Human heat shock gene expression and the modulation of plasma membrane Na+, K+-ATPase activity

Benzodiazepine receptor solubilized from bovine cortical membranes was bound to a new benzodiazepine affinity column, the synthesis of which is described. Bio-specific elution with the benzodiazepine compound chlorazepate resulted in the elution of fractions highly enriched in specific binding for the GABA receptor agonist muscimol. Specific activity for [³H]muscimol binding was >1.3 nmol/mg protein. It is shown that [³H]flunitrazepam binding activity can be recovered by removal of chlorazepate from the purified fraction. These results strongly support a model which suggests that the 2 binding sites reside on the same physical entity.     

Differential heat shock gene expression in chick blastula

Summary The component areas of chick blastula show differential expression of heat shock genes. The area opaca (ao), marginal zone (mz) and central area (ca) components of the epiblast display distinct quantitative and minor qualitative differences in the heat-induced and heat-repressible proteins, but are clearly different from the primary hypoblast (endoderm) in their expression of a given stress protein (hsp) as a response to heat shock. The major proteins synthesized in the component areas of epiblast in response to heat shock include hsp 18, 24, 70 and 89 Kd. Two-dimensional electrophoresis shows that each of these proteins consists of multiple charged species. The hypoblast expresses only hsp 70 Kd at non-significant levels and shows marked inhibition in the level of synthesis of heat-shock-repressible proteins. Heat shock during the blastula stage results in an increase in the size of the blastoderm and disrupts normal embryonic development. The heat shock genes provide an important molecular marker, which attests to regional specification in the chick blastula.     

Identification and expression of a cloned yeast heat shock gene

We have isolated the yeast HSP90 gene which encodes the Mr = 90,000 heat shock-inducible protein of this organism. When this gene is introduced into yeast on a multicopy plasmid vector, a dramatic increase is observed in the level of synthesis of the Mr = 90,000 heat shock-inducible protein. This protein overproduction is due to expression of the plasmid-borne HSP90 gene, which is under the same heat shock regulation as its chromosomal counterpart. The presence of an increased dosage of the HSP90 gene has no effect on the synthesis of the other major heat shock-inducible proteins and does not alter the heat shock-associated phenotype of thermal tolerance.     

Structural changes in chromatin of heat shock protein 70 gene of Drosophila during transcription

Using "protein-image" hybridization technique combined with various crosslinking methods, for formaldehyde-prefixed nuclei we have analysed changes induced by activation in the chromatin structure of HSP-70 genes. From the crosslinking data it follows that chromatin of actively transcribed genes undergoes some structural rearrangements resulting in certain weakening of the contacts between DNA and the globular parts of histones so that the histones remain bound to DNA through their N-terminal regions. In addition, there have been found two specific regions with a reduced content of histones: the 5'-promoter of HSP-70 gene and a region distanced by approximately 1 k.b. from the 3'-end of the HSP-70 gene.     

DNA methylation and chromatin structure regulate T cell perforin gene expression

Perforin is a cytotoxic effector molecule expressed in NK cells and a subset of T cells. The mechanisms regulating its expression are incompletely understood. We observed that DNA methylation inhibition could increase perforin expression in T cells, so we examined the methylation pattern and chromatin structure of the human perforin promoter and upstream enhancer in primary CD4(+) and CD8(+) T cells as well as in an NK cell line that expresses perforin, compared with fibroblasts, which do not express perforin. The entire region was nearly completely unmethylated in the NK cell line and largely methylated in fibroblasts. In contrast, only the core promoter was constitutively unmethylated in primary CD4(+) and CD8(+) cells, and expression was associated with hypomethylation of an area residing between the upstream enhancer at -1 kb and the distal promoter at -0.3 kb. Treating T cells with the DNA methyltransferase inhibitor 5-azacytidine selectively demethylated this area and increased perforin expression. Selective methylation of this region suppressed promoter function in transfection assays. Finally, perforin expression and hypomethylation were associated with localized sensitivity of the 5' flank to DNase I digestion, indicating an accessible configuration. These results indicate that DNA methylation and chromatin structure participate in the regulation of perforin expression in T cells.