Wild and cultivated Triticum species differ in thermotolerant habit and HSP gene expression

High temperature (HT) stress is one of the most important environmental stimuli, negatively affecting plant survival and crop yield. Basal and acquired thermotolerance (ATT) are two components of plant response to HT, the mechanisms controlling them are not completely known yet. Basal thermotolerance was evaluated in a collection of 47 Triticum turgidum and Triticum durum genotypes, by the cell membrane stability (CMS) test, observing high variability. T. turgidum accessions exhibited the highest CMS values corresponding to higher thermotolerance, while T. durum cultivars (cvs) exhibited lower CMS values. The heat shock response is characterized by the synthesis of heat shock proteins (HSPs), and variation in HSPs production may be related to variation in ATT. The expression of HSP genes (coding cytoplasmic and plastidial small HSPs and two members of HSP70 family), previously hypothesized to be correlated with thermotolerance, was evaluated in thermotolerant and thermosensitive genotypes grown in the field, in control and HT conditions. The results obtained suggest that the genes coding for the two members of HSP70 family, may be responsible for basal thermotolerance. The overall results suggest that wild genotypes may possess a yet undisclosed variability for alleles involved in thermotolerance.     

Heat shock proteins: modifying factors in physiological stress responses and acquired thermotolerance.

Cells from virtually all organisms respond to a variety of stresses by the rapid synthesis of a highly conserved set of polypeptides termed heat shock proteins (HSPs). The precise functions of HSPs are unknown, but there is considerable evidence that these stress proteins are essential for survival at both normal and elevated temperatures. HSPs also appear to play a critical role in the development of thermotolerance and protection from cellular damage associated with stresses such as ischemia, cytokines, and energy depletion. These observations suggest that HSPs play an important role in both normal cellular homeostasis and the stress response. This mini-review examines recent evidence and hypotheses suggesting that the HSPs may be important modifying factors in cellular responses to a variety of physiologically relevant conditions such as hyperthermia, exercise, oxidative stress, metabolic challenge, and aging.     

Variation in Heat-shock Proteins and Photosynthetic Thermotolerance among Natural Populations of Chenopodium album L. from Contrasting Thermal Environments: Implications for Plant Responses to Global Warming

Production of heat-shock proteins (Hsps) is a key adaptation to acute heat stress and will be Important in determining plant responses to climate change. Further, intraspecifc variation in Hsps, which will influence species-level response to global warming, has rarely been examined in naturally occurring plants. To understand intraspeciflc variation in plant Hsps and its relevance to global warming, we examined Hsp content and thermotolerance in five naturally occurring populations of Chenopodium album L. from contrasting thermal environments grown at low and high temperatures. As expected,Hsp accumulation varied between populations, but this was related more to habitat variability than to mean temperature.Unexpectedly, Hsp accumulation decreased with increasing variability of habitat temperatures. Hsp accumulation also decreased with increased experimental growth temperatures. Physiological thermotolerance was partitioned into basal and induced components. As with Hsps, induced thermotolerance decreased with increasing temperature variability. Thus,populations native to the more stressful habitats, or grown at higher temperatures, had lower Hsp levels and induced thermotolerance, suggesting a greater reliance on basal mechanisms for thermotolerance. These results suggest that future global climate change will differentially impact ecotypes within species, possibly by selecting for increased basal versus inducible thermotolerance.     

Treatment with 24-epibrassinolide,a brassinosteroid,increases the basic thermotolerance of Brassica napus and tomato seedlings

