热休克蛋白的生物学作用和转录水平调控研究进展

热休克蛋白（HSP）具有广泛的生物学功能,其表达方式有两种：一种是诱导性表达,即当生物细胞受到刺激时才进行表达,另一种是组成性表达,即在生物,细胞的正常生活,代谢过程中表达。HSP的这两种表达式意味着HSP基因表达的调控方式和机理不同。本文简要介绍了热休克因子（HSF）的种类,结构及调控HSP基因表达的机理,HSF通过以下4个步骤调节HSP基因：（1）HSF由单体形式变成磷酸化的三聚体形式被激活;（2）三聚体形成式的HSF与HSP基因的热休克元件（HSE）上相邻排列的3个5′－GAA－3′结合,（3）与HSF结合后,HSE的活化域暴露,HSP基因转录;（4）HSP的mRNA5′端前导芪的特异结构适合于核糖体快速结合和高效翻译,不同生物体内的HSF作用有一定差异,功能较为明确的有：（1）对应激信号敏感的HSF1;（2）对应激信号不敏感,对生长,发育,分化信号敏感的HSF2;（3）起抑制HSP基因转录作用的HSF4。还有一些HSF（如HSF3）的作用机制较复杂,有待深入研究。此外,本文也简单介绍了HSP在衰老,免疫应答,细胞生存和凋亡平衡等中的作用,对了解和认识生物生长,发育,衰老,保护,免疫应答及细胞生存和凋亡平衡的分子机制有一定帮助。     

水稻热休克转录因子OsHSF13的克隆与生物信息学的初步分析(简报)

环境刺激的信号转导是植物信号转导的一个重要研究方向。热激反应(heat-shockresponse,HSR)是动植物细胞或器官在遇到外界热刺激时所产生的一种保护性反应,是正常的蛋白质合成受阻时产生热激蛋白(heat-shockprotein,HSP)的一种细胞生理活动,其表达通过热休克转录因子(heat-shock factor,HSF)来进行调控[1]。编码热激蛋白基因的启动子区域存在着一段保守的DNA序列,是热休克转录因子的结合位点(heat-shockelement,HSE)。当植物受到外界的热刺激时,HSF可以与HSE特异性结合,激活热激蛋白基因的表达,     

热休克因子1活性的调控机制

热休克因子1(HSF1)是调控热休克蛋白(HSPs)表达的核心转录因子,可被热应激、氧化应激、缺氧/血、pH下降等刺激因素激活,与靶基因的热休克元件特异性结合,增强HSPs表达,发挥内源性保护作用.HSF1活性的调控发生在HSF1三聚化、转位入核、结合DNA和调节转录等多个环节,受到分子伴侣蛋白、磷酸化作用、氧化-还原等机制共同调控,其复杂而精确的调控对于应激应答、生长发育等过程有重要意义.     

热休克因子1对内毒素所致G-CSF基因表达的影响

为探讨热休克因子1(heatshockfactor 1,HSF1)活化和过表达对内毒素(endotoxin ,ET)所致粒细胞集落刺激因子(granulocyte colonystimulatingfactor,G CSF)基因表达的影响,采用大肠杆菌内毒素即脂多糖(lipopolysaccharide ,LPS)处理RAW2 6 4 7巨噬细胞,并通过热休克预处理诱导HSF1活化,采用Western印迹检测HSP70的表达观察HSF1的活化情况,RT PCR检测热休克反应(heatshockresponse ,HSR)对G CSFmRNA表达的影响;构建HSF1的pcDNA3 1真核表达质粒,采用脂质体转染法建立HSF1过表达RAW 2 6 4 7巨噬细胞株,用免疫细胞化学和Western印迹观察HSF1的表达,RT- PCR及Northern印迹进一步研究HSF1对G CSF基因表达的可能影响.发现LPS诱导巨噬细胞中G- CSFmRNA表达增多,并随时间的延长,表达量逐渐增加;与单纯内毒素处理组相比,热休克预处理后,LPS诱导的巨噬细胞G- CSFmRNA的表达明显被抑制;建立的稳定表达HSF1的RAW 2 6 4 7细胞株中有HSF1蛋白的核移位;HSF1过表达可明显抑制LPS诱导的RAW2 6 4 7巨噬细胞G -CSFmRNA的表达.上述结果表明热休克预处理能抑制LPS诱导的巨噬细胞G- CSFmRNA的表达;HSF1过表达可抑制内毒素诱导的巨噬细胞G CSFmRNA的表达.     

