The evolutionary and ecological role of heat shock proteins

Most heat shock proteins (Hsp) function as molecular chaperones that help organisms to cope with stress of both an internal and external nature. Here, we review the recent evidence of the relationship between stress resistance and inducible Hsp expression, including a characterization of factors that induce the heat shock response and a discussion of the associated costs. We report on studies of stress resistance including mild stress, effects of high larval densities, inbreeding and age on Hsp expression, as well as on natural variation in the expression of Hsps. The relationship between Hsps and life history traits is discussed with special emphasis on the ecological and evolutionary relevance of Hsps. It is known that up‐regulation of the Hsps is a common cellular response to increased levels of non‐native proteins that facilitates correct protein folding/refolding or degradation of non‐functional proteins. However, we also suggest that the expression level of Hsp in each species and population is a balance between benefits and costs, i.e. a negative impact on growth, development rate and fertility as a result of overexpression of Hsps. To date, investigations have focused primarily on the Hsp70 family. There is evidence that representatives of this Hsp family and other molecular chaperones play significant roles in relation to stress resistance. Future studies including genomic and proteonomic analyses will increase our understanding of molecular chaperones in stress research.     

The evolution of heat shock genes and expression patterns of heat shock proteins in the species from temperature contrasting habitats

Heat shock genes are the most evolutionarily ancient among the systems responsible for adaptation of organisms to a harsh environment. The encoded proteins (heat shock proteins, Hsps) represent the most important factors of adaptation to adverse environmental conditions. They serve as molecular chaperones, providing protein folding and preventing aggregation of damaged cellular proteins. Structural analysis of the heat shock genes in individuals from both phylogenetically close and very distant taxa made it possible to reveal the basic trends of the heat shock gene organization in the context of adaptation to extreme conditions. Using different model objects and nonmodel species from natural populations, it was demonstrated that modulation of the Hsps expression during adaptation to different environmental conditions could be achieved by changing the number and structural organization of heat shock genes in the genome, as well as the structure of their promoters. It was demonstrated that thermotolerant species were usually characterized by elevated levels of Hsps under normal temperature or by the increase in the synthesis of these proteins in response to heat shock. Analysis of the heat shock genes in phylogenetically distant organisms is of great interest because, on one hand, it contributes to the understanding of the molecular mechanisms of evolution of adaptogenes and, on the other hand, sheds the light on the role of different Hsps families in the development of thermotolerance and the resistance to other stress factors.     

Stress modulation of cellular metabolic sensors: interaction of stress from temperature and rainfall on the intertidal limpet Cellana toreuma

In the natural environment, organisms are exposed to large variations in physical conditions. Quantifying such physiological responses is, however, often performed in laboratory acclimation studies, in which usually only a single factor is varied. In contrast, field acclimatization may expose organisms to concurrent changes in several environmental variables. The interactions of these factors may have strong effects on organismal function. In particular, rare events that occur stochastically and have relatively short duration may have strong effects. The present experiments studied levels of expression of several genes associated with cellular stress and metabolic regulation in a field population of limpet Cellana toreuma that encountered a wide range of temperatures plus periodic rain events. Physiological responses to these variable conditions were quantified by measuring levels of mRNA of genes encoding heat‐shock proteins (Hsps) and metabolic sensors (AMPKs and Sirtuin 1). Our results reveal high ratios of individuals in upregulation group of stress‐related gene expression at high temperature and rainy days, indicating the occurrence of stress from both prevailing high summer temperatures and occasional rainfall during periods of emersion. At high temperature, stress due to exposure to rainfall may be more challenging than heat stress alone. The highly variable physiological performances of limpets in their natural habitats indicate the possible differences in capability for physiological regulation among individuals. Our results emphasize the importance of studies of field acclimatization in unravelling the effects of environmental change on organisms, notably in the context of multiple changes in abiotic factors that are accompanying global change.     

Heat shock proteins in toxicology: How close and how far?

The response to stress triggers activation of the genes involved in cell survival and/or cell death. Stress response is a ubiquitous feature of cells that is induced under stress conditions. As a part of this response a set of genes called stress genes are induced to synthesize a group of proteins called heat shock proteins (Hsps). The Hsps play an essential role as molecular chaperones by assisting the correct folding of nascent and stress-accumulated misfolded proteins, and by preventing their aggregation. Because of their sensitivity to even minor assaults, Hsps are suitable as an early warning bio-indicator of cellular hazard. Despite having enormous use in toxicology, the current state of knowledge in defining a mechanism of action or accurately predicting toxicity based on stress gene expression warrants further investigation. The goal of this review is to summarize current developments in the application of stress genes and their products ‘Hsps’ in toxicology with a brief discussion of the caveats. While focusing on hsp70 because of its higher conservation across the taxa and since it is one of the first to be induced under stress conditions, we will also discuss other members of the stress gene family.     