Brassinosteroids are plant growth-promoting compounds that exhibit structural similarities to animal steroid hormones. Recent studies have indicated that brassinosteroids are essential for proper plant development. In addition to a role in development, several lines of evidence suggest that brassinosteroids exert anti-stress effects on plants. However, the mechanism by which they modulate plant stress responses is not understood. We show here that Brassica napus and tomato seedlings grown in the presence of 24-epibrassinolide (EBR) are significantly more tolerant to a lethal heat treatment than are control seedlings grown in the absence of the compound. Since a preconditioning treatment of seedlings was not required to observe this effect, we conclude that EBR treatment increases the basic thermotolerance of seedlings. An analysis of heat shock proteins (HSPs) in B. napus seedlings by western blot analysis indicated that the HSPs did not preferentially accumulate in EBR-treated seedlings at the control temperature. However, after heat stress, HSP accumulation was higher in EBR-treated than in untreated seedlings. The results of the present study provide the first direct evidence for EBR-induced expression of HSPs. The higher accumulation of HSPs in EBR-treated seedlings raises the possibility that HSPs contribute, at least in part, to thermotolerance in EBR-treated seedlings. A search for factors other than HSPs, which may directly or indirectly contribute to brassinosteroid-mediated increase in thermotolerance, is underway.     

Nitrogen availability alters patterns of accumulation of heat stress-induced proteins in plants

Mounting evidence suggests that heat-shock proteins (HSPs) play a vital role in enhancing survival at high temperature. There is, however, considerable variation in patterns of HSP production among species, and even among and within individuals of a species. It is not known why this variation exists and to what extent variation in HSPs among organisms might be related to differences in thermotolerance. One possibility is that production of HSPs confers costs and natural selection has worked towards optimizing the cost-to-benefits of HSP synthesis and accumulation. However, the costs of this production have not been determined. If HSP production confers significant nitrogen (N) costs, then we reasoned that plants grown under low-N conditions might accumulate less HSP than high-N plants. Furthermore, if HSPs are related to thermotolerance, then variation in HSPs induced by N (or other factors) might correlate with variation in thermotolerance, here measured as short-term effects of heat stress on net CO₂ assimilation and photosystem II (PSII) function. To test these predictions, we grew individuals of a single variety of corn (Zea mays L.) under different N levels and then exposed the plants to acute heat stress. We found that: (1) high-N plants produced greater amounts of mitochondrial Hsp60 and chloroplastic Hsp24 per unit protein than their low-N counterparts; and (2) patterns of HSP production were related to PSII efficiency, as measured by F _v/F _m. Thus, our results indicate that N availability influences HSP production in higher plants suggesting that HSP production might be resource-limited, and that among other benefits, chloroplast HSPs (e.g., Hsp24) may in some way limit damage to PSII function during heat stress.     

Ethanol treatment triggers a heat shock-like response but no thermotolerance in soybean (Glycine max cv. Kaohsiung No.8) seedlings

Non‐lethal heat‐shock (HS) treatment has previously been shown to induce thermotolerance in soybean (Glycine max cv. Kaohsiung No.8) seedlings. This acquired thermotolerance correlates with the de novo synthesis of heat‐shock proteins (HSPs). Interestingly, we found that ethanol treatments also elicited HS‐like responses in aetiolated soybean seedlings at their normal growth temperature of 28 °C. Northern blot analyses revealed that the expression of HS genes hsp17.5, hsp70 and hsc 70 was induced by ethanol. Radioactive amino acids were preferentially incorporated into high molecular weight (HMW) HSPs rather than class I low molecular weight (LMW) HSPs during non‐lethal ethanol treatments. Immunoblot analysis confirmed that no accumulation of class I LMW HSPs occurred after non‐lethal ethanol treatment. Pre‐treatment with a non‐lethal dose of ethanol did not provide thermotolerance, as the aetiolated soybean seedlings could not survive a subsequent heat shock of 45 °C for 2 h. In contrast, non‐lethal HS pre‐treatment, 40 °C for 2 h, conferred tolerance on aetiolated soybean seedlings to otherwise lethal treatments of 7·5% ethanol for 8 h or 10% ethanol for 4 h. These results suggest that plant class I LMW HSPs may play important roles in providing both thermotolerance and ethanol tolerance.     

