophila(C.A.Mey.)O.E. Schulz)中编码胞质hsc70蛋白的基因Thhsc70.实验结果表明:在非胁迫条件下,Thhsc70基因具有组织特异性表达;Thhsc70基因受热胁迫和冷胁迫的诱导表达,但几乎不受盐诱导和干旱诱导.Thhsc70基因在拟南芥中过量表达后提高了转基因拟南芥的热耐受性和冷耐受性.     

盐芥热激同源蛋白70基因(Thhsc70)的分子克隆及鉴定(英文)

热激蛋白70(hsp70s)具有分子伴侣的功能,其中在非胁迫条件下表达的hsp70s称为热激同源蛋白70(hsc70)。为更好地了解hsc70基因的特性,鉴定了盐芥(Thellungiella halophila(C. A. Mey. )O. E. Schulz)中编码胞质hsc70蛋白的基因Thhsc70。实验结果表明:在非胁迫条件下,Thhsc70基因具有组织特异性表达;Thhsc70基因受热胁迫和冷胁迫的诱导表达,但几乎不受盐诱导和干旱诱导。Thhsc70基因在拟南芥中过量表达后提高了转基因拟南芥的热耐受性和冷耐受性。     

水曲柳中MYBL2基因表达特征分析

MYB转录因子家族是植物中最大的转录因子家族之一,参与植物生长、繁殖和代谢的各个时期,能通过多种方式参与植物抗逆生长。该文在水曲柳中克隆FmMYBL2基因,利用生物信息学分析其结构和表达特征,并构建FmMYBL2蛋白的系统进化树。对水曲柳幼苗进行低温胁迫、盐胁迫处理以及激素分子诱导处理(包括ABA、IAA、GA_3、JA、SA)。分别在0、1、3、6、12、24、48 h取样,利用实时荧光定量PCR对上述处理样品中FmMYBL2基因进行定量分析,并分析了FmMYBL2的时空表达特征。结果表明:(1)克隆得到的FmMYBL2基因全长为762 bp,编码253个氨基酸。(2) FmMYBL2蛋白是亲水性蛋白,氨基酸序列比对表明其与棉花同源关系较近。(3)荧光定量分析表明,FmMYBL2基因响应低温胁迫和盐胁迫,同时ABA、IAA、GA_3、JA、SA共同调控该基因表达。(4)在低温处理1 h、盐胁迫48 h时,虽然FmMYBL2基因表达量最高,激素诱导后表达量持续波动,但其能在短时间内迅速响应。(5) FmMYBL2基因在根、芽、花、种子中均有表达,雄花中的表达量最高。该研究结果为深入研究MYBL2基因功能和水曲柳抗逆生长的调控奠定基础。     

Differential expression of two HSP70 transcripts in response to cold shock,thermoperiod, and adult diapause in the Colorado potato beetle

Partial clones for two members of Leptinotarsa decemlineata inducible 70kDa heat shock protein family (LdHSP70A and B) were developed using RT-PCR. LdHSP70A, but not LdHSP70B, was upregulated during adult diapause. The ability of L. decemlineata to express these two genes in response to subzero temperatures depended on the thermal history of the beetles. Chilling diapausing beetles increased the rate at which both LdHSP70A and B were expressed following a cold shock at -10 degrees C. Following cold shock at -10 degrees C, LdHSP70B expression peaked after 3h at 15 degrees C for chilled diapausing individuals, decreasing to near background levels by the sixth hour. In contrast, nonchilled diapausing beetles expressed their highest level of LdHSP70B only after 6h at 15 degrees C. Diapausing beetles exposed to a thermoperiod with a mean temperature of either 0 or -2.5 degrees C expressed significantly higher levels of both LdHSP70A and B than beetles exposed to constant 0 or -2.5 degrees C. These results demonstrate that the expression of LdHSP70A and B is differentially regulated in response to diapause and environmental conditioning.     

