Irreversible aggregation of protein synthesis machinery after focal brain ischemia

Focal brain ischemia leads to a slow type of neuronal death in the penumbra that starts several hours after ischemia and continues to mature for days. During this maturation period, blood flow, cellular ATP and ionic homeostasis are gradually recovered in the penumbral region. In striking contrast, protein synthesis is irreversibly inhibited. This study used a rat focal brain ischemia model to investigate whether or not irreversible translational inhibition is due to abnormal aggregation of translational complex components, i.e. the ribosomes and their associated nascent polypeptides, protein synthesis initiation factors and co-translational chaperones. Under electron microscopy, most rosette-shaped polyribosomes were relatively evenly distributed in the cytoplasm of sham-operated control neurons, but clumped into large abnormal aggregates in penumbral neurons subjected to 2 h of focal ischemia followed by 4 h of reperfusion. The abnormal ribosomal protein aggregation lasted until the onset of delayed neuronal death at 24-48 h of reperfusion after ischemia. Biochemical study further suggested that translational complex components, including small ribosomal subunit protein 6 (S6), large subunit protein 28 (L28), eukaryotic initiation factors 2alpha, 4E and 3eta, and co-translational chaperone heat-shock cognate protein 70 (HSC70) and co-chaperone Hdj1, were all irreversibly clumped into large abnormal protein aggregates after ischemia. Translational complex components were also highly ubiquitinated. This study clearly demonstrates that focal ischemia leads to irreversible aggregation of protein synthesis machinery that contributes to neuronal death after focal brain ischemia.     

The methionine-rich low-molecular-weight chloroplast heat-shock protein: evolutionary conservation and accumulation in relation to thermotolerance

The evolutionary conservation of the low-molecular-weight chloroplast-localized heat-shock protein (LMW chlpHsp) in vascular plants was examined using immunological methods. An antibody (Abmet) specific to the LMW chlpHsp was produced using a synthetic 28-residue peptide containing the most conserved elements of its unique "methionine-rich domain" as an antigen. This antibody detected a heat-inducible low-molecular-weight chloroplast protein in plants of six divergent Anthophyta species, including C3, C4, CAM, monocot, and dicot species. Abmet also detected a LMW chlpHsp in species from the Divisions Psilotophyta, Equisetophyta, Polypodiophyta, and Ginkgophyta. A preliminary examination of the relationship between accumulation of the LMW chlpHsp and habitat was also conducted. Seven Anthophyta species originating from both warm- and cool-temperature habitats were grown at 28C and then heat stressed at 40C. A positive qualitative relationship between the accumulation of the LMW chlpHsp and organismal thermotolerance in these species was observed; similar results were obtained separately with four nonAnthophyta species. The strong evolutionary conservation of this LMW Hsp and its localization to the chloroplast, and the correlation between production of this protein and plant thermotolerance, suggest that the LMW chlpHsp plays an important role in adaptation to heat stress.     

The regulation and function of small heat-shock protein synthesis

The four small heat shock protein genes of Drosophila are tightly linked at the level of DNA, and are coordinately regulated. In cultured cell lines their expression is induced by high temprature shock and by physiological doses of ecdysterone. In vivo, small heat shock gene expression is developmentally regulated. Using recombinant DNA clones we have characterized and compared small hsp gene induction in response to the two independent stimuli.     

Natural thermal stress and heat-shock protein expression in Drosophila larvae and pupae

1. Whether Drosophila larvae and pupae naturally experience temperatures that can cause heat damage or death is poorly understood, but bears directly on numerous investigations of the thermal biology and heat-shock response in Drosophila . Accordingly, the temperatures of necrotic fruit, which Drosophila larvae and pupae inhabit, the temperatures of larvae and pupae outside the laboratory, and the levels of the heat-shock protein hsp 70 expressed by larvae in nature were examined.
2. When necrotic fruit was sunlit, internal temperatures rose to levels that can harm indwelling insects. Fruit size and evaporative water loss affected these temperatures. Temperatures of larvae and pupae in the field commonly exceeded 35 °C, with living larvae recorded at >44°C and pupae at >41°C. Natural mortality was evident, presumably because of heat.
3. In the laboratory, these temperatures kill larvae rapidly, with LT₅₀s (time taken for half the sample to be killed) of 30 min at 39 °C, 15 min at 40 °C and 8·5 min at 41 °C. Gradual transfer from 25°C to these temperatures resulted in no lesser mortality than did direct transfer.
4. Hsp 70 levels in lysates of whole larvae were measured by ELISA (enzyme-link immunosorbent assay) with an hsp 70-specific antibody. For larvae within necrotic apples experimentally transferred from shade to sun and within necrotic fruit in situ , hsp 70 levels equalled or exceeded levels detected in parallel laboratory studies of whole larvae or cells in culture.
5. These data provide an ecological context for studies of thermal stress and the heat-shock response in Drosophila that has heretofore been lacking.     

