Hsp70 and larval thermotolerance in Drosophila melanogaster: how much is enough and when is more too much?

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.     

Hsp70 and thermal pretreatment mitigate developmental damage caused by mitotic poisons in Drosophila

To assess the ability of the heat-inducible molecular chaperone heat-shock protein 70 (Hsp70) to mitigate a specific developmental lesion, we administered the antimicrotubule drugs vinblastine (VB) and colchicine (COL) to larvae of Drosophila engineered to express differing levels of Hsp70 after heat pretreatment (HP). VB and COL decreased survival during metamorphosis, disrupted development of the adult eye and other structures as well as their precursor imaginal disks, and induced chromosome nondisjunction in the wing imaginal disk as indicated by the somatic mutation and recombination test (SMART) assay. Hsp70-inducing HP reduced many of these effects. For the traits viability, adult eye morphology, eye imaginal disk morphology, cell death in the eye imaginal disks, and single and total mutant clone formation in the SMART assay, HP reduced the impact of VB to a greater extent in Drosophila with 6 hsp70 transgenes than in a sister strain from which the transgenes had been excised. Because the extra-copy strain has higher levels of Hsp70 than does the excision strain but is otherwise almost identical in genetic background to the excision strain, these outcomes are attributable to Hsp70. The hsp70 copy number had a variable interaction with HP and COL administration.     

Antioxidant responses of Chilo suppressalis (Lepidoptera: Pyralidae) larvae exposed to thermal stress

High temperatures cause a variety of physiological stress responses in insects, including increased generation of reactive oxygen species (ROS), which can cause oxidative damage. This study investigated the effects of thermal stress on ROS generation, the expression of heat shock protein 70 (Hsp70) at the mRNA and protein levels, the activity of antioxidant enzymes (SOD, CAT), and apoptosis in hemocytes of Chilo suppressalis larvae. Results indicated that thermal stress significantly elevated the level of ROS and antioxidant enzyme activity in C. suppressalis larvae. Real-time quantitative PCR showed that hsp70 gene expression was induced by heat stress. Flow cytometric results revealed that the expression profile of Hsp70 at the protein level was in agreement with that at the mRNA level. The expression of Hsp70 at both the mRNA and protein levels reached a maximum at 36 °C in larval hemocytes. Exposure to tested temperatures did not cause any significant change in the rate of apoptosis in larval hemocytes. These results suggest that thermal stress leads to oxidative stress and that antioxidant enzymes and the Hsp70 play an important role in reducing oxidative damage in C. suppressalis larvae.     

Dropping like flies: environmentally induced impairment and protection of locomotor performance in adult Drosophila melanogaster

In Drosophila, heat shock (HS) during the pupal stage chronically hinders adult locomotor performance by disrupting wing development and cellular and/or tissue-level mechanisms that support walking and flight. Furthermore, heat pretreatment (PT) protects locomotor function against these disruptions. HS flies with abnormal wings were less able to alter trajectory in free fall relative to control, PT-only, and PT+HS wild-type flies. This deficit was less severe but still present in HS-only flies with wild-type wings. Transgenic increases in the copies of genes encoding the major inducible heat-shock protein of Drosophila melanogaster, Hsp70, also protected walking ability from disruption due to pupal HS. Walking velocity did not differ between excision (five natural hsp70 copies) and extra-copy (five natural and six transgenic hsp70 copies) flies in the control, PT, and PT+HS groups, nor did velocity vary among these thermal treatment groups. HS dramatically reduced walking velocity, however, but this effect occurred primarily in the excision flies. These results suggest that Hsp70 and other mechanisms protect against heat-induced locomotor impairment.     

