Patterns of protein synthesis following heat shock in pupae of Drosophila melanogaster

Pupae of Drosophila melanogaster were heat-shocked under conditions required to induce phenocopies in more than 90% of the flies that subsequently emerge. The effects of these treatments on protein synthesis in two tissues (thoracic epithelium and brain) were followed for several hours after the heat treatments. Results from pulse-labeling and protein separations on sodium dodecylsulfate (SDS) acrylamide gels showed a virtually complete cessation of protein synthesis immediately after the shock, followed by a noncoordinate resumption of the starting pattern. Similar experiments following double heat shocks demonstrated a more rapid resumption of synthesis of heat shock proteins after two successive heat treatments than after a single one.     

Prosomes and heat shock complexes in Drosophila melanogaster cells.

Prosomes and heat shock protein (HSP) complexes isolated from the cytoplasm of Drosophila cells in culture were biochemically and immunologically characterized. The two complexes were found to separate on sucrose gradients, allowing the analysis of their protein constituents by two-dimensional polyacrylamide gel electrophoresis and by reaction with anti-HSP sera and prosome-specific monoclonal antibodies. All of the prosomal proteins were found to be clearly distinct from the HSP; none of the prosomal proteins was synthesized de novo in heat shock. However, an antiprosome (anti-p27K) monoclonal antibody (mouse anti-duck) recognizing the Drosophila p29K prosomal protein allowed immunoprecipitation from a heat-shocked postmitochondrial supernatant of the crude HSP complex, including the low- and the high-molecular-weight components, in particular the 70 x 10(3)-molecular weight HSP. The highly purified small 16S HSP complex still contained this preexistent p29K prosomal protein, which thus also seems to be a metabolically stable constituent of the HSP complex. The significance of this structural and possibly functional relationship between prosomes and HSP, involving the highly ubiquitous and evolutionarily conserved prosomal protein p27/29K, remains to be elucidated.     

Synthesis of heat shock proteins in Drosophila melanogaster embryos

The pattern of polypeptides synthesized in a cell-free protein synthesizing system containing polysomes isolated from heat-shocked (37 C) Drosophila embryos showed significant differences when compared with the pattern obtained when polysomes from normal embryos were used. The synthesis of normal embryonal proteins was reduced and the heat shock proteins were the major products of elongation. After short, 10 min, heat treatment mainly quantitative changes were observed suggesting that normal mRNAs were still present on polysomes, and their products could be completed in vitro in the heterologous cell-free system. The mRNAs coding for normal embryonal proteins were present in almost unchanged amounts in heat-shocked embryos as could be judged from the pattern of proteins synthesized in heterologous cell-free system supplemented with cytoplasmic RNA from normal and heat-shocked embryos. Thus the change in protein synthesis in heat-shocked embryos is not associated with degradation of normal embryonal mRNAs but with their inaccessibility for translation.     

Dephosphorylation of S6 and expression of the heat shock response in Drosophila melanogaster.

A basic ribosomal phosphoprotein of 30,000 molecular weight was rapidly dephosphorylated in cultured Drosophila melanogaster cells heat shocked at 37 degrees C. The protein was associated with the 40S ribosomal subunit and had an electrophoretic mobility similar to that of purified rat liver protein S6 on basic two-dimensional polyacrylamide gels as well as a similar partial proteolysis peptide map. In logarithmically growing cultures, this D. melanogaster S6 protein appeared to have a single phosphorylated species consisting of 30 to 40% of the total cellular S6. Thus, the nearly complete dephosphorylation of this protein observed in heat shock involves a large fraction of the cellular S6. The significance of this dephosphorylation in the expression of the heat shock response was investigated by examining the phosphorylation status of S6 in recovery from heat shock and in response to chemical inducers of the heat shock response. During recovery from a 30-min heat shock, the recovery of normal protein synthesis was almost complete in 2 to 4 hr, whereas there was no significant rephosphorylation of S6 for 8 h. Two chemical inducers of the heat shock response, canavanine and sodium arsenite, induced the synthesis of heat shock proteins in D. melanogaster cells. Sodium arsenite also caused an inhibition of normal protein synthesis similar to that observed in heat shock. Neither agent, however, caused significant dephosphorylation of S6. These results suggest that the dephosphorylation of S6, although invariably observed in heat-shocked cells, may in some cases be dissociated from both the induction of heat shock protein synthesis and the turnoff of normal protein synthesis which occur in a heat shock response.     

Regulated expression of a Drosophila melanogaster heat shock locus after stable integration in a Drosophila hydei cell line.

DNA-mediated cotransformation has been used to transfer a Drosophila melanogaster heat shock locus into cultured Drosophila hydei cells by use of the copia-based selectable vector pCV2gpt and of pMH10A, a cloned 87A7 heat shock locus encoding a mutant heat shock protein (hsp). Transformed lines contain between 50 and 200 copies of both plasmids, each separately organized as a head-to-tail concatemer which is stably maintained in the transformed lines. Exposure of the cotransformants to heat shock temperatures induces the regulated expression of the hsp RNA and the mutant hsp in all the lines analyzed.