Gene expression during leaf development in Lolium temulentum: Patterns of protein synthesis in response to heat-shock and cold-shock

At an optimal growth temperature of 20°C, expending 4th leaves of Lolium temulentum L. synthesised a broad spectrum of polypeptides which altered with the maturity of the leaf tissue. Elevation of the temperature to 35°C, or above, induced synthesis of heat-shock proteins (hsp), and all parts of the 4th leaf were capable of this response. The threshold temperature for induction of hsp synthesis was little affected by the growth temperature (5 or 20°C). In contrast, a sudden 15–18°C decrease in temperature did not result in a marked alteration of protein synthesis patterns. It is concluded that in this species adaptation to rapid temperature reduction is not mediated by stress protein synthesis.     

Cell stress and implications of the heat-shock response in skin

Heat-shock proteins (HSPs), or so-called stress proteins may play an important role in cutaneous pathophysiology. HSPs are a group of highly conserved molecules that are expressed by all cells when subjected to heat or other forms of physical or chemical stress. The physiological roles of stress proteins are varied and are important in stress and nonstress conditions. They bind to other cellular proteins and participate in protein folding pathways during stress and also during the synthesis of new polypeptides. HSPs are also essential for thermotolerance and for prevention and repair of damage caused in DNA after ultraviolet exposure. Although HSPs are expressed in the skin in both epidermis and dermis, HSPs may influence many other cellular processes in the inflammatory and immune skin response. Many authors have speculated on a link between HSPs and human skin disease characterized by inflammation and proliferation.Abbreviations HSP heat-shock protein - IL-1 interleukin-1     

Characterization of a new high-temperature-induced 66-kDa heat-shock protein,antigenically related to heat-shock protein 72

M-14 human melanoma cells, following severe hyperthermic exposures, synthesized a heat-shock protein of 66 kDa (hsp 66), in addition to the major “classic” heat-shock proteins. This hsp 66 was not expressed following mild hyperthermic exposures sufficient to trigger the synthesis of the other heat-shock proteins. The induction of hsp 66 was observed also in Li human glioma cells treated at 45°C for 20 min. By contrast, hsp 66 was not induced in seven other human cell lines (both melanoma and nonmelanoma) when they were subjected to the same hyperthermic treatment. Immunological recognition experiments showed that hsp 66 cross-reacted with the inducible hsp 72, but not with the constitutive hsp 73. The possibility that hsp 66 is a breakdown product of hsp 72 was ruled out by the fact that Poly(A)⁺ RNA extracted from cells treated at 45°C for 20 min was able to direct the synthesis of hsp 66 (together with hsp 72) in a message-dependent rabbit reticulocyte lysate, as well as in microinjected Xenopus oocytes. By contrast, only the hsp 72 was expressed using Poly(A)⁺ RNA extracted from cells heated at 42°C for 1 h. Affinity chromatography experiments on ATP-agarose showed that hsp 66 did not bind ATP in vitro, hsp 66 was localized both in the cytoplasm (cytosol, mitochondria, and microsome fraction) and in the nuclei of cells recovered from a severe heat shock: this intracellular distribution closely corresponded to that of hsp 72. The nuclear-associated hsp 66 was found to be tightly bound to nuclear structures and could not be extracted by incubation in ATP-containing buffer. © 1996 Wiley-Liss, Inc.     

Enhanced tolerance to drought stress in transgenic rice plants overexpressing a small heat-shock protein,sHSP17.7

Exposure of rice (Oryza sativa L.) seedlings to a high temperature (42°C) for 24 h resulted in a significant increase in tolerance to drought stress. To try to determine the mechanisms of acquisition of tolerance to drought stress by heat shock, the rice small heat-shock protein gene, sHSP17.7, the product of which was shown to act as molecular chaperones in vitro and in vivo in our previous study, was overexpressed in the rice cultivar “Hoshinoyume”. Western and Northern blot analyses showed higher expression levels of sHSP17.7 protein in three transgenic lines than in one transgenic line. Drought tolerance was assessed in these transgenic lines and wild-type plants by withholding water for 6 days for evaluation of the ability of plants to continue growth after water-stress treatments. Although no significant difference was found in water potential of seedlings between transgenic lines and wild-type plants at the end of drought treatments, only transgenic seedlings with higher expression levels of sHSP17.7 protein could regrow after rewatering. Similar results were observed in survival rates after treatments with 30% polyethylene glycol (PEG) 3640 for 3 days. These results suggest that overproduction of sHSP17.7 could increase drought tolerance in transgenic rice seedlings.     