Natural hyperthermia and expression of the heat shock protein Hsp70 affect developmental abnormalities in Drosophila melanogaster

We demonstrate that natural heat stress on wild larval Drosophila melanogaster results in severe developmental defects in >10% of eclosing adults, and that increased copy number of the gene encoding the major inducible heat shock protein of D. melanogaster, Hsp70, is sufficient to reduce the incidence of such abnormalities. Specifically, non-adult D. melanogaster inhabiting necrotic fruit experienced severe, often lethal heat stress in natural settings. Adult flies eclosing from wild larvae that had survived natural heat stress exhibited severe developmental anomalies of wing and abdominal morphology, which should dramatically affect fitness. The frequency of developmental abnormalities varied along two independent natural thermal gradients, exceeding 10% in adults eclosing from larvae developing in warm, sunlit fruit. When exposed to natural heat stress, D. melanogaster larvae with the wild-type number of hsp70 genes (n=10) developed abnormal wings significantly more frequently than a transgenic sister strain with 22 copies of the hsp70 gene. Received: 19 April 1999 / Accepted: 16 July 1999     

Thermal biology of horseshoe crab embryos and larvae: A role for heat shock proteins

Eggs of the American horseshoe crab, Limulus polyphemus L., develop on sandy estuarine beaches during the spring and summer, and are potentially vulnerable to thermal stress during the 3-4 weeks of development to the first instar (trilobite) larval stage. In many marine taxa, heat shock (stress) proteins (Hsp's) help individuals acclimate to stresses by restoring the proper folding of cellular proteins whose shape has been altered by temperature shock or other forms of environmental stress. We examined the survival of embryos and first instar (trilobite) larvae following heat shock, and compared the levels of Hsp70 in heat shocked and control animals. Animals acclimated to 13 or 22 °C had close to 100% survival when heat shocked for 3 h at 35 or 40 °C, but exposure to 45 °C for 3 h was lethal. To study the effect of heat shock on Hsp70 production under environmentally realistic conditions, animals were acclimated to either 13 or 22 °C, heat-shocked at 35 °C for 3 h, and soluble proteins were extracted following 0, 2, 4, or 6 h recovery at 22 °C. The relative amounts of Hsp70 in horseshoe crab embryos and larvae were examined using SDS-PAGE and Western blotting. Relative to controls animals held at a constant temperature, there was a slight elevation of Hsp70 only among heat shocked trilobite larvae in the 6 h recovery treatment. Hsp70 levels did not differ significantly between control and heat shocked embryos. Horseshoe crabs have adapted to living in a thermally stressful environment by maintaining a high baseline (constitutive) level of cellular stress proteins such as Hsp70, rather than by synthesizing inducible Hsp's when stressful temperatures are encountered. This may be an effective strategy given that the heat shocks encountered by intertidal embryos and larvae occur regularly as a function of diurnal and tidal temperature changes.     

Natural and Genetic Engineering of the Heat-Shock Protein Hsp70 in Drosophila melanogaster: Consequences for Thermotolerance

SYNOPSIS. Larvae of the fruit fly, Drosophila melanogaster,live within necrotic fruit, a challenging environment in whichlarvae can experience severe thermal stress. One response tothermal stress, the expression of heat-shock proteins (Hsps),has evolved distinctively in this species; the gene encodingHsp70 has undergone extensive duplication and accounts for thebulk of Hsps that are expressed upon heat shock. Genetic engineeringof hsp70 copy number is sufficient to affect thermotoleranceat some (but not all) life stages. Increases in Hsp70, moreover,can protect intact larvae against thermal inactivation of theenzyme alcohol dehydrogenase and thermal inhibition of feeding.Deleterious consequences of high levels of Hsp70, however, maylimit further evolutionary proliferation of hsp70 genes. Thesefindings illustrate how the perspectives of integrative andcomparative biology, if applied to even well-studied model organisms,can lead to novel findings.     