Phototransduction genes are up-regulated in a global gene expression study of Drosophila melanogaster selected for heat resistance

The genetic architecture underlying heat resistance remains partly unclear despite the well-documented involvement of heat shock proteins (Hsps). It was previously shown that factors besides Hsps are likely to play an important role for heat resistance. In this study, gene expression arrays were used to make replicate measurements of gene expression before and up to 64 hours after a mild heat stress treatment, in flies selected for heat resistance and unselected control flies, to identify genes differentially expressed in heat resistance-selected flies. We found 108 genes up-regulated and 10 down-regulated using the Affymetrix gene expression platform. Among the up-regulated genes, a substantial number are involved in the phototransduction process. Another group of genes up-regulated in selected flies is characterized by also responding to heat shock treatment several hours after peak induction of known Hsps revert to nonstress levels. These findings suggest phototransduction genes to be critically involved in heat resistance, and support a role for components of the phototransduction process in stress-sensing mechanisms. In addition, the results suggest yet-uncharacterized genes responding to heat stress several hours after treatment to be involved in heat stress resistance. These findings mark an important increase in the understanding of heat resistance.     

棉花粉蚧热休克蛋白基因的鉴定

热休克蛋白(heat shock proteins,Hsps)是生物体或细胞受到热胁迫后新合成的一类遗传上高度保守的蛋白,在昆虫应对外界环境因子胁迫时起着重要作用。为了系统研究棉花粉蚧Phenacoccus solenopsis Hsp基因家族,对棉花粉蚧转录组基因注释信息进行分析、获得目标序列,并应用NCBI上Blast X等软件进行比对、共鉴定出24条热激蛋白(Hsp)基因,包括3个Hsp90、8个Hsp70、2个Hsp60和11个s Hsp(small heat shock protein,s Hsp)基因。对棉花粉蚧与模式昆虫家蚕Bombyx mori、黑腹果蝇Drosophila melanogaster、赤拟谷盗Tribolium castaneum系统进化关系分析显示,昆虫的小分子量热休克蛋白s Hsp具有很强的种属特异性,Hsp70家族的保守性比s Hsp强。棉花粉蚧热激蛋白基因的鉴定为深入研究该虫Hsp与生长发育、抗逆境的相互关系奠定了基础。     

Biochemical and biophysical characterization of small heat shock proteins from sugarcane. Involvement of a specific region located at the N-terminus with substrate specificity

When cells are submitted to an increase in temperature, heat shock proteins (Hsp) are synthesized to help heat stress resistance. Small Hsps, which are diverse and abundant in plants, have the major function of preventing irreversible protein aggregation. The diversity of small Hsps in plants is intriguing and characterization of their chaperone activity is important to understand plant tolerance to heat stress. A previous study showed that small Hsps, mainly represented by class I (cytosolic), correspond to about 5% of all sugarcane Expressed Sequencing Tags belonging to the molecular chaperone category. Here, we present biochemical and biophysical characterization of two sugarcane small Hsps from class I, which were named SsHsp17.2 and SsHsp17.9 according to their monomer molecular mass of 17.2 and 17.9 kDa, respectively. The recombinant proteins have identity of about 75% to each other and similar structural characteristics. However, their stability and their chaperone activity were not equivalent: SsHsp17.9 was more efficient in protecting citrate synthase and malate dehydrogenase from aggregation whereas SsHsp17.2 was more efficient in protecting luciferase from aggregation. There is only one region, which is located at the N-terminus, of low homology between these two proteins. Based on that and on previous works pointing to multiple sites, mainly at the N-terminus, involved with substrate specificity in small Hsps, we suggest that this specific region is one of these sites. In addition, this is the first report on the chaperone activity of sugarcane small Hsps.     

A step towards understanding plant responses to multiple environmental stresses: a genome‐wide study

In natural habitats, especially in arid areas, plants are often simultaneously exposed to multiple abiotic stresses, such as salt, osmotic and heat stresses. However, most analyses of gene expression in stress responses examine individual stresses. In this report, we compare gene expression in individual and combined stresses. We show that combined stress treatments with salt, mannitol and heat induce a unique pattern of gene expression that is not a simple merge of the individual stress responses. Under multiple stress conditions, expression of most heat and salt stress‐responsive genes increased to levels similar to or higher than those measured in single stress conditions, but osmotic stress‐responsive genes increased to lower levels. Genes up‐regulated to higher levels under multiple stress condition than single stress conditions include genes for heat shock proteins, heat shock regulators and late embryogenesis abundant proteins (LEAs), which protect other proteins from damage caused by stresses, suggesting their importance in multiple stress condition. Based on this analysis, we identify candidate genes for engineering crop plants tolerant to multiple stresses.     

