Heat shock and ecdysterone activation of the Drosophila melanogaster hsp23 gene; a sequence element implied in developmental regulation.

The regulation of the Drosophila melanogaster hsp23 gene by heat shock and ecdysterone has been analysed by measuring activities of hsp--Escherichia coli beta-galactosidase hybrid genes in transfected hormone-sensitive D. melanogaster cells. Mutation analysis identified multiple, distinct promoter elements. A sequence element, which also occurs in the promoters of several other developmentally regulated Drosophila genes, is present in regions of the hsp23 promoter that are essential for its ecdysterone, but not its heat-regulated activity; this element may represent a binding site for an ecdysterone--receptor complex. Mutant promoters that can be activated only by heat shock or by hormone have been constructed. Thus the two types of regulation of the hsp23 gene can function independently of each other.     

The heat shock consensus sequence is not sufficient for hsp70 gene expression in Drosophila melanogaster.

A hybrid gene in which the expression of an Escherichia coli beta-galactosidase gene was placed under the control of a Drosophila melanogaster 70,000-dalton heat shock protein (hsp70) gene promoter was constructed. Mutant derivatives of this hybrid gene which contained promoter sequences of different lengths were prepared, and their heat-induced expression was examined in D. melanogaster and COS-1 (African green monkey kidney) cells. Mutants with 5' nontranscribed sequences of at least 90 and up to 1,140 base pairs were expressed strongly in both cell types. Mutants with shorter 5' extensions (of at least 63 base pairs) were transcribed and translated efficiently in COS-1 but not at all in D. melanogaster cells. Thus, in contrast to the situation in COS-1 cells, the previously defined heat shock consensus sequence which is located between nucleotides 62 and 48 of the hsp70 gene 5' nontranscribed DNA segment is not sufficient for the expression of the D. melanogaster gene in homologous cells. A second consensus-like element 69 to 85 nucleotides upstream from the cap site is postulated to be also involved in the heat-induced expression of the hsp70 gene in D. melanogaster cells.     

Heat shock proteins and aging in Drosophila melanogaster

Heat shock proteins (Hsps) are conserved molecular chaperones that are upregulated following exposure to environmental stress and during aging. The mechanisms underlying the aging process are only beginning to be understood. The beneficial effects of Hsps on aging revealed in mild stress and overexpression experiments suggest that these proteins are part of an important cell protection system rather than being unspecific molecular chaperones. Among the Hsps families, small Hsps have the greatest influence on aging and the modulation of their expression during aging in Drosophila suggest that they are involved in pathways of longevity determination.     

Heat shock protection against cold stress of Drosophila melanogaster.

Heat shock protein synthesis can be induced during recovery from cold treatment of Drosophila melanogaster larvae. Survival of larvae after a cold treatment is dramatically improved by a mild heat shock just before the cold shock. The conditions which induce tolerance to cold are similar to those which confer tolerance to heat.     

Purification of Drosophila hsp 83 and immunoelectron microscopic localization

Heat-shock protein (hsp) 83 was purified from Drosophila culture cells. Analysis by gel filtration revealed that this hsp exists in a dimeric form under nondenaturing conditions. Monoclonal and polyclonal antibodies produced against this hsp have been used to determine its intracellular localization by indirect immunofluorescence and immunogold electron microscopy in normal cells, after heat shock, during recovery and after a second heat shock. Under normal conditions, hsp 83 is predominantly cytoplasmic. Immunogold labeling reveals that this hsp is associated with vacuole-like structures containing numerous dense bodies. In addition, hsp 83 is detected, albeit at a lower level, in the nucleus where it is found within the network of perichromatin ribonucleoprotein (RNP) fibrils. This distribution changes during heat shock: hsp 83 is then found in increased concentrations at the cell periphery close to the plasma membrane. After a recovery period, hsp 83 appears associated with the nuclear membrane and/or with the neighboring endoplasmic reticulum. Following a second heat shock at 37 degrees C after recovery, a renewed deposition of hsp 83 is observed at the cell periphery. A small population of cells also shows an increased concentration of this protein in the nucleus. This intracellular distribution of hsp 83 is consistent with its reported association with various cellular proteins and suggest that this hsp may be involved in their intracellular transport and/or in the modulation of their activity.     

Adaptation of Drosophila enzymes to temperature--V. Heat shock effect on the malate dehydrogenase of Drosophila melanogaster

Drosophila melanogaster cMdh allozymic variants (MdhF MdhF/S, MdhS) were subjected to heat shock (33 degrees C/30 min----40 degrees C/30 min). This stress increases differentially MDH specific activity, with the cMdhF strain showing greater response as compared with the cMdhS one; heterozygotes exhibited generally intermediate values. Correlative differences were also revealed for some catalytic properties (Vmax, Vmax/Km ratio, thermostability) of the cMDH; this is not true for the mMDH. The catalytic behavior of the enzyme is correlated with the differential survival of the cMdh variants, with the cMdhF showing again higher survival than the cMdhS one, a fact which seems to contribute to temperature adaptation of D. melanogaster.     