HERITABILITY OF EXPRESSION OF THE 70KD HEAT-SHOCK PROTEIN IN DROSOPHILA MELANOGASTER AND ITS RELEVANCE TO THE EVOLUTION OF THERMOTOLERANCE

The principle inducible heat-shock protein of Drosophila melanogaster, Hsp70, contributes to thermotolerance throughout the entire life cycle of the species but may also reduce fitness in some life stages. In principle, selection might maximize the benefits of Hsp70 expression relative to its costs by adjusting the magnitude of Hsp70 expression for each life-cycle stage independently. Therefore we examined whether the magnitude of Hsp70 expression varied during the life cycle and the relationship of this variation to several life-history traits. For 28 isofemale lines derived from a single natural population, estimates of heritable variation in Hsp70 expression ranged between 0.25 and 0.49, and the association among variation in first- and third-instar larvae and in adults correlated highly. Thus, Hsp70 expression is genetically coupled at these developmental stages. A line engineered with extra copies of the hsp70 gene produced more Hsp70 and survived heat shock much better than did a control strain. Among natural lines, Hsp70 expression was only weakly related to tolerance of heat shock and to larva-to-adult survival and developmental time at permissive temperatures. Additionally, lines with high adult survival developed slowly as larvae, which is a possible trade-off. These and other findings suggest that trade-offs may maintain quantitative variation both in heat-shock protein expression and in life-history traits that associate with thermotolerance.     

Quantitative evidence that both Hsc70 and Hsp70 contribute to thermal adaptation in hybrids of the livebearing fishes Poeciliopsis

The 70-kilodalton heat shock protein family is composed of both environmentally inducible (Hsp) and constitutively expressed (Hsc) family members. While the role of the constitutively expressed stress proteins in thermotolerance is largely unknown, de novo expression stress proteins in response to elevated temperatures has been associated with increased thermotolerance in many cell lines, developing embryos and adult organisms. Distinct, hemiclonal hybrids between the livebearing fish species Poeciliopsis monacha and P. lucida varied in their abilities to survive temperature stress, with survival being greatest when rates of temperature increase to 40°C were slowest and when P. monacha genomes were combined with a sympatric P. lucida genome. Quantification of Hsp70 under heat shock conditions and Hsc70 under normal physiological conditions indicated that variation in survival among hemiclones was best explained by the combined effects of these two proteins. Similar complex interactions between maternal and paternal genomes and rate of temperature increase were found to underline patterns of survival, Hsp70 accumulation and Hsc70 abundance. These data suggest that the relationship between Hsps and thermotolerance is more intricate than previously thought and that Hsps contribute to thermal adaptation in these fishes through genetic interactions specific to particular environments.     

Heat-preconditioning confers protection from Ca2+-mediated cell toxicity in renal tubular epithelial cells (BSC-1)

A rise in intracellular calcium may mediate ischemic damage by phospholipid hydrolysis and proteolysis Heat shock proteins have been shown to provide protection from various forms of cell stress, but not from models of Ca²⁺-mediated injury. The effect of heat preconditioning in a model of ionomycin-induced injury in cultured renal tubular epitheliaal cells (BSC-1) was examined. Hsp70-mRNA expression was induced by hyperthermia (HT) (42°C, 60 min). Hsp70 protein accumulation was maximal after 12–18 h and returned to baseline levels by 96 h. Treatment of BSC-1 cells with ionomycin (7.0 µM) produced lethal cell injury characterized by LDH release. Cells examined at 18 h after HT were significantly less damaged than cells studied at 96 h after HT. Our data are the first to demonstrate that heat preconditioning confers protection from Ca²⁺-mediated cell injury. The state of increased tolerance is transient and closely parallels kinetics of Hsp70 expression.     

Heat Shock Response in the Thermophilic Enteric Yeast Arxiozyma telluris

Heat stress tolerance was examined in the thermophilic enteric yeast Arxiozyma telluris. Heat shock acquisition of thermotolerance and synthesis of heat shock proteins hsp 104, hsp 90, hsp 70, and hsp 60 were induced by a mild heat shock at temperatures from 35 to 40°C for 30 min. The results demonstrate that a yeast which occupies a specialized ecological niche exhibits a typical heat shock response.     