A small heat-shock protein confers stress tolerance and stabilizes thylakoid membrane proteins in cyanobacteria under oxidative stress

Small heat-shock proteins are molecular chaperones that bind and prevent aggregation of nonnative proteins. They also associate with membranes. In this study, we show that the small heat-shock protein HspA plays a protective role under oxidative stress in the cyanobacterium Synechococcus elongatus strain ECT16-1, which constitutively expresses HspA. Compared with the reference strain ECT, ECT16-1 showed much better growth and viability in the presence of hydrogen peroxide. Under the peroxide stress, pigments in thylakoid membrane, chlorophyll, carotenoids, and phycocyanins, were continuously reduced in ECT, but in ECT16-1 they decreased only during the first 24 h of stress; thereafter no further reduction was observed. For comparison, we analyzed a wild type and an hspA deletion strain from Synechocystis sp. PCC 6803 and found that lack of hspA significantly affected the viability of the cell and the pigment content in the presence of methyl viologen, suggesting that HspA stabilizes membrane proteins such as the photosystems and phycobilisomes from oxidative damage. In vitro pull down assays showed a direct interaction of HspA with components of phycobilisomes. These results show that HspA and small heat-shock proteins in general play an important role in the acclimation to oxidative stress in cyanobacteria. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Localization of the heat-shock protein Hsp70 to the synapse following hyperthermic stress in the brain

Heat-shock proteins are induced in response to cellular stress. Although heat-shock proteins are known to function in repair and protective mechanisms, their relationship to critical neural processes, such as synaptic function, has received little attention. Here we investigate whether the major heat-shock protein Hsp70 localizes to the synapse following a physiologically relevant increase in temperature in the mammalian nervous system. Our results indicate that hyperthermia-induced Hsp70 is associated with pre- and postsynaptic elements, including the postsynaptic density. The positioning of Hsp70 at the synapse could facilitate the repair of stress-induced damage to synaptic proteins and also contribute to neuroprotective events at the synapse.     

Induced thermotolerance and associated expression of the heat-shock protein Hsp70 in adult Drosophila melanogaster

1. Inducible heat-shock proteins are synthesized when temperatures are increased to levels substantially above normal. The functional role of these proteins is well known at the cellular level. Today increasing interest has been directed towards the importance of heat-shock proteins for resistance of whole organisms to high-temperature stress and other environmental stressors.
2. Here the functional relationship between the heat-shock protein, Hsp70, and thermal resistance in adult Drosophila melanogaster was examined by comparing thermal resistance, i.e. survival at 39 °C for 85 min, and levels of Hsp70 at various times elapsed (2, 4, 8, 16, 32 and 64 h) after thermotolerance was induced by short-term acclimation/heat hardening at 37 °C for 55 min.
3. Levels of Hsp70 in both males and females were highest 2 h after heat hardening and declined with longer times elapsed. The rate of decrease initially was very fast but diminished with increasing time. After 32 h the level of Hsp70 approached the level in flies that were not hardened. Levels of Hsp70 in males exceeded that of females during the entire period.
4. Survival of both sexes increased with increasing time after heat hardening and reached an optimum between 8 and 32 h. Thereafter resistance decreased with longer times elapsed. Survival of females generally exceeded that of males except after 16 and 64 h.
5. Regression analysis applied to the data on Hsp70 levels revealed that the model describing these data could not explain the data for survival. Also, higher levels of Hsp70 in males compared with females were not associated with greater survival in males. However, statistical analysis on paired measurements of Hsp70 and survival revealed a positive association between Hsp70 level and survival at each time elapsed after induction of thermotolerance.     

The mitochondrial small heat-shock protein protects NADH:ubiquinone oxidoreductase of the electron transport chain during heat stress in plants

Functional inactivation of the mitochondrial small heat-shock protein (lmw Hsp) in submitochondrial vesicles using protein-specific antibodies indicated that this protein protects NADH:ubiquinone oxidoreductase (complex I), and consequently electron transport from complex I to cytochrome c:O₂ oxidoreductase (complex IV). Lmw Hsp function completely accounted for heat acclimation of complex I electron transport in pre-heat-stressed plants. Addition of purified lmw Hsp to submitochondrial vesicles lacking this Hsp increased complex I electron transport rates 100% in submitochondrial vesicles assayed at high temperatures. These results indicate that production of the mitochondrial lmw Hsp is an important adaptation to heat stress in plants.     

