Heat shock induced proteins in plant cells

Tobacco (Nicotiana tabacum) and soybean (Glycine max) tissue culture cells were exposed to a heat shock and protein synthesis studied by SDS-polyacrylamide gel electrophoresis after labeling with radioactive amino acids. A new pattern of protein synthesis is observed in heat-shocked cells compared to that in control cells. About 12 protein bands, some newly appearing, others synthesized in greatly increased quantities in heat-shock cells, are seen. Several of the heat-shock proteins (HSPs) in both tobacco and soybean are similar in size. One of the HSPs in soybean (76K) shares peptide homology with its presumptive 25°C counterpart, indicating that the synthesis of at least some HSPs may not be due to activation of new genes. The optimum temperature for maximal induction of most HSPs is 39–40°C. Total protein synthesis decreases as heat-shock temperature is increased and is barely detectable at 45°C. The heat-shock response is maintained for a relatively short time in tobacco cells. After 3 hr at 39°C, a decrease is seen in the synthesis of the HSPs, and after 4 hr practically no HSPs are synthesized. After exposure to 39°C for 1 hr, followed by a return of tobacco cells to 26°C, recovery to the control pattern of synthesis requires greater than 6 hours. These results indicate that cells of flowering plants exhibit a heat-shock response similar to that observed in animal cells.     

Induction of Heat Shock Proteins and Acquisition of Thermotolerance in Germinating Pigeonpea Seeds

Heat shock proteins (HSPs) ranging in molecular masses from 14 to 110 kDa were induced in embryonic axes of germinating Cajanus cajan (L.) Millspaugh seeds after exposure to 40 °C for 1 or 2 h. At 45 °C, there was a marked decline in synthesis of HSPs. A close relationship was observed between HSPs induced and the growth of the germinating seeds. Pretreatment of germinating seeds at 40 °C for 1 h or 45 °C for 10 min followed by incubation at 28 °C for 3 h led to considerable thermotolerance (45 °C, 2 h) and the recovery of protein synthesis. This revised version was published online in July 2006 with corrections to the Cover Date.     

Heat-Resistance and Heat-Shock Response in the Nosocomial Pathogen <Emphasis Type="Italic">Enterococcus faecium</Emphasis>

We have characterized the heat-shock response of the nosocomial pathogen Enterococcus faecium. The growth of E. faecium cells was analyzed at different temperatures; little growth was observed at 50°C, and no growth at 52°C or 55°C. In agreement, a marked decrease of general protein synthesis was observed at 52°C, and very light synthesis was detected at 55°C. The heat resistance of E. faecium cells was analyzed by measuring the survival at temperatures higher than 52°C and, after 2 h of incubation, viable cells were still observed at 70°C. By Western blot analysis, two heat-induced proteins were identified as GroEL (65 kDa) and DnaK (75 kDa). Only one isoform for either GroEL or DnaK was found. The gene expression of these heat-shock proteins was also analyzed by pulsed-labeled experiments. The heat-induced proteins showed an increased rate of synthesis during the first 5 min, reaching the highest level of induction after 10 min and returning to the steady-state level after 20 min of heat treatment. Received: 29 March 2002 / Accepted: 5 July 2002     

The cytoplasmic pH, ATP content and total protein synthesis rate during heat-shock protein inducing treatments in yeast

In S. cerevisiae the induction of heat-shock protein (HSP) synthesis is accompanied by a decrease in the cytoplasmic and vacuolar pH as determined by means of [31P]NMR spectroscopy. The relationship of HSP synthesis and acidification of the cytoplasmic pH is dose-dependent under a variety of treatments (temperature increases (23-32 degrees C), addition of 2,4-dinitrophenol (greater than 1 mM), sodium arsenite (greater than 3.75 X 10(-5) M) or sodium cyanide (greater than 10 mM]. Changes in the intracellular pH occur within 5 min after treatment, attain a maximum within 30 min and are subsequently stable. HSPs 98, 85 and 70 show maximum synthesis rates 1-2 h after a 40 degrees C heat shock. The synthesis rates then decline. HSPs 56, 44 and 33 reveal a smaller and slower increase and almost no decrease in the synthesis rate within 4 h at 40 degrees C. The similar dose dependencies of HSP synthesis and cytoplasmic pH. as well as the immediate response of the pH, can also be demonstrated in the mitochondrial mutant of S. cerevisiae (Q0). This result indicates that the heat-shock response is mainly independent of intact oxidative phosphorylation. No correlation was observed between HSP synthesis rate and total intracellular ATP content.     