The effects of heat shock and acclimation temperature on hsp70 and hsp30 mRNA expression in rainbow trout: in vivo and in vitro comparisons

Heat shock (25° C) of 10° C-acclimated rainbow trout Oncorhynchus mykiss led to increases in heat shock protein 70 (hsp70) mRNA in blood, brain, heart, liver, red and white muscle, with levels in blood being amongst the highest. Hsp30 mRNA also increased with heat shock in all tissues with the exception of blood. When rainbow trout blood was heat shocked in vitro , both hsp70 and hsp30 mRNA increased significantly. In addition, these in vitro experiments demonstrated that blood from fish acclimated to 17° C water had a lower hsp70 mRNA heat shock induction temperature than did 5° C acclimated fish (20 v. 25° C). The hsp30 mRNA induction temperature (25° C), however, was unaffected by thermal acclimation. While increases in hsp70 mRNA levels in blood may serve as an early indicator of temperature stress in fish, tissue type, thermal history and the particular family of hsp must be considered when evaluating stress by these molecular means.     

Heat Shock Proteins and Their mRNAs in Dry and Early Imbibing Embryos of Wheat

Two-dimensional gels of in vitro translation products of mRNAs isolated from quiescent wheat (Triticum aestivum) embryos demonstrate the presence of mRNAs encoding heat shock proteins (hsps). There were no detectable differences in the mRNAs found in mature embryos from field grown, from 25°C growth chamber cultivated, or from plants given 38°C heat stresses at different stages of seed development. The mRNAs encoding several developmentally dependent (dd) hsps were among those found in the dry embryos. Stained two-dimensional gels of proteins extracted from 25°C growth chamber cultivated wheat embryos demonstrated the presence of hsps, including dd hsps. A study of the relationship of preexisting hsp mRNAs and the heat shock response during early imbibition was undertaken. Heat shocks (42°C, 90 minutes) were administered following 1.5, 16, and 24 hours of 25°C imbibition. While the mRNAs encoding the low molecular weight hsps decayed rapidly upon imbibition, the mRNAs for dd hsps persisted longer and were still detectable following 16 hours of imbibition. After 1.5 hours of imbibition, the mRNAs for the dd hsps did not accumulate in response to heat shock, even though the synthesis of the proteins was enhanced. Thus, an applied heat shock appeared to lead to the preferential translation of preexisting dd hsp mRNAs. The mRNAs for the other hsps, except hsp 70, were newly transcribed at all of the imbibition times examined. The behavior of the hsp 70 group of proteins during early imbibition was examined by RNA gel blot analysis. The mRNAs for the hsp 70 group were detectable at moderate levels in the quiescent embryo. The relative level of hsp 70 mRNA increased after the onset of imbibition at 25°C and remained high through 25.5 hours of prior imbibition. The maximal levels of these mRNAs at 25°C was reached at 17.5 hours of imbibition. Heat shock caused modest additional accumulation of hsp70 mRNA at later imbibition times.     

Geographic variation in thermal tolerance and strategies of heat shock protein expression in the land snail <Emphasis Type="Italic">Theba pisana</Emphasis> in relation to genetic structure

Land snails are exposed to conditions of high ambient temperature and low humidity, and their survival depends on a suite of morphological, behavioral, physiological, and molecular adaptations to the specific microhabitat. We tested in six populations of the land snail Theba pisana whether adaptations to different habitats affect their ability to cope with thermal stress and their strategies of heat shock protein (HSP) expression. Levels of Hsp70 and Hsp90 in the foot tissue were measured in field-collected snails and after acclimation to laboratory conditions. Snails were also exposed to various temperatures (32 up to 54 °C) for 2 h and HSP messenger RNA (mRNA) levels were measured in the foot tissue and survival was determined. To test whether the physiological and molecular data are related to genetic parameters, we analyzed T. pisana populations using partial sequences of nuclear and mitochondrial DNA ribosomal RNA genes. We show that populations collected from warmer habitats were more thermotolerant and had higher constitutive levels of Hsp70 isoforms in the foot tissue. Quantitative real-time polymerase chain reaction (PCR) analysis indicated that hsp70 and hsp90 mRNA levels increased significantly in response to thermal stress, although the increase in hsp70 mRNA was larger compared to hsp90 and its induction continued up to higher temperatures. Generally, warm-adapted populations had higher temperatures of maximal induction of hsp70 mRNA synthesis and higher upper thermal limits to HSP mRNA synthesis. Our study suggests that Hsp70 in the foot tissue of T. pisana snails may have important roles in determining stress resistance, while Hsp90 is more likely implicated in signal transduction processes that are activated by stress. In the phylogenetic analysis, T. pisana haplotypes were principally divided into two major clades largely corresponding to the physiological ability to withstand stress, thus pointing to genetically fixed tolerance.     

