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.     

Regulation of heat-shock protein synthesis in chicken muscle culture during recovery from heat shock

Exposure of chick myotube cultures to a temperature (45 degrees C) higher than their normal growing temperature (37 degrees C) caused extensive synthesis of three major polypeptides of Mr = 25 000, 65 000 and 81 000 referred to as 'heat-shock polypeptides' (hsps). When these cells were allowed to recover from heat-shock treatment at 37 degrees C for 6-8 h, the rate of accumulation of isotope into the 65 000-Mr and 81 000-Mr hsps declined to levels comparable to those in control cultures maintained at 37 degrees C. However, incorporation of isotope in the 25 000-Mr hsp continued at an elevated rate for a longer period than the 65 000-Mr and 81 000-Mr hsps. When heat-shocked cells were allowed to recover at 37 degrees C in the presence of actinomycin D to block new mRNA synthesis, the hsp synthesis as measured by the incorporation of radioactive isotope in these polypeptides continued at levels comparable to those in heat-shocked cells prior to recovery. The block of recovery by actinomycin D was due to the presence of a greater amount of functional hsp mRNAs in the polysomes as compared to untreated controls. The role of competition between the mRNAs for hsps and normal cellular proteins for the translation machinery in regulating protein synthesis during the recovery from heat shock has been discussed.     

Factors influencing the heat shock response of Xenopus laevis embryos

We have further characterized the heat shock response of Xenopus laevis embryos. Xenopus embryos respond to heat shock by consistently synthesizing four major heat shock proteins (hsps) of 62, 70, 76, and 87 kilodaltons. In addition to these hsps, heat-shocked embryos also exhibit the synthesis of several minor hsps. The synthesis of these hsps is often variable. We have monitored the effects of different temperatures and lengths of heat shock on the pattern and intensity of hsp synthesis. In general, the four major hsps are induced more strongly at higher temperatures and during increasing intervals of heat shock. The temperature and duration of heat shock can affect the synthesis of the minor hsps, however. Some hsps are synthesized at lower temperatures only (i.e., below 37 degrees C), whereas others are synthesized only at higher temperatures (i.e., above 37 degrees C). We have extensively examined the characteristics of hsp 35 synthesis, one of the most variably synthesized hsps. This hsp is characteristically synthesized at temperatures above 35 degrees C and usually during the first 40 min of heat shock, after which it becomes undetectable. In some experiments, its synthesis is restimulated during later intervals of heat shock. Hsp 35 is also under developmental regulation. It is not synthesized by heat-shocked embryos until the late blastula to early gastrula stage. After this brief period of inducibility, its synthesis is dramatically reduced in mid- to late gastrulae, but reappears in heat-shocked neurulae. We have previously demonstrated that hsp 35 is related to the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The induction of hsp 35 synthesis is inversely correlated with the constitutive levels of GAPDH specific activity. In this paper we document further correlations between the synthesis of hsp 35 and GAPDH specific activity during early Xenopus development.     

Flavonoids inhibit the expression of heat shock proteins

Cells exposed to several forms of stress, such as heat shock, transiently synthesize a group of proteins called heat shock proteins (hsps). Although many stressors other than heat shock are known to induce hsps, inhibitors of hsp expression have never been reported. Here we show that quercetin and several other flavonoids inhibit the synthesis of hsps induced by heat shock in two human cell lines, Hela cells and COLO320 DM cells. Quercetin inhibited the induction of hsp70 at the level of mRNA accumulation. This is the first report to describe the inhibition of hsp expression by reagents.     

A comparison of sodium arsenite- and hyperthermia-induced stress responses and abnormal development in cultured postimplantation rat embryos.

Acute exposures to sodium arsenite (50 microM) were embryotoxic in day 10 rat embryos exposed in vitro. Sodium arsenite-induced embryotoxicity was characterized by decreased growth (crown-rump length, somite number, and embryo protein content) and abnormal development (hypoplastic prosencephalon, abnormal somites, and abnormal flexion of the tail). At embryotoxic exposures, sodium arsenite also induced the synthesis of three heat shock proteins (hsps), one of which is recognized by a monoclonal antibody specific for the heat-inducible hsp 72. In addition, sodium arsenite induced the accumulation of heat-inducible hsp 70 mRNA. Although the abnormal morphologies induced by sodium arsenite and hyperthermia appear to be different, the stress response as measured by the synthesis of hsps, the accumulation of hsp 72 protein, and the accumulation of hsp 70 mRNA is similar in embryos exposed to these two embryotoxic agents. Thus, sodium arsenite and hyperthermia both induce a stress response; however, the relationship between the induction of a stress response and the subsequent abnormal development that ensues is unclear.     

Physiological and Molecular Effects of 24-Epibrassinolide, a Brassinosteroid on Thermotolerance of Tomato

Brassinosteroids are naturally occurring plant growth regulators, which exhibit structural similarities to animal steroid hormones. Recent studies have indicated that besides an essential role in plant growth and development, brassinosteroids also exert anti-stress effects on plants. We show here that tomato plants treated with 24-epibrassinolide (EBR) are more tolerant to high temperature than untreated plants. An analysis of mitochondrial small heat shock proteins (MT-sHSP) in tomato leaves by western blotting revealed that the MT-sHSP did not preferentially accumulate in EBR treated plants at 25 °C. However, treatment of plants at 38 °C induced much more accumulation of MT-sHSP in EBR treated than in untreated plants. Results of this study provide the first direct evidence for EBR induced expression of MT-sHSP, which possibly induced thermotolerance in tomato plants. EBR treated tomato plants had better photosynthetic efficiency. We also observed significantly higher in vitro pollen germination, enhanced pollen tube growth and low pollen bursting in the presence of EBR at 35 °C, a temperature high enough to induce heat-stress symptoms in tomato, indicating a possible role of EBR during plant reproduction.     