Heat shock responses for understanding diseases of protein denaturation

Extracellular stresses induce heat shock response and render cells resistant to lethal stresses. Heat shock response involves induction of heat shock proteins (Hsps). Recently the roles of Hsps in neurodegenerative diseases and cancer are attracting increasing attention and have accelerated the study of heat shock response mechanism. This review focuses on the stress sensing steps, molecules involved in Hsps production, diseases related to Hsp malfunctions, and the potential of proteomics as a tool for understanding the complex signaling pathways relevant to these events.     

Variation in heat shock protein expression at the latitudinal range limits of a widely‐distributed species,the Glanville fritillary butterfly (Melitaea cinxia)

Studies of heat shock response show a correlation with local climate, although this is more often across altitudinal than latitudinal gradients. In the present study, differences in constitutive but not inducible components of heat shock response are detected among populations of the Glanville fritillary butterfly Melitaea cinxia L. that exist at the species' latitudinal range limits (Finland and Spain). The study demonstrates that macroclimatic differences between these sites should cause greater exposure of the Spanish population to higher temperatures. Thermal stress treatments are used to estimate differences in the expression of four genes potentially relevant for tolerating these temperatures. For the analysis, three heat‐shock proteins and glyceraldehyde‐3‐phosphate dehydrogenase (G3PDH), a glycolysis enzyme that also modulates cell growth based on metabolic state, are chosen. Two constitutive differences are found between the sites. First, insects from Spain have higher levels of Hsp 21.4 than those from Finland regardless of thermal stress treatment; this protein is not inducible. Second, insects from Finland have higher levels of G3PDH. The two remaining Hsps, Hsp20.4 and Hsp90, show dramatic up‐regulation at higher temperatures, although there are no significant differences between insects from the different populations in either constitutive levels or inducibility. In nature, differences between the study populations likely occur in the expression of all four genes that were studied, although these differences would be directly climate‐induced in Hsp20.4 and Hsp90 and constitutive in Hsp21.4 and G3PDH. Inducibility may mitigate the need for constitutive variation in traits that adapt insects to local climate.     

Role of HSF activation for resistance to heat, cold and high-temperature knock-down

Regulation of heat shock proteins (Hsps) by the heat shock factor (HSF) and the importance of these proteins for resistance to heat stress is well documented. Less characterized is the importance of Hsps for cold stress resistance although Hsp70 is known to be induced following long-term cold exposure in Drosophila melanogaster. In this study, a temperature-sensitive HSF mutant line was used to investigate the role of HSF activation following heat hardening, rapid cold hardening (RCH) and long-term cold acclimation (LTCA) on heat and cold resistance, and this was correlated with Hsp70 expression. In addition, the effect of HSF activation on high-temperature knock-down resistance was evaluated. We found a significantly decreased HSF activation in the mutant line as compared to a corresponding control line following heat hardening, and this was correlated with decreased heat resistance of the mutant line. However, we did not find this difference in HSF activity to be important for resistance to cold stress or high-temperature knock-down. The findings indicate that induction of stress genes regulated by HSF, such as Hsps, although occurring following LTCA, are not of major importance for cold stress resistance and neither for RCH nor high-temperature knock-down resistance in D. melanogaster.     

The heat shock response: life on the verge of death

Organisms must survive a variety of stressful conditions, including sudden temperature increases that damage important cellular structures and interfere with essential functions. In response to heat stress, cells activate an ancient signaling pathway leading to the transient expression of heat shock or heat stress proteins (Hsps). Hsps exhibit sophisticated protection mechanisms, and the most conserved Hsps are molecular chaperones that prevent the formation of nonspecific protein aggregates and assist proteins in the acquisition of their native structures. In this Review, we summarize the concepts of the protective Hsp network.     

Role of Escherichia coli molecular chaperones in the protection of bacterial cells against irreversible aggregation induced by heat shock

All living organisms respond to environmental stresses, such as heat or ethanol by increasing the synthesis of a specific group of proteins termed heat shock proteins (Hsps) or stress proteins. Major Hsps are molecular chaperones and proteases. Molecular chaperones facilitate the proper folding of polypeptides, protect other proteins from inactivation, and reactivate aggregated proteins. Heat shock proteases eliminate proteins irreversibly damaged by stress. This review describes the role of heat shock proteins of the model bacterial cell, E. coli in the protection of other proteins against aggregation and in the mechanism of removal of protein aggregates from the cell. This mechanism remains unclear and it is believed to involve substrate renaturation and proteolysis by molecular chaperones and heat shock proteases. Recently, many studies have been focused on the disaggregation and reactivation of proteins by a bi-chaperone system consisting of DnaK/DnaJ/GrpE and ClpB, an ATPase from the AAA superfamily of proteins.