Potentiation of heat stress-induced hsp70 expression in vivo by aspirin

Studies in cultured cells have demonstrated that non-steroidal anti-inflammatory agents can potentiate heat-induced hsp70 expression through activation of HSF1 to a DNA binding state. We investigated the influence of aspirin on hsp70 expression in intact rats subjected to heat stress. Rats were injected intraperitoneally either with aspirin (100 mg/kg) or vehicle alone, 60 min prior to their placement at 37°C or room temperature for 30 min. hsp70 mRNA expression was analyzed in lung, liver and kidney isolated from animals assigned to one of four different treatment paradigms; untreated controls, heat aspirin, and aspirin-plus-heat. Comparison of hsp70 expression in the treatment groups revealed that in all tissues examined, aspirin-plus-heat treatment resulted in 3–4 fold higher levels of hsp70 mRNA relative to those seen with heat treatment alone. Little or no hsp70 mRNA expression was detected in the unheated groups, regardless of aspirin treatment. In keeping with the mRNA expression, Hsp70 protein levels were also elevated in aspirin-plus-heat treated animals. Aspirin treatment did not alter hsp70 protein expression in the absence of heat. In contrast to in vitro observations, aspirin treatment in vivo did not alter HSF1 DNA binding properties. Core body temperature measurements revealed that aspirin pretreatment enhanced the rise in body temperature seen in response to heat treatment. This increased hyperthermic response to heat stress probably accounts for the potentiation of hsp70 expression observed in aspirin-plus-heat treated rats. Given the widespread use of aspirin in humans within a dose range comparable to that used here, our findings are likely to have important physiological consequences.     

温室粉虱和烟粉虱3个隐种中热激蛋白基因hsp70和hsp90含量的比较分析

【目的】昆虫适应新环境的能力与其对温度的耐受能力密切相关。热激蛋白HSP70和HSP90具有提高生物体温度耐受性的功能。烟粉虱Bemisia tabaci (Gennadius)不同隐种和不同种粉虱对温度的适应能力有差异,这与它们的热激蛋白基因拷贝数的差异可能相关。【方法】利用实时荧光定量PCR方法,检测入侵型烟粉虱MED隐种和MEAM1隐种、本地型烟粉虱AsiaⅡ1隐种以及温室粉虱Trialeurodes vaporariorum (Westwood)基因组DNA中热激蛋白基因hsp70和hsp90的拷贝数。【结果】不同种类的粉虱和烟粉虱不同隐种体内的hsp70和hsp90的含量均有较大差异,其中hsp70和hsp90拷贝数在入侵型烟粉虱MED和MEAM1隐种中含量较其他两种均高,而在土著种AsiaⅡ1隐种中含量最低,在温室粉虱中居中。此外,相同物种雌雄成虫hsp70和hsp90的拷贝数也不同,雌虫hsp70和hsp90拷贝数约为雄虫的2倍。【结论】不同种粉虱及烟粉虱不同隐种的hsp70和hsp90的拷贝数可能与其耐热性差异相关。本研究为解释不同种粉虱、烟粉虱不同隐种及其不同性别的耐热性差异机制提供了进一步的依据。