The endosymbiotic bacterium Holospora obtusa enhances heat-shock gene expression of the host Paramecium caudatum

The bacterium Holospora obtusa is a macronuclear-specific symbiont of the ciliate Paramecium caudatum. H. obtusa-bearing paramecia could survive even after the cells were quickly heated from 25 degrees C to 35 degrees C. To determine whether infection with H. obtusa confers heat shock resistance on its host, we isolated genes homologous to the heat shock protein genes hsp60 and hsp70 from P. caudatum. The deduced amino acid sequences of both cDNAs were highly homologous to hsp family sequences from other eukaryotes. Competitive PCR showed that H. obtusa-free paramecia expressed only trace amounts of hsp60 and hsp70 mRNA at 25 degrees C, but that expression of hsp70 was enhanced immediately after the cells were transferred to 35 degrees C. H. obtusa-bearing paramecia expressed high levels of hsp7O mRNA even at 25 degrees C and the level was further enhanced when the cells were incubated at 35 degrees C. In contrast, the expression pattern of hsp60 mRNA was the same in H. obtusa-bearing as in H. obtusa-free paramecia. These results indicate that infection with its endosymbiont can confer a heat-shock resistant nature on its host cells.     

Heat-stress-dependency and developmental modulation of gene expression: the potential of house-keeping genes as internal standards in mRNA expression profiling using real-time RT-PCR

The potential of different house-keeping genes for their use as internal standards of gene expression under changing environmental conditions and in different organs of plants was assessed. Using real-time PCR mRNA levels were precisely quantified for preselected actin and ribosomal protein genes in Arabidopsis thaliana (L.) Heinh. and Nicotiana tabacum L. grown at normal temperature and following heat stress. In tobacco leaves the mRNA levels of the constitutively expressed ribosomal protein gene Nt-L25 and the actin genes Nt-ACT9 and At-ACT66 were strongly reduced (to approximately 10%) during heat stress. Heat stress applied at the temperature optimum (37 degrees C) for elicitation of a heat stress response to Arabidopsis leaves resulted in a strong induction (several thousand-fold) of the mRNA heat shock protein genes, At-HSP17.6 and At-HSP18.2. Concomitantly, the mRNA levels of constitutively expressed actin 2 (At-ACT2) and ribosomal protein L23 (At-L23a) genes were reduced to approximately 50% of the levels in leaves incubated at room temperature. Conversely, under severe heat stress conditions (44 degrees C), the induction of At-HSP17.6 and At-HSP18.2 mRNAs was insignificant, the mRNA levels of At-ACT2 remained at approximately the same levels as in leaves incubated at room temperature, whereas the mRNA level of At-L23 declined. The mRNA levels of At-ACT2 and At-L23a examined in stem, flower and siliques of Arabidopsis plants grown under non-stress condition showed differential alterations; the mRNA level of ribosomal protein L23 correlates with the metabolic activity of tissues. The potential use of house-keeping gene expression as standards in expression profiling and the mechanisms modulating the mRNA levels are discussed.     

Role of the antioxidant system in response of Escherichia coli bacteria to cold stress

The response of aerobically grown Escherichia coli cells to the cold shock induced by the rapid lowering of growth temperature from 37 to 20 degrees C was found to be basically the same as the oxidative stress response. The enhanced sensitivity of cells deficient in two superoxide dismutases, Mn-SOD and Fe-SOD, and the increased expression of the Mn-SOD gene, sodA, in response to cold stress were interpreted as both oxidative and cold stresses are due to a rise in the intracellular level of superoxide anion. The long-term cultivation of E. coli at 20 degrees C was also accompanied by the typical oxidative stress response reactions--an enhanced expression of the Mn-SOD and catalase HPI genes and a decrease in the intracellular level of reduced glutathione (GSH) and in the GSH/GSSG ratio.     