植物热激因子网络

在热或其他刺激条件下,热激因子(heat shock factor,HSF)与热激元件(heat shock element,HSE)结合从而启动表达热激蛋白.与其他生物相比,植物中HSF更具有多样性和复杂性.本文从植物HSF的结构域、多样性、相互作用及专一性等四个方面介绍了植物HSF网络的复杂性.     

热休克转录因子1与机体耐热性的相关研究

热休克转录因子1(HSF1)能够启动各种热休克蛋白基因的诱导表达,这对防止机体免受热应激损伤具有重要的意义。从HSF1的结构、功能及活化过程等几个方面阐述了HSF1的生理特征及其与机体耐热性能之间的关系。     

Thermotolerance induced by heat shock in Chlorella

Thermotolerance in cultures of Chlorella zofingiensis was induced by heat shock treatment at supraoptimal temperatures (40and 45 °C for 30 min). Thermotolerance was assayed by two methods: the survival of the cells at 70 °C and the growth of diluted cultures at 35 and 45 °C. A culture without heat shock treatment was unable to grow at 45 °C. According to eletrophoretic analyses, the synthesis of proteins of 95, 73, 60, 43 and 27 kDa was induced by heat shock treatment. The large molecular weight proteins (95, 73, 60 and43 kDa) were present in non-heat treated cells, but the heat shock treatment increased their quantity in cells. The synthesis of a low molecular weight protein (27 kDa) was induced by heat shock treatment. The induced thermotolerance could be inhibited by the presence of an 80S ribosomal translation inhibitor, cycloheximide(CHI). The first 12 amino acid residues from the N-terminus of the27 kDa heat shock induced protein are Val-Glu-Trp-Try-Gly-Pro-Asn-Arg-Ala-Lys-Phe-Leu. This revised version was published online in August 2006 with corrections to the Cover Date.     

昆虫的热休克反应和热休克蛋白

热休克（热激heatshock）是指短暂、迅速地向高温转换所诱导出的一种固定的应激反应。诱导该反应的温度在种与种之间有所不同。热休克反应最明显的特征是：伴随着正常蛋白质合成的抑制,一部分特殊蛋白质的诱导和表达增加,即为热休克蛋白（heatshockproteins,HSPs）。尽管热休克蛋白的合成也能被其它形式的应激反应所诱导,将它们认为是应激蛋白可能更恰当,但人们习惯上仍将这类蛋白质称为热休克蛋白。由于热休克反应和热休克蛋白是在果蝇（Drosophiliamelanogaster）中最初发现的,故在昆虫中,特别是果蝇等双翅目昆虫中研究得较深入…     

葡萄糖调节蛋白75的研究进展

葡萄糖调节蛋白75(Grp75)是高度保守的热激蛋白家族中的一员,在细胞内主要行使伴侣蛋白的功能,帮助未折叠或错误折叠蛋白质进行正确的折叠,还与细胞内多个因子结合,参与细胞内多个重要的生物学过程。现就Grp75的基因定位、蛋白质分布和功能以及临床研究展开本综述。     

Cloning of heat shock protein genes from the brown planthopper,Nilaparvata lugens,and the small brown planthopper,Laodelphax striatellus,and their expression in relation to thermal stress