Heat shock of Drosophila melanogaster induces the synthesis of new messenger RNAs and proteins.

The heat shock proteins, labelled in vivo with [35S]methionine, were separated by sodium dodecylsulphate-polyacrylamide gel electrophoresis and fingerprinted after tryptic digestion. Eight distinct heat shock polypeptides are characterized in this way. Heat shock messenger RNAs were isolated and partially purified. Assayed in vitro for protein synthesis, they were found to code for heat shock polypeptides. Some parameters of the kinetics of in vivo synthesis of the heat shock proteins are presented.     

Heat shock mRNA accumulation during recovery from cold shock in Drosophila melanogaster

Heat shock protein synthesis is induced in response to a variety of chemical and physical stresses. Among these are heating above normal growing temperatures, treatment with heavy metals, amino acid analogues, steroid hormones and a variety of other chemicals (CRC Crit. Rev. Biochem. 18, 239–280). We have shown previously that heat shock proteins are also synthesized during recovery from prolonged 0°C treatment in Drosophila larval salivary glands. In this paper we describe the cold treatments which induce heat shock protein synthesis in more detail, and show that heat shock mRNA does not accumulate during the cold treatment, but rather during the recovery period when the larvae are returned to 25°C. The implications of these results for the regulation of heat shock mRNA levels, and for the role of heat shock proteins in recovery from cold shock are discussed.     

Multiple, compensatory regulatory elements specify spermatocyte-specific expression of the Drosophila melanogaster hsp26 gene.

The hsp26 gene of Drosophila melanogaster is expressed in six tissues during development and in a tissue-general response to heat shock. To be able to compare tissue-specific and heat-induced mechanisms of hsp26 expression, we have begun an analysis of the sequences involved in the spermatocyte-specific expression of the hsp26 gene by using germ line transformation. hsp26 mRNA synthesized in the spermatocytes has the same start site as sites previously demonstrated for nurse cell-specific and heat-induced mRNAs. Three regions of the hsp26 gene (nucleotides -351 to -135, -135 to -85, and +11 to +632) were able to stimulate spermatocyte-specific expression when fused with promoter sequences (nucleotides -85 to +11) that alone were insufficient to stimulate expression. These stimulatory regions appear to contain elements that provide redundant functions. While each region was able to stimulate expression independently, the deletion of any one region from a construct was without consequence as long as another compensatory region(s) was still present. There must reside, at a minimum, two independent spermatocyte-specifying elements within the sequences that encompass the three stimulatory regions and the promoter. At least one element is contained within sequences from -351 to -48. This region, in either orientation, can stimulate spermatocyte-specific expression from a heterologous promoter. A second element must reside in sequences from -52 to +632, since these sequences are also sufficient to direct spermatocyte-specific expression.     

Expression and localization of Drosophila melanogaster hsp70 cognate proteins.

Monoclonal antibodies have been used to identify three proteins in Drosophila melanogaster that share antigenic determinants with the major heat shock proteins hsp70 and hsp68. While two of the proteins are major proteins at all developmental stages, one heat shock cognate protein, hsc70, is especially enriched in embryos. hsc70 is shown to be the product of a previously identified gene, Hsc4. We have examined the levels of hsp70-related proteins in adult flies and larvae during heat shock and recovery. At maximal induction in vivo, hsp70 and hsp68 never reach the basal levels of the major heat shock cognate proteins. Monoclonal antibodies to hsc70 have been used to localize it to a meshwork of cytoplasmic fibers that are heavily concentrated around the nucleus.     

Primary sequence and developmental expression of a novel Drosophila melanogaster src gene.

We have sequenced a cDNA clone for the Drosophila melanogaster gene Dsrc28C, a homolog of the vertebrate gene c-src. The cDNA contains a single open reading frame encoding a protein of 66 kilodaltons which contains features highly conserved within the src family of tyrosine protein kinases. Novel structural features of the Dsrc28C protein include a basic pI and a polyglycine domain near the amino terminus. Cell-free translation of in vitro-transcribed RNA yielded a protein of the predicted size which could be immunoprecipitated by anti-v-src antisera. RNA blot hybridization revealed that the gene is expressed predominantly during embryogenesis, in imaginal disks of third-instar larvae, and in adult females. In situ hybridization showed that expression in adult females is largely confined to nurse cells and developing oocytes.