Small heat-shock proteins function in the insoluble protein complex

Small heat-shock proteins (sHSPs) represent an abundant and ubiquitous family of molecular chaperones. The current model proposes that sHSPs function to prevent irreversible aggregation of non-native proteins by forming soluble complex. The chaperone activity of sHSPs is usually determined by the capacity to suppress thermally or chemically induced protein aggregation. However, sHSPs were frequently found in the insoluble complex particularly in vivo. In this report, it is clearly revealed that the insoluble sHSP/substrate complex is formed when sHSP is overloaded with non-native substrates, which is the very case under in vivo conditions. The proposal that sHSPs function to prevent the protein aggregation seems misleading. sHSPs appear to promote the elimination of protein aggregates by incorporating into the insoluble protein complex.     

Enhanced phosphorylation of a 65 kDa protein is associated with rapid induction of stress proteins in 9L rat brain tumor cells

Induction of heat-shock proteins and glucose-regulated proteins in 9L rat brain tumor cells can be differentially elicited by sodium arsenite, cadmium chloride, zinc chloride, copper sulfate, sodium fluoride, and L-azetidine-2-carboxylic acid. The kinds of stress protein induced by the above chemicals varied considerably, mainly determined by the nature and the concentration of the chemicals, as well as the treatment protocols. In addition, at the concentrations where stress proteins can be induced, the above chemicals were able to suppress general protein synthesis and were cytotoxic. Enhanced phosphorylation of a protein with an apparent molecular weight of 65 kDa was detected during the induction of stress proteins except in azetidine treatments during which uptake of phosphate by the cells was impaired after prolonged incubation. The phosphate moiety on the 65 kDa phosphoprotein appeared to be alkaline-stable and two-dimensional gel electrophoresis revealed that the phosphoprotein resolved into four isoforms with isoelectric points ranging from 5.1 to 5.6. Enhanced phosphorylation of the same protein was also detected in heat-shocked and withangulatin A-treated 9L cells in which stress proteins were induced. It is suggested that this phosphoprotein may be a common target for heat stress response-stimulated phosphorylation and important in the further metabolic responses of the cell to stress. © 1993 Wiley-Liss, Inc.     

Reaction of small heat-shock proteins to different kinds of cellular stress in cultured rat hippocampal neurons

Upregulation of small heat-shock proteins (sHsps) in response to cellular stress is one mechanism to increase cell viability. We previously described that cultured rat hippocampal neurons express five of the 11 family members but only upregulate two of them (HspB1 and HspB5) at the protein level after heat stress. Since neurons have to cope with many other pathological conditions, we investigated in this study the expression of all five expressed sHsps on mRNA and protein level after sublethal sodium arsenite and oxidative and hyperosmotic stress. Under all three conditions, HspB1, HspB5, HspB6, and HspB8 but not HspB11 were consistently upregulated but showed differences in the time course of upregulation. The increase of sHsps always occurred earlier on mRNA level compared with protein levels. We conclude from our data that these four upregulated sHsps (HspB1, HspB5, HspB6, HspB8) act together in different proportions in the protection of neurons from various stress conditions.     

Cloning and molecular characterization of a strawberry fruit ripening-related cDNA corresponding a mRNA for a low-molecular-weight heat-shock protein

We have isolated and characterized a cDNA from a strawberry fruit subtractive library that shows homology to class-I low-molecular-weight (LMW) heat-shock protein genes from other higher plants. The strawberry cDNA (clone njjs4) was a 779 bp full-length cDNA with a single open reading frame of 468 bp that is expected to encode a protein of ca. 17.4 kDa with a pI of 6.57. Southern analysis with genomic DNA showed several high-molecular-weight hybridization bands, indicating that the corresponding njjs4 gene is not present as a single copy in the genome. This strawberry gene was not expressed in roots, leaves, flowers and stolons but in fruits at specific stages of elongation and ripening. However, a differential pattern of mRNA expression was detected in the fruit tissues achenes and receptacle. The njjs4 gene expression increased in achenes accompanying the process of seed maturation whereas in the receptacle, a high mRNA expression was detected in the W2 stage, during which most of the metabolic changes leading to the fruit ripening are occurring. Our results clearly show a specific relationship of this njjs4 strawberry gene with the processes of seed maturation and fruit ripening, and strongly support that at least some of the class-I LMW heat-shock protein-like genes have a heat-stress-independent role in plant development, including fruit ripening.     

The protein import machinery of the mitochondrial membranes

Mitochondria are surrounded by two membranes that contain independent and non-related protein transport machineries. Remarkable progress was recently achieved in elucidating the structure of the outer membrane import channel and in the identification of new components involved in protein traffic across the intermembrane space and the inner membrane. Traditional concepts of protein targeting and sorting had to be revised. Here we briefly summarize the data on the mitochondrial protein import system with particular emphasis on new developments and perspectives.