Three heat shock protein （HSP） genes （hsp70, hsc70, hsp90） were partially cloned from the brown planthopper Nilaparvata lugens and the small brown planthopper Laodelphax striatellus （Homoptera： Delphacidae）, which are serious pests of the rice plant. Sequence comparisons at the deduced amino acid level showed that the three HSPs of planthoppers were most homologous to corresponding HSPs of dipteran and lepidopteran species. Identities of both heat shock cognate 70 and HSP90 were higher than HSP70 in both species. Identity of the HSP70 between the two planthopper species was only 81%, a value much lower than seen among fly and moth groups. Effects of heat and cold shocks were demonstrated on expression of the three hsp genes in the two planthopper species. Heat shock （40 ℃） upregulated the hsp90 level but did not change the hsc70 level in either the nymph and adult stages of either species. On the other hand, the hsp70 level was only upregulated in L. striatellus. This heat shock response was prompt and lasted only for 1 h after treatment. In contrast, cold shock at 4℃ did not change the expression levels of any hsp in either species.     

A heat shock protein 90 inhibitor that modulates the immunophilins and regulates hormone receptors without inducing the heat shock response

When a cell encounters external stressors, such as lack of nutrients, elevated temperatures, changes in pH or other stressful environments, a key set of evolutionarily conserved proteins, the heat shock proteins (hsps), become overexpressed. Hsps are classified into six major families with the hsp90 family being the best understood; an increase in cell stress leads to increased levels of hsp90, which leads to cellular protection. A hallmark of hsp90 inhibitors is that they induce a cell rescue mechanism, the heat shock response. We define the unique molecular profile of a compound (SM145) that regulates hormone receptor protein levels through hsp90 inhibition without inducing the heat shock response. Modulation of the binding event between heat shock protein 90 and the immunophilins/homologs using SM145, leads to a decrease in hormone receptor protein levels. Unlike N-terminal hsp90 inhibitors, this hsp90 inhibitor does not induce a heat shock response. This work is proof of principle that controlling hormone receptor expression can occur by inhibiting hsp90 without inducing pro-survival protein heat shock protein 70 (hsp70) or other proteins associated with the heat shock response. Innovatively, we show that blocking the heat shock response, in addition to hsp90, is key to regulating hsp90-associated pathways.     

玉米胚发育过程中热激蛋白的合成

35S-Met标记玉米胚蛋白合成结果表明,热激处理(42℃)与对照(25℃)的蛋白合成趋势相近,热激抑制16 DAP的蛋白合成,增加22和34 DAP蛋白合成.SDS-PAGE自显影图谱表明,热激诱导16DAP的胚合成86.4、80.0、73.2 kD等3种分子量较高的热激蛋白,22DAP后热激诱导合成86.4、80.0、73.2、24.4、18.2、16.8和13.6 kD等7种分子量的热激蛋白.2D-PAGE自显影图谱进一步显示,热激诱导22和28 DAP的胚合成近20种热激蛋白,其中超过10种为小分子热激蛋白.特异热激蛋白BiP(HsP70)、PDI(HsP60)Western blot表明,这2种热激蛋白在玉米胚发育过程均有高水平的表达,热激对其合成影响不明显.     

抗阿维菌素朱砂叶螨的热激反应及热激蛋白

选用朱砂叶螨Tetranychus cinnabarinus阿维菌素抗性品系和敏感品系,测定了热预刺激后其在极限高温下的存活率,并应用SDS-PAGE技术研究了热激蛋白(HSPs)的种类及其含量。结果表明：非致死的热预刺激能显著提高朱砂叶螨耐极限温度的能力。两个品系在不同温度热激处理后,其蛋白质种类和含量发生了变化。正常情况下,朱砂叶螨敏感品系与阿维菌素抗性品系相比缺失8条条带;敏感品系热激后,增加了分子量分别为97.2,74.3,62.4,53.0和30.3 kDa的5条条带; 抗性品系热激后没有特异蛋白带的产生,但进一步高温胁迫后有些蛋白表达增强。此结果有助于解释朱砂叶螨抗性品系存在高温适合度优势现象。