Aging affects expression of 70-kDa heat shock proteins in Drosophila

We examined the effect of cellular aging on adult mortality and hsp70 gene expression in Drosophila melanogaster under thermal stress. The results showed that flies exposed to 37 degrees C for various time intervals had reduced survival rate with age. The level of hsp70 mRNA increases in flies up to 23-28 days of age, but then declines as they get older. When flies are shifted to 25 degrees C after 30 min of heat stress, the time-dependent decrease in hsp70 mRNA levels occurs more rapidly in young flies than in old ones. The hsp70 mRNA present during this recovery period is translated into protein, and senescent flies continue to synthesize this protein for up to 5 h after heat shock. The prolonged expression of hsp70 RNA during recovery from heat shock was also observed in young flies fed canavanine, an arginine analogue. These data suggest that in old insects, the accumulation of conformationally altered proteins plays a role in the regulation of hsp70 RNA expression. These results are discussed in relation to the finding that old flies are more sensitive to thermal stress than young ones.     

Heat shock and developmental regulation of the Drosophila melanogaster hsp83 gene.

In contrast to the hsp70 gene, whose expression is normally at a very low level and increases by more than 2 orders of magnitude during heat shock, the hsp83 gene in Drosophila melanogaster is expressed at high levels during normal development and increases only severalfold in response to heat shock. Developmental expression of the hsp83 gene consists of a high level of tissue-general, basal expression and a very high level of expression in ovaries. We identified regions upstream of the hsp83 gene that were required for its developmental and heat shock-induced expression by assaying beta-galactosidase activity and mRNA levels in transgenic animals containing a series of 5' deletion and insertion mutations of an hsp83-lacZ fusion gene. Deletion of sequences upstream of the overlapping array of a previously defined heat shock consensus (HSC) sequence eliminated both forms of developmental expression of the hsp83 gene. As a result, the hsp83 gene with this deletion mutation was regulated like that of the hsp70 gene. Moreover, an in vivo polymer competition assay revealed that the overlapping HSC sequences of the hsp83 gene and the nonoverlapping HSC sequences of the hsp70 gene had similar affinities for the factor required for heat induction of the two heat shock genes. We discuss the functional similarity of hsp70 and hsp83 heat shock regulation in terms of a revised view of the heat shock-regulatory sequence.     

Heat shock gene activation by mutant actin is independent of myofibril degeneration in Drosophila muscle

Artificially mutagenized Drosophila Act88F actin genes with triple and double mutations were expressed in the indirect flight muscles of transgenic flies. The triple mutant actin, GD245T (Gly-36----Glu, Glu-83----Asp, and Gly-245----Asp), induced heat shock protein (hsp) synthesis without affecting flight ability. On the other hand, the double mutation, GD245D (Gly-36----Glu and Glu-83----Asp), disrupted myofibrils but induced little hsp synthesis. These results demonstrate that myofibril degeneration is not the primary cause of the anomalous heat shock gene activation by mutant actins.     

Heat-inducible transgenic expression in the silkmoth Bombyx mori

Germline transformation with new transposon vectors now enables causal tests of gene function via ectopic protein expression or RNA interference in non-drosophilid insects. The problem remains of how to drive the transgene expression in vivo. We employed germline transformation using the piggyBac 3xP3-EGFP vector to test whether the Drosophila heat shock hsp70 promoter will be active in the live silkworm. We modified the original vector by cloning the coding sequence for Bombyx nuclear receptor Ftz-F1 between the hsp70 promoter and the terminator. Three independent transgenic lines expressing the Pax-6-driven EGFP marker in larval and adult photoreceptors were obtained with efficiencies of up to 1.7% of fertile G0 adults that gave GFP-positive progeny. Chromosomal integration of the transposon was confirmed with inverse PCR. Heat induction of the transgenic BmFtz-F1 was proven at both the mRNA and protein levels. RT-PCR data showed that the Drosophila heat shock promoter was functional in all three transgenic lines. Although basal activity was apparent at 25 degrees C, 1 h at 42 degrees C induced BmFtz-F1 mRNA at different stages of development and in diverse tissues. The relative levels of induction differed among the transgenic lines. Northern blot hybridization detected transgenic BmFtz-F1 only after heat shock and low levels of the mRNA were still present 6 h after the heat treatment. Immunostaining of epidermis using anti-BmFtz-F1 antibody showed a clear increase of nuclear signal 90 min after a heat shock.     

Heat shock induces changes in the expression and binding of ubiquitin in senescent Drosophila melanogaster

We examined the effect of aging on the expression of ubiquitin RNA and the binding of the ubiquitin polypeptide to proteins following heat shock in Drosophila melanogaster. Heat-shocked adult flies transcribe two major RNA species-one of 4.4 kb and one of about 6 kb that hybridize to the polyubiquitin-encoding probe. Several less abundant RNAs were also observed but the 4.4-kb band was present as the major RNA species in both stressed and nonstressed flies of both ages. The 6-kb fragment was more abundant in heat shocked aged flies than in younger flies. The quantitative expression of the polyubiquitin gene increased in proportion to the duration of the heat stress. Moreover, the induction of the polyubiquitin RNA was markedly elevated during aging following heat shock. Hybridization of Northern blots with the monoubiquitin gene probe revealed a band of 0.9 kb that was not significantly affected by heat stress. We also investigated the relationship between the changes in polyubiquitin gene expression and the formation of ubiquitin-protein complexes in aging heat-shocked flies. Heat shock to old flies results in a significant increase in the level of proteins immunoprecipitated by anti-ubiquitin antibodies. In the case of proteins synthesized 2 h before heat shock, most of the ubiquitinated proteins were of high molecular weight. For those proteins synthesized during a 30-min heat shock and the 2 h following heat shock, two major immunoprecipitated bands were observed: an 80-kD and a 70-kD polypeptide. The ubiquitination of a 60 kD protein was also observed in nonstressed flies, but its for mation was drastically reduced following heat shock. For proteins synthesized during and after heat shock from both age groups, the major ubiquitinated polypeptide is 70 kD. In all age groups, more ubiquitin complexes were formed with proteins synthesized before heat shock, than with proteins synthesized either during or after heat shock. This suggests that cellular proteins synthesized at physiological temperatures are more sensitive to heat induced damage than those synthesized during stress. These data support the hypothesis that in aging flies, heat shock induces an unusually high concentration of abnormal proteins which are targeted for degradation by the ubiquitin-dependent proteolytic system. © 1993Wiley-Liss, Inc.     

