The dynamics of chromatin condensation: redistribution of topoisomerase II in the 87A7 heat shock locus during induction and recovery.

We have examined the in vivo sites of action for topoisomerases II in the 87A7 heat shock locus as a function of gene activity. When the hsp70 genes are induced, there is a dramatic redistribution of topoisomerase II in the locus which parallels many of the observed alterations in chromatin structure. In addition to changes in the topoisomerase II distribution within the locus, we find topoisomerase II localized around the putative domain boundaries scs and scs'. During recovery, when the chromatin fiber of the locus recondenses, the major sites of action for topoisomerase II appear to be located within the two hsp70 genes and in the intergenic spacer separating the two genes.     

The constitutive and stress inducible forms of hsp 70 exhibit functional similarities and interact with one another in an ATP- dependent fashion

Mammalian cells constitutively express a cytosolic and nuclear form of heat shock protein (hsp) 70, referred to here as hsp 73. In response to heat shock or other metabolic insults, increased expression of another cytosolic and nuclear form of hsp 70, hsp 72, is observed. The constitutively expressed hsp 73, and stress-inducible hsp 72, are highly related proteins. Still unclear, however, is exactly why most eukaryotic cells, in contrast to prokaryotic cells, express a novel form of hsp 70 (i.e., hsp 72) after experiencing stress. To address this question, we prepared antibodies specific to either hsp 72 or hsp 73 and have compared a number of biological properties of the two proteins, both in vivo and in vitro. Using metabolic pulse-chase labeling and immunoprecipitation analysis, both the hsp 72 and hsp 73 specific antibodies were found to coprecipitate a significant number of newly synthesized proteins. Such interactions appeared transient and sensitive to ATP. Consequently, we suspect that both hsp 72 and hsp 73 function as molecular chaperones, interacting transiently with nascent polypeptides. During the course of these studies, we routinely observed that antibodies specific to hsp 73 resulted in the coprecipitation of hsp 72. Similarly, antibodies specific to hsp 72 were capable of coprecipitating hsp 73. Using a number of different approaches, we show that the constitutively expressed, pre-existing hsp 73 rapidly forms a stable complex with the newly synthesized stress inducible hsp 72. As is demonstrated by double-label indirect immunofluorescence, both proteins exhibit a coincident locale within the cell. Moreover, injection of antibodies specific to hsp 73 into living cells effectively blocks the ability of both hsp 73 and hsp 72 to redistribute from the cytoplasm into the nucleus and nucleolus after heat shock. These results are discussed as they relate to the possible structure and function of the constitutive (hsp 73) and highly stress inducible (hsp 72) forms of hsp 70, both within the normal cell as well as in the cell experiencing stress.     

A consensus sequence polymer inhibits in vivo expression of heat shock genes.

Promoter function for hsp70 gene expression in Drosophila melanogaster was studied with an in vivo competition assay. A polymer of 40 tandem copies of the pair of regulatory elements of the hsp70 gene was constructed and cloned into a plasmid vector. Various marked genes were cotransfected with the polymer plasmid into Schneider line 2 cells, and their expression was determined by enzyme activity measurements. The polymer dramatically inhibited expression of cotransfected hsp70, hsp26, and hsp83 genes, but not cotransfected copia and histone genes. Our results indicate that in vivo, a trans-acting, positive regulatory factor, which can be titrated by heat shock consensus sequences, is required for activation of heat shock genes and is specific for these genes; the coordinate induction of different heat shock genes appears to be mediated by similar, but not identical, interactions of the trans-acting induction factor and the cis-acting heat shock consensus sequences; and the uninduced or basal level expression of the transfected hsp70 gene is also due to interaction of the consensus sequence with a positively acting factor.     

The 87A7 chromomere. Identification of novel chromatin structures flanking the heat shock locus that may define the boundaries of higher order domains

The chromatin fiber of eukaryotic chromosomes is thought to be organized into a series of discrete domains or loops. To learn more about these large-scale structures, we have examined the sequence and chromatin organization of the DNA segments surrounding the two hsp 70 genes at the Drosophila melanogaster cytogenetic locus 87A7. These studies indicate that this heat shock locus is flanked on both the proximal and distal sides by novel chromatin structures, which we have called, respectively, scs and scs' (specialized chromatin structures). Each structure is defined by two sets of closely spaced nuclease-hypersensitive sites arranged around a central nuclease-resistant segment. Our findings suggest that these two structures define the proximal and distal boundaries of the 87A7 chromomere and, hence, may be one of the first examples of anchor points for the organization of eukaryotic chromosomes into a series of discrete higher order domains. Moreover, these structures may provide focal points both for the decondensation of the chromomere when the hsp 70 genes are induced by heat shock and for the subsequent rewinding and condensation of the chromomere during recovery from heat shock.