Activation of Heat-Shock Genes by Digitonin is Selectively Repressed in Preheated Drosophila Salivary Glands

Treatment of Drosophila salivary glands with a mild detergent, digitonin, activates puffing at 35 chromosome loci. These digitonin-activated puffs include all of the nine heat-shock puffs known in D. melanogaster . Here we show that the activation of heat-shock genes, but not of other digitoninstimulated puffs, is repressed in salivary glands which have been subjected to and have recovered from heat shock before being treated with digitonin. The findings indicate that, (a) the activation of heat-shock genes by digitonin, as that by temperature elevation, is self-regulated by the heat-shock proteins (HSPs). (b) the gene repressive activity of HSPs is heat-shock-gene specific, and (c) the repression mechanism of heat-shock genes by HSPs is resistant to digitonin, in contrast to that the suppression of heat-shock genes is prevented by the detergent in non-heat-shocked salivary glands. The selective repression of heat-shock genes in preheated salivary glands suggests that the heat-shock genes and other digitonin-activated genes may be controlled by a different mechanism(s).     

HSP70-3 Interacts with Phospholipase Dδ and Participates in Heat Stress Defense

Heat shock proteins (HSPs) function as molecular chaperones and are key components responsible for protein folding, assembly, translocation, and degradation under stress conditions. However, little is known about how HSPs stabilize proteins and membranes in response to different hormonal or environmental cues in plants. Here, we combined molecular, biochemical, and genetic approaches to elucidate the involvement of cytosolic HSP70-3 in plant stress responses and the interplay between HSP70-3 and plasma membrane (PM)-localized phospholipase Dδ (PLDδ) in Arabidopsis (Arabidopsis thaliana). Analysis using pull-down, coimmunoprecipitation, and bimolecular fluorescence complementation revealed that HSP70-3 specifically interacted with PLDδ. HSP70-3 bound to microtubules, such that it stabilized cortical microtubules upon heat stress. We also showed that heat shock induced recruitment of HSP70-3 to the PM, where HSP70-3 inhibited PLDδ activity to mediate microtubule reorganization, phospholipid metabolism, and plant thermotolerance, and this process depended on the HSP70-3–PLDδ interaction. Our results suggest a model whereby the interplay between HSP70-3 and PLDδ facilitates the re-establishment of cellular homeostasis during plant responses to external stresses and reveal a regulatory mechanism in regulating membrane lipid metabolism.

The heat shock protein 70-3 interacts with phospholipase Dδ to regulate microtubule organization, lipid metabolism, and plant thermotolerance in Arabidopsis.     

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     

Detailed characterization of heat shock protein synthesis and induced thermotolerance in seedlings of Sorghum bicolor L.

Tolerance of both protein synthesis and seedling growth to apreviously lethal high temperature can be induced by prior exposureto a sub-lethal temperature during which the synthesis of heatshock proteins (HSPs) occurs. In this study, a thermal gradientbar was used to measure the physiological effects of temperatureon seedlings of sorghum (Sorghum bicolor L.) in conjunctionwith studies of gene expression. The duration of HSP synthesis,both during continued high temperature treatment or on returnto normal temperatures, was found to be very finely modulatedand was dependent on the severity of the initial heat shock.The synthesis of heat shock proteins and the induction of thermotolerancewere rapid, reversible and reinducible phenomena. Maximal thermotolerancewas obtained after treatments that induced the full complementof HSPs. Subsequent treatments that repressed HSP synthesis,also abolished thermotolerance. The presence of HSPs, however,was not sufficient for the tissue to be in a thermotolerantstate and the results suggest that either their de novo synthesis,or some other factor, is required for the induction of thermotolerance.Pre-existing HSPs did not inhibit the synthesis of new HSPs.Although the kinetics of the synthesis of HSPs and the developmentof thermotolerance show a tight correlation, the kinetics ofthe decay of thermotolerance and the degradation of HSPs werenot linked. The functional state or distribution of HSPs maywell change during the recovery process. Key words: Heat shock, thermotolerance, Sorghum bicolor, growth, protein synthesis