热休克因子生理功能研究进展

热休克因子是调控真核细胞热休克基因转录的关键因子,在应激和正常生理条件下发挥重要作用,使其成为近年来的研究热点。该文简要综述热休克因子在抗炎反应、肿瘤发生与维持、生长发育、衰老等生理病理过程中的重要生理功能。     

Expression levels of heat shock factors are not functionally coupled to the rate of expression of heat shock genes

The expression patterns of two mammalian heat shock factors (HSFs) were analysed in cell systems known to reflect an altered heat shock response. For being able to discriminate between the two closely related factors HSF 1 and HSF 2, specific cDNA sequences were cloned and used to generate antisense RNAs as hybridization probes. In general, in various cell lines expression of the two heat shock factors was clearly different. These expression patterns of the HSF genes were not influenced by retinoic acid-induced differentiation of human NT2 and mouse F9 teratocarcinoma cells. Generally, HSF 2 expression was extremely low, whereas the significantly higher expression of HSF 1 revealed cell specific differences. The highest expression rates of both HSFs were observed in 293 cells. To examine whether these high levels are involved in the constitutive expression of heat shock genes in these cells, we analysed the binding pattern of 293 cell proteins to the heat shock elements (HSEs). As with other cells, HSE-binding activity in 293 cells was only observed after heat shock treatment. This points to an HSE-independent way for high level expression of heat shock genes in these cells.     

Inactivation of splicing factors in HeLa cells subjected to heat shock

The nuclear extracts from HeLa cells subjected to heat shock at 43 or 46 degrees C for 2 h were unable to splice pre-mRNA in vitro. Analysis of snRNPs in the extracts revealed that the U4.U5.U6 small nuclear ribonucleoprotein particle (snRNP) complex was disrupted at both temperatures while U1 and U2 snRNPs remained unaffected at 43 degrees C but were disrupted to certain extent during heat shock at 46 degrees C. During splicing reaction, the extract from cells heat shocked at 43 degrees C formed intermediate splicing complexes alpha and beta but was unable to form a functional spliceosome, complex gamma. Addition of fractions from a normal nuclear extract restored splicing activity only in the extract from cells subjected to heat shock at 43 degrees C. Using this complementation assay, we have partially purified the factor(s) inactivated at this temperature. The purified factor(s) was essentially devoid of snRNAs and snRNPs and resistant to micrococcal nuclease, indicating that the factor(s) inactivated by in vivo heat shock at 43 degrees C is a protein. We have also subjected the nuclear extracts from normal HeLa cells to in vitro heat treatment at 43 or 46 degrees C. The results indicate that during in vitro heat treatment of the extracts the damage to splicing machinery is more extensive than that during in vivo heat shock. These experiments also suggest that the factor(s) inactivated by heat shock at 43 degrees C is different from previously identified thermolabile splicing factors.     

Interaction of the Neurospora crassa heat shock factor with the heat shock element during heat shock and different developmental stages

The interaction of the heat shock factor (HSF) with the heat shock element (HSE) was determined by a non-radioactive electrophoretic mobility shift assay, in order to analyze HSF regulation in Neurospora crassa. HSF binds to HSE under normal, non-stress conditions and is thus constitutively trimerized. Upon heat shock, the HSF-HSE complex shows a retarded mobility. This was also observed in Saccharomyces cerevisiae, where this mobility shift was shown to be due to HSF phosphorylation [Sorger and Pelham (1988) Cell 54, 855-864]. In N. crassa, HSE-dependent electrophoretic mobility shift is temperature- and time-dependent. Under normal growth conditions, the HSF is located in the cytoplasm as well as in the nucleus. In germinating conidia the HSF shows a retarded mobility typical for heat shock even at normal growth temperatures. No HSF-dependent mobility shift was detectable in aerial hyphae.