We compared transgenic Drosophila larvae varying in hsp70 copy number to assess the consequences of Hsp70 overexpression for growth and development after heat shock. Exposure to a mildly elevated temperature (36 degrees C) induced expression of Hsp70 (and presumably other heat shock proteins) and improved tolerance of more severe heat stress, 38.5-39.5 degrees C. We examined this pattern in two independently derived pairs of extra-copy and excision strains that differed primarily in hsp70 copy number (with 22 and 10 copies, respectively). Extra-copy larvae produced more Hsp70 in response to high temperature than did excision larvae, but surpassed the excision strain in survival only immediately after thermal stress. Excision larvae survived to adulthood at higher proportions than did extra-copy larvae and grew more rapidly after thermal stress. Furthermore, multiple pretreatment reduced survival of 1st-instar extra-copy larvae, but did not affect the corresponding excision strain. While extra Hsp70 provides additional protection against the immediate damage from heat stress, abnormally high concentrations can decrease growth, development and survival to adulthood.
JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. British Ecological Society is collaborating with JSTOR to digitize, preserve and extend access to Functional Ecology. Summary 1. The costs of conditioning adult Drosophila melanogaster with a mild thermal stress that activates the genes for heat-shock proteins were examined by comparing the number of offspring produced by females maintained continuously at 25 'C with females exposed to a non-lethal stress, 36 'C for 75 min, once, twice or three times. The comparison was done under two nutritional treatments, with or without yeast added to the medium. 2. Benefits of conditioning adult D. melanogaster to thermal stress were examined by comparing survival after a severe stress (39 'C for 100 min) among flies that were not conditioned with those conditioned once, twice or three times by exposure to 36 'C for 75 min. Additional comparisons were made varying either the duration of conditioning or the time elapsed between conditioning and exposure to the severe stress. 3. Fewer offspring were produced by females receiving the conditioning treatment than for those not receiving it and the decrease in fecundity was greater for females conditioned more often. Proportional differences in fecundity were larger for the noyeast treatment than for females held with yeast. 4. Survival after the severe stress was much greater for flies that were conditioned than for those not conditioned and survival increased with increasing number of conditioning bouts. Survival also was greater for flies conditioned closer to the exposure to severe stress, with the exception that survival for flies conditioned only 2 or 4 h before exposure to severe stress was less than that for those conditioned 8 h before.
Heat shock proteins (Hsps) and other molecular chaperones perform diverse cellular roles (e.g., inducible thermotolerance) whose functional consequences are concentration dependent. We manipulated Hsp70 concentration quantitatively in intact larvae of Drosophila melanogaster to examine its effect on survival, developmental time and tissue damage after heat shock. Larvae of an extra-copy strain, which has 22 hsp70 copies, produced Hsp70 more rapidly and to higher concentrations than larvae of a control strain, which has the wild-type 10 copies of the gene. Increasing the magnitude and duration of pretreatment increased Hsp70 concentrations, improved tolerance of more severe stress, and reduced delays in development. Pretreatment, however, did not protect against acute tissue damage. For larvae provided a brief or mild intensity pretreatment, faster expression of Hsp70 in the extra-copy strain improved survival to adult and reduced tissue damage 21h after heat shock. Negative effects on survival ensued in extra-copy larvae pretreated most intensely, but their overexpression of Hsp70 did not increase tissue damage. Because rapid expression to yield a low Hsp70 concentration benefits larvae but overexpression harms them, natural selection may balance benefits and costs of high and low expression levels in natural populations.
Although Hsp70, the principal inducible heat-shock protein of Drosophila melanogaster, has received intense scrutiny in laboratory strains, its variation within natural populations and the consequences of such variation for thermotolerance are unknown. We have characterized variation in first-instar larvae of 20 isofemale lines isolated from a single natural population of D. melanogaster, in which larvae are prone to thermal stress in nature. Hsp70 expression varied more than twofold among lines after induction by exposure to 36°C for one hour, with an estimated proportion of the variation due to genetic differences of 0.24 ± 0.08. Thermotolerance with and without a Hsp70inducing pretreatment, survival at 25°C, and developmental time also varied significantly. As expected, expression of Hsp70 correlated positively with larval thermotolerance. By contrast, lines in which larval survival was high in the absence of heat stress showed lower than average Hsp70 expression and lower than average inducible thermotolerance. This conditional performance suggests an evolutionary trade-off between thermotolerance and the ability to produce higher concentrations of Hsp70, and survival in a benign environment.
Effects of thermal stress on survival and reproductive success in ten recently collected isofemale lines of Drosophila melanogaster were compared for flies treated as follows: always held at 25" C, placed in an incubator set at 37" C for 120 min, or exposed to 40" C in an incubator for 90 min, with or without previous exposure to 37' C. Short-term exposure to the higher temperature greatly reduced adult survival, the mating frequency of males and females, and female fecundity, which was measured as offspring produced over ten days. Male fertility, measured as the progeny produced by a female mated once, differed little among treatments. Previous exposure to a high, but non-lethal, temperature before exposure to the higher one, improved survival of males and females, and improved offspring production of females. Genetic variation was present among lines for offspring production, but genetic variation for survival was not significant, and genotype by environment interactions for fitness components of females were small. These results indicated low genetic variation in thermal resistance in the studied population, such that a threshold for temperature stress probably exists, above which local extinction is more likely than the evolution of resistance.
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