Induction of heat shock proteins during initiation of solvent formation inClostridium acetobutylicum

Summary The response to stresses produced by changes in the fermentation conditions ofClostridium acetobutylicum in continuous culture was determined under acid- and solvent-producing conditions. Using a phosphate-limited chemostat it was found that specificheatshockproteins (hsp 73, hsp 72 [Dnak], hsp 67 [GroEL], hsp 17 and hsp 14) were synthesized at elevated levels during the shift from acid to solvent formation. The induction of these stress proteins was observed before acetone and butanol were detected in the medium and was therefore not a response to these solvents present in the medium. Simultaneously with the induction of hsps, changes in the synthesis rates of other cellular proteins were observed. Synthesis of proteins associated with the acid production phase decreased and of proteins correlated with the solvent production phase increased. Some hsps, including the DnaK- and GroEL-similar proteins, hsp 73 and hsp 21, were also induced by a change in the growth rate and/or the pH. The analysis of the general regulation of the heat shock response inC. acetobutylicum revealed that the induction of at least 15 hsps after a temperature up-shift was transient and that two temporal classes of hsps could be distinguished. The synthesis of one group of hsps reached a maximum after 6 min and another around 11 min after the temperature upshift and returned to steady-state levels 30 to 40 min after the shock.     

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.     

Heat shock response in psychrophilic and psychrotrophic yeast from Antarctica

The response to heat stress in six yeast species isolated from Antarctica was examined. The yeast were classified into two groups: one psychrophilic, with a maximum growth temperature of 20°C, and the other psychrotrophic, capable of growth at temperatures above 20°C. In addition to species-specific heat shock protein (hsp) profiles, a heat shock (15°C–25°C for 3 h) induced the synthesis of a 110-kDa protein common to the psychrophiles, Mrakia stokesii, M. frigida, and M. gelida, but not evident in Leucosporidium antarcticum. Immunoblot analyses revealed heat shock inducible proteins (hsps) corresponding to hsps 70 and 90. Interestingly, no proteins corresponding to hsps 60 and 104 were observed in any of the psychrophilic species examined. In the psychrotrophic yeast, Leucosporidium fellii and L. scottii, in addition to the presence of hsps 70 and 90, a protein corresponding to hsp 104 was observed. In psychrotrophic yeast, as observed in psychrophilic yeast, the absence of a protein corresponding to hsp 60 was noted. Relatively high endogenous levels of trehalose which were elevated upon a heat shock were exhibited by all species. A 10 Celsius degree increase in temperature above the growth temperature (15°C) of psychrophiles and psychrotrophs was optimal for heat shock induced thermotolerance. On the other hand, in psychrotrophic yeast grown at 25°C, only a 5 Celsius degree increase in temperature was necessary for heat shock induced thermotolerance. Induced thermotolerance in all yeast species was coincident with hsp synthesis and trehalose accumulation. It was concluded that psychrophilic and psychrotrophic yeast, although exhibiting a stress response similar to mesophilic Saccharomyces cerevisiae, nevertheless had distinctive stress protein profiles. Received: August 7, 1997 / Accepted: October 22, 1997     

Hydrogen peroxide induces heat shock protein and proto-oncogene mRNA accumulation in Xenopus laevis A6 kidney epithelial cells

In this study, we examined the effect of hydrogen peroxide on the accumulation of various mRNAs encoding heat shock proteins (hsps) and proto-oncogenes in Xenopus A6 kidney epithelial cells. Hydrogen peroxide treatment enhanced the accumulation of hsp90, hsp70, hsp30, c-jun, c-fos, and actin mRNAs with distinct temporal patterns. Although hsp70, c-fos, and c-jun mRNA levels peaked at 1-2 h before declining, hsp30 and hsp90 mRNA levels were maximal at 4-6 h. Other mRNAs, including heat shock cognate hsc70, immunoglobulin binding protein, and ribosomal L8, were unaffected. Treatment of kidney cells with a combination of mild heat shock plus hydrogen peroxide resulted in a synergistic increase in the relative levels of both hsp70 and hsp30 mRNA, but not hsp90, c-fos, c-jun, or actin. This study suggests that analysis of hsp and proto-oncogene mRNA levels may be of value as molecular biomarkers of oxidative stress associated with various disease states and nephrotoxicity in kidney.     

Preliminary study of heat shock proteins in nemerteans

Nemerteans experience varying environmental temperatures during low tide exposures. Inducible heat shock proteins (hsps) have been reported for most organisms following both artificial heat stress and natural environmental temperature variations. This preliminary study reports the presence of hsps in the phylum Nemertea. A lethal temperature of 36 °C was determined for Paranemertes peregrina Coe, 1901. The nemerteans were exposed to a temperature of 34 °C for 2 h. After a 2 h recovery time, the worms were then analyzed for hsps by SDS–PAGE and western immunoblot protocols. Control worms were allowed to acclimate to ambient temperatures (13–15 °C) before hsp analysis. Hsp70 and hsp90 were detected in both the control and heat-shocked worms in highly variable concentrations, and the latter group had significantly elevated hsp70 levels. In addition, the analysis detected different isoforms of hsp70. The detection of hsps indicates a possible role in nemertean physiology during response to thermal stress, and potentially to other environmental challenges.