Landry J, Chrétien P, Laszlo A, Lambert H
Centre de recherche en cancérologie Université Laval, Hôtel-Dieu de Québec, Canada.
J Cell Physiol. 1991 Apr;147(1):93-101. doi: 10.1002/jcp.1041470113.
The small molecular weight heat shock protein HSP27 was recently shown to confer a stable thermoresistant phenotype when expressed constitutively in mammalian cells after structural gene transfection. These results suggested that HSP27 may also play an important role in the development of thermotolerance, the transient ability to survive otherwise lethal heat exposure after a mild heat shock. In Chinese hamster O23 cells increased thermoresistance is first detected at 2 h after a triggering treatment of 20 min at 44 degrees C, attains a maximum at 5 hours, and decays thereafter with a half-life of 10 h. We found that the development and decay of transient thermotolerance cannot be solely explained on the basis of changes in the cellular concentration of HSP27. The cellular HSP27 concentration is not increased appreciably at 2 h after heat shock and attains a maximum at 14 h. Similar results were obtained in the case of another heat shock protein, HSP70. HSP70 follows slightly faster kinetics of accumulation (peaks at 10 h) and decays much more rapidly (ti/2 = 4h) than HSP27 (t1/2 = 13h). HSP27 has 3 isoelectric variants A, B, and C of which B and C are phosphorylated. In cells maintained at normal temperature, HSP27A represents more than 90% of all HSP27. Shifting the cell culture temperature from 37 to 44 degrees C induces the incorporation of 32P into the more acidic B and C forms, a process that occurs very rapidly since the reduction in the concentration of the A form and a corresponding increase in the level of B and C is detectable by immunoblot analysis within 2.5 min at 44 degrees C. Analyses performed at various times during development and decay of transient thermotolerance revealed a close relationship between the effect of heat shock on HSP27 phosphorylation and cell ability to survive. For example, fully thermotolerant cells (5 h post-induction) are refractory to induction of HSP27 phosphorylation by a 20-min heat shock. The induction of HSP27 phosphorylation was also studied in a family of clonal cell lines of O23 cells that are thermoresistant as a result of the constitutive expression of a transfected human HSP27 gene. In these thermoresistant cells, phosphorylation of the endogenous hamster HSP27 is induced to a level comparable to that found in the thermosensitive parental cells. However, phosphorylation of the exogenous human protein, which represents more than 80% of total HSP27 in these cells, was much less induced.(ABSTRACT TRUNCATED AT 250 WORDS)
最近研究表明,小分子量热休克蛋白HSP27在结构基因转染后于哺乳动物细胞中组成性表达时,可赋予稳定的耐热表型。这些结果提示,HSP27在热耐受(轻度热休克后对致死性热暴露的短暂存活能力)的形成中可能也发挥重要作用。在中国仓鼠O23细胞中,在44℃触发处理20分钟后2小时首次检测到耐热性增加,5小时达到最大值,此后以10小时的半衰期衰减。我们发现,短暂热耐受的形成和衰减不能仅基于细胞中HSP27浓度的变化来解释。热休克后2小时细胞内HSP27浓度没有明显增加,14小时达到最大值。在另一种热休克蛋白HSP70的情况中也得到了类似结果。HSP70的积累动力学稍快(10小时达到峰值),且比HSP27(半衰期 = 13小时)衰减得更快(半衰期 = 4小时)。HSP27有3种等电变体A、B和C,其中B和C是磷酸化的。在正常温度下培养的细胞中,HSP27A占所有HSP27的90%以上。将细胞培养温度从37℃升至44℃会诱导32P掺入酸性更强的B和C形式中,这一过程非常迅速,因为在44℃下2.5分钟内通过免疫印迹分析就可检测到A形式浓度降低以及B和C水平相应升高。在短暂热耐受形成和衰减的不同时间进行的分析显示,热休克对HSP27磷酸化的影响与细胞存活能力之间存在密切关系。例如,完全耐热的细胞(诱导后5小时)对20分钟热休克诱导的HSP27磷酸化不敏感。还在一组O23细胞克隆系中研究了HSP27磷酸化的诱导情况,这些细胞由于转染的人HSP27基因的组成性表达而具有耐热性。在这些耐热细胞中,内源性仓鼠HSP27的磷酸化被诱导至与热敏亲本细胞中相当的水平。然而,外源性人蛋白(在这些细胞中占总HSP27的80%以上)的磷酸化诱导程度要低得多。(摘要截短于250词)