Gene expression analysis of cold and freeze stress in Baker's yeast

We used mRNA differential display to assess yeast gene expression under cold or freeze shock stress conditions. We found both up- and down-regulation of genes, although repression was more common. We identified and sequenced several cold-induced genes exhibiting the largest differences. We confirmed, by Northern blotting, the specificity of the response for TPI1, which encodes triose-phosphate isomerase; ERG10, the gene for acetoacetyl coenzyme A thiolase; and IMH1, which encodes a protein implicated in protein transport. These genes also were induced under other stress conditions, suggesting that this cold response is mediated by a general stress mechanism. We determined the physiological significance of the cold-induced expression change of these genes in two baker's yeast strains with different sensitivities to freeze stress. The mRNA level of TPI1 and ERG10 genes was higher in freeze-stressed than in control samples of the tolerant strain. In contrast, both genes were repressed in frozen cells of the sensitive strain. Next, we examined the effects of ERG10 overexpression on cold and freeze-thaw tolerance. Growth of wild-type cells at 10 degrees C was not affected by high ERG10 expression. However, YEpERG10 transformant cells exhibited increased freezing tolerance. Consistent with this, cells of an erg10 mutant strain showed a clear phenotype of cold and freeze sensitivity. These results give support to the idea that a cause-and-effect relationship between differentially expressed genes and cryoresistance exists in Saccharomyces cerevisiae and open up the possibility of design strategies to improve the freeze tolerance of baker's yeast.     

Differential expression of two types of sucrose synthase-encoding genes in wheat in response to anaerobiosis, cold shock and light

The expression of two types of sucrose synthase-encoding genes, Ss1 and Ss2, in hexaploid wheat (Triticum aestivum, L.), has been investigated using type-specific probes, corresponding to the 250-270 bp C-terminal portions of the respective cDNA clones. Both types of genes are highly expressed in developing endosperm, where the expression of the Ss2 type slightly precedes in time that of the Ss1 type. Expression of Ss genes is lower in etiolated leaves and in roots than in endosperm. In the first two tissues, the Ss1 mRNA is much more abundant than the Ss2 mRNA, and the Ss1 mRNA level sharply increases in response to anaerobiosis and to cold shock (6 degrees C), while the level of Ss2 mRNA is not significantly affected. Upon illumination of etiolated leaves, the Ss1 level mRNA decreases significantly and the Ss2 mRNA level increases.     

The eukaryote chaperonin CCT is a cold shock protein in Saccharomyces cerevisiae

The eukaryotic Hsp60 cytoplasmic chaperonin CCT (chaperonin containing the T-complex polypeptide-1) is essential for growth in budding yeast, and mutations in individual CCT subunits have been shown to affect assembly of tubulin and actin. The present research focused mainly on the expression of the CCT subunits, CCTalpha and CCTbeta, in yeast (Saccharomyces cerevisiae). Previous studies showed that, unlike most other chaperones, CCT in yeast does not undergo induction following heat shock. In this study, messenger ribonucleic acid (mRNA) and protein levels of CCT subunits following exposure to low temperatures, were examined. The Northern blot analysis indicated a 3- to 4-fold increase in mRNA levels of CCTalpha and CCTbeta genes after cold shock at 4 degrees C. Interestingly, Western blot analysis showed that cold shock induces an increase in the CCTalpha protein, which is expressed at 10 degrees C, but not at 4 degrees C. Transfer of 4 degrees C cold-shocked cells to 10 degrees C induced a 5-fold increase in the CCTalpha protein level. By means of fluorescent immunostaining and confocal microscopy, we found CCTalpha to be localized in the cortex and the cell cytoplasm of S. cerevisiae. Localization of CCTalpha was not affected at low temperatures. Co-localization of CCT and filaments of actin and tubulin was not observed by microscopy. The induction pattern of the CCTalpha protein suggests that expression of the chaperonin may be primarily important during the recovery from low temperatures and the transition to growth at higher temperatures, as found for other Hsps during the recovery phase from heat shock.