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.     

Ecdysterone selectively stimulates the expression of a 23000-Da heat-shock protein-beta-galactosidase hybrid gene in cultured Drosophila cells

To study the regulated expression of cloned heat-shock genes in homologous cells, hybrid Drosophila heat-shock-Escherichia coli beta-galactosidase genes were constructed. Segments of the ecdysterone-inducible 23,000-Da heat-shock protein (hsp23) gene and of two other hsp genes (hsp84 and 70), which are not hormone regulated, were functionally linked to the bacterial coding sequence, and the resulting hybrid genes were introduced into cultured, hormone-responsive Drosophila cells by transfection. All hybrid genes directed the synthesis of E. coli-specific beta-galactosidase in heat-treated cells. hsp23 hybrid gene expression was stimulated strongly by ecdysterone, while the activities of the other hybrid genes were not affected at all by the hormone. A hybrid gene with only 147 bp of hsp23 promoter sequence could not be activated by either heat or ecdysterone treatment. Thus, far upstream sequences contain signals required for the regulated expression of the hsp23 gene in Drosophila cells.     

Ecdysterone selectively stimulates the expression of a 23000-Da heat-shock protein-β-galactosidase hybrid gene in cultured Drosophila cells

To study the regulated expression of cloned heat-shock genes in homologous cells, hybrid Drosophila heat-shock-Escherichia coli β-galactosidase genes were constructed. Segments of the ecdysterone-inducible 23,000-Da heat-shock protein (hsp23) gene and of two other hsp genes (hsp84 and 70), which are not hormone regulated, were functionally linked to the bacterial coding sequence, and the resulting hybrid genes were introduced into cultured, hormone-responsive Drosophila cells by transfection. All hybrid genes directed the synthesis of E. coli-specific β-galactosidase in heat-treated cells. hsp23 hybrid gene expression was stimulated strongly by ecdysterone, while the activities of the other hybrid genes were not affected at all by the hormone. A hybrid gene with only 147 bp of hsp23 promoter sequence could not be activated by either heat or ecdysterone treatment. Thus, far upstream sequences contain signals required for the regulated expression of the hsp23 gene in Drosophila cells.     

Expression of microinjected hsp 70/CAT and hsp 30/CAT chimeric genes in developing Xenopus laevis embryos

The expression of microinjected chimeric genes containing Drosophila hsp 70 and Xenopus hsp 70 and hsp 30 promoters linked to the reporter gene coding for bacterial chloramphenicol acetyltransferase (CAT) was examined during early development of Xenopus laevis. Heat-inducible expression of fusion genes containing either the Drosophila hsp 70 promoter (1100 bp) or the Xenopus hsp 70 promoter (750 bp) was first detectable after the midblastula stage of development. This coincides with the embryonic stage at which the endogenous hsp 70 gene is first heat-inducible. A Xenopus hsp 30/CAT fusion gene containing 350 bp of promoter sequences was also heat-inducible after the midblastula stage unlike the endogenous hsp 30 genes which were not heat-inducible until the early tailbud stage (stage 23-24). Sequences that are present within either the coding or 3' region of the hsp 30 clone do not cause the microinjected hsp 30 gene to be developmentally regulated in a normal manner. Additionally, microinjected hsp 30 gene sequences have no effect on the developmental regulation of endogenous hsp 30 genes which continue to be activated at the tailbud stage of development. Our data suggest, that an inhibitory system, which may control the expression of the endogenous hsp 30 gene during development, does not regulate the expression of the injected hsp 30 gene.     

Nucleotide sequences of heat shock activated genes in Drosophila melanogaster. I. Sequences in the regions of the 5' and 3' ends of the hsp 70 gene in the hybrid plasmid 56H8.

We present the sequences at the 5' and 3' ends of one hsp 70 gene variant which is derived from the chromosomal locus 87A7. The 5' end of the hsp 70 mRNA has also been determined. 550 bp upstream from the 5' end of the hsp 70 mRNA, there is a very A+T rich region shown by heteroduplex analysis to be also present at the same position in other hsp 70 genes9. The 5' end of the hsp 70 mRNA was found 26 bp after a characteristic "Hogness box". The first ATG codon was found 250 bp downstream from the 5' end of the hsp 70 mRNA. We also determined the termination codon at the 3' end of the hsp 70 gene. Comparisons with other genes are discussed.     

hsp23 and hsp26 exhibit distinct spatial and temporal patterns of constitutive expression in Drosophila adults

To determine differences in the patterns of expression of Drosophila small heat shock proteins (shsp) during normal development in the absence of stress, proteins obtained from head, thorax and gonads of young (0–12 h, 3 days), middle-aged (3–6 days) and 15- to 20-day-old adult flies were separated on SDS-PAGE gels and blotted with monoclonal antibodies against hsp23 and hsp26. hsp23 was found in the heads and gonads of young males and females. In contrast, the maximum expression of hsp26 was seen in gonads of young flies, and it was only lightly detected in the brain. The expression of both proteins decreased as flies aged. This age-related decrease was particularly striking for hsp23 in females. The immunoblot results obtained were complemented by immunostaining of thin parasagittal sections of whole fly bodies Hsp23 was found to be expressed in the brain, thoracic ganglion, fat body and gonads of young (0-12 h) males and females. On the other hand, hsp26 was essentially detected in ovaries and testes of these young flies. The analysis of the tissue expression of both proteins demonstrate that each shsp has a distinct cellular localization. In the central nervous system, hsp23 and hsp26 were present in the neurocytes of the brain and the thoracic ganglion. In addition, hsp23 (but not hsp26) was also detected in the central neuropile of these two organs. In testis, hsp26 was localized in the cytoplasm of spermatocytes and, probably, in the spermatid bundles. In contrast, hsp23 was detected at the periphery of cells (membranes). In ovorioles of newborn females the expression of hsp26 was stronger, and the maximum expression of hsp23 was only reached in older (2 days and more) flies. These results demonstrate that each shsp possesses a specific spatial and temporal pattern of expression in adults of Drosophila. The distinct tissue-specific and age-dependent expression of hsp23 and hsp26 suggests that these two proteins may have different functions in crucial organs of Drosophila. © 1993Wiley-Liss, Inc.     

Expression of endogenous and microinjected hsp 30 genes in early Xenopus laevis embryos

In the present study, we have examined the regulation of expression of a newly isolated member of the hsp 30 gene family, hsp 30C. Using RT-PCR, we found that this gene was first heat-inducible at the tailbud stage of development. We also examined the expression of two microinjected modified hsp 30C gene constructs in Xenopus embryos. One of the constructs had 404 bp of hsp 30C 5′-flanking region, whereas the other had 3.6 kb. Both gene constructs had 1 kb of 3′-flanking region. RT-PCR assays were employed to detect the expression of these microinjected genes. The presence of extensive 5′- and 3′-flanking regions of the hsp 30C gene did not confer proper developmental regulation, since heat-inducible expression of both of the microinjected constructs was detectable at the midblastula stage. The premature expression of the microinjected hsp 30 gene was not a result of high plasmid copy number or the presence of plasmid DNA sequences. These results suggest that the microinjected genes contain all the cis-acting DNA sequences required for correct heat-inducible regulation but do not contain the elements required for the proper regulation of hsp 30 gene expression during development. It is possible that regulatory elements controlling the developmental expression of the hsp30 genes may reside upstream or downstream of the entire cluster. © 1993Wiley-Liss, Inc.