The use of promoter fusions in Drosophila genetics: isolation of mutations affecting the heat shock response

We have constructed a gene fusion using the promoter of Drosophila hsp70 and the structural gene for Drosophila alcohol dehydrogenase (Adh) and used this construct to transform Adh-deficient flies. In these transformants, Adh is expressed only after heat shock. Like hsp70 itself, this heat-shock-inducible Adh (Adhhs) is induced in a wide variety of tissues. It fails to be induced in primary spermatocytes. Although the tissue distribution of Adh activity is very different from wild type, this does not appear to be deleterious. Indeed, the induction of Adhhs allows flies to survive exposure to ethanol. We have used this latter characteristic to select dominant, trans-acting mutations that alter the response of flies to heat shock.     

Evolution of Senescence: Longevity and the Expression of Heat Shock Proteins

Senescence is the progressive deterioration of organismal functionleading to accelerating rates of mortality. Cumulative extrinsicand intrinsic stresses are thought to contribute to senescence.Molecular chaperones, such as heat shock proteins, are hypothesizedto modulate senescence through their ability to mitigate proteindamage. Recent discoveries made with the nematode Caenorhabditiselegans and the fruit fly Drosophila melanogaster lend strongsupport to this theory. Longevity extending mutants of the nematodealso increase intrinsic and inducible thermotolerance, and theyoverexpress heat shock proteins upon thermal shock. Intriguingly,these genes regulate dauer (diapause) formation, and are associatedwith an insulin-like dependent signal transduction pathway.Direct evidence for a casual role of hsp70 in aging is providedby analysis of transgenic fruit flies. When hsp70 is inducedby mild heat shock, flies that overexpress the protein havegreatly reduced mortality rates during subsequent weeks of agingat normal temperatures. Current work with fruit flies focuseson the relationship between insulin-like receptors, ovariandiapause, heat shock and aging.     

Reproductive costs of heat shock protein in transgenic Drosophila melanogaster

Senescence may evolve when genes have antagonistic effects between early reproduction and later age-specific mortality. Although widely consistent with data of quantitative genetics, this model has yet to be validated with the identification of a specific locus presenting such trade-offs. The molecular chaperone hsp70 may be a candidate for such a gene. Heat induced expression of the Hsp70 protein in adults decreases rates of age-specific mortality during normal aging, while maternally experienced heat shock depresses the production of mature progeny. Here we show that maternal heat shock reduces the proportion of egg hatch but not the viability of successfully hatched offspring. To assess whether heat induced maternal expression of hsp70 causes reduced egg hatch, we measured the proportion of eggs that hatch from females engineered to overexpress hsp70 transgenes. We used the same transgenic strains that extend longevity upon hsp70 expression and found that Hsp70 is sufficient to suppress egg hatch. The proportion of egg hatch as a function of hsp70 expression was not reduced in the first eggs laid after maternal heat shock, but appears in later laid eggs, which were at preoogenic and early vitellogenic stages during the maternal expression of hsp70. The contervailing effects of hsp70 upon fecundity and subsequent age-specific mortality exemplify antagonistic pleiotropy, and this trade-off could contribute to the evolution of Drosophila senescence.     

Development of a heat shock inducible gfp transgenic zebrafish line by using the zebrafish hsp27 promoter

In the present study, a zebrafish hsp27 promoter was isolated and used to develop heat shock inducible gfp transgenic zebrafish. The endogenous hsp27 mRNAs were constitutively expressed from 4 hpf and increased in several regions of brain, heart and somites in early embryogenesis until 24 hpf. Subsequently, the expression was reduced significantly but maintained in the heart and ears. Heat shock induced hsp27 mRNAs in the blastoderm from 6 hpf and later in somites, branchial arches and several regions of brain. Similarly in hsp27-gfp transgenic zebrafish, constitutive GFP expression was observed from 11 hpf. GFP expression was mainly in the skin cells and increased to the peak level at 7 dpf, followed by a reduction. The constitutive GFP expression in the heart was initiated from 50 hpf and maintained even in the adult fish. After heat shock, GFP expression was mainly induced in the muscle in addition to a mild increase in the skin and heart. The early stages of the embryos were more sensitive than late stages as the time required for induced GFP expression in the muscle is shorter. Thus, the hsp27-gfp transgenic line generally recapitulates the expression pattern and heat shock inducibility of endogenous hsp27 RNAs. We also tested the potential of using the hsp27-gfp transgenic zebrafish embryos for heavy metal induction and demonstrated the inducibility of GFP expression by arsenic; this pattern of induction was also supported by examination of endogenous hsp27 mRNA.     

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.