Modulation of protein phosphorylation and stress protein expression by okadaic acid on heat shock cells

We have demonstrated that pretreatment but not post-treatment with okadaic acid (OA) can aggravate cytotoxicity as well as alter the kinetics of stress protein expression and protein phosphorylation in heat shocked cells. Compared to heat shock, cells recovering from 1 hr pretreatment of OA at 200 nM and cotreated with heat shock at 45°C for the last 15 min of incubation (OA→HS treatment) exhibited enhanced induction of heat shock proteins (HSPs) 70 and 110. In addition to enhanced expression, the attenuation of HSC70 and HSP90 after the induction peaks was also delayed in OA→HS-treated cells. The above treatment also resulted in the rapid induction of the 78 kDa glucose-regulated protein (GRP78), which expression remained constant in cells recovering from treatment with 200 nM OA for 1 hr, heat shocked at 45°C for 15 min, or in combined treatment in reversed order (HS→OA treatment). Enhanced phosphorylation of vimentin and proteins with molecular weights of 65, 40, and 33 kDa and decreased phosphorylation of a protein with a molecular weight of 29 kDa were also observed in cells recovering from OA→HS treatment. Again, protein phosphorylation in cells recovering from HS→OA treatment did not differ from those in cells treated only with heat shock. Since the alteration in the kinetics of stress protein expression and protein phosphorylation was tightly correlated, we concluded that there is a critical link between induction of the stress proteins and phosphorylation of specific proteins. Furthermore, the rapid induction of GRP78 under the experimental condition offered a novel avenue for studying the regulation of its expression. © 1996 Wiley-Liss, Inc.     

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.     

Control of heat-shock response of young gametophytes of the sensitive fern is at the translational level

Young gametophytes of the sensitive fern, Onoclea sensibilis,respond to heat-shock by synthesizing in excess certain proteinsthat are made at normal growth temperature. Enhanced proteinsynthesis occurred during a 2 h heat-shock at a range of temperaturesbetween 38 °C and 50 °C. Although a temperature of 50°C proved lethal, a 5 min pulse at 50 °C resulted inenhanced synthesis of heat-shock proteins which continued forseveral hours at 25 °C. After heat-shock at 50 °C for10 or 15 min, the gametophytes temporarily lost their capacityfor protein synthesis but normal protein synthesis was resumedwithin 24 h of heat-shock. A heat-shock at 38 °C precedingone at 50 °C did not have any protecting effect on the gametophytes.In vitro translation of poly(A)+ RNA isolated from heat-shockedgametophytes yielded several proteins including heat-shock proteins.The results suggest that, rather than activating genes encodingnew messages for the synthesis of stress proteins, heat-shockof gametophytes of O. sensibilis triggers a controlling systemwhich enhances the translation of certain messages that aresynthesized at normal growth temperature. Key words: Onoclea sensibilis, heat-shock response, protein synthesis, sensitive fern, in vitro translation     

Tetraploid Induction by Inhibiting Mitosis I with Heat Shock, Cold Shock, and Nocodazole in the Hard Clam Mercenaria mercenaria (Linnaeus, 1758)

Tetraploid induction by inhibiting mitosis I with heat shock (32, 35, and 38°C), cold shock (1, 4, and 7°C), and nocodazole (0.02 to 1.6 mg/L) was investigated in the hard clam Mercenaria mercenaria. All treatments were applied to fertilized eggs about 5 min before the first cell division at 22 to 23°C, and lasted for 10, 15, and 20 min. Three replicates were produced for each treatment with different parents. The ploidy of resultant larvae and juveniles was determined with flow cytometry. Heat shock of 35 and 38°C was effective in inhibiting mitosis I, producing 54% to 89% tetraploid larvae. Heat shock of 32°C accelerated embryonic development without inhibiting mitosis or producing tetraploids. In all heat-shock groups, the survival to D-stage larvae was lower than in controls, suggesting that heat-shock treatments and tetraploidy were detrimental to larval development. At the juvenile stage, survivors from heat-shock groups contained no tetraploids. Cold shocks suspended the first cell division during the treatment, but produced no tetraploids in the 4°C and 7°C treatment groups. Cold shock of 1°C produced 31% tetraploid larvae in one replicate, with none surviving to juvenile stage. Nocodazole inhibited mitosis I at concentrations of 0.04 mg/L or higher, but did not produce tetraploids. This study indicates that heat shock is most effective in inducing tetraploids through mitosis I inhibition, although none of the induced tetraploids survived to juvenile stage.     

A study of the effect of heat shock and metal ions on protein synthesis in Neurospora crassa cells

• 1.1. Neurospora cells were grown at 28°C for 14hr and subjected to heat shock (HS) at 48°C for 45 min. Protein synthesis profiles, monitored by labelling with [³⁵S]methionine and one and two-dimensional electrophoresis, revealed nine heat shock proteins (HSPs).
• 2.2. Crossed-immunoelectrophoresis revealed five polypeptides in the shocked cell extracts that were not detectable in normal cells.
• 3.3. Synthesis of HSPs occurred rapidly during the shock treatment and ceased upon transfer to normal conditions. One of the HSPs—~43 K in size—may be a developmentally-regulated protein.
• 4.4. Metal ions—cadmium, zinc, manganese, copper—did not elicit a stress response when used alone but appeared to modulate the heat shock response.

     

Blood heat shock proteins evoked by some <Emphasis Type="Italic">Salmonella</Emphasis> strains infection in ducks

Bacterial heat-shock response is a global regulatory system required for effective adaptation to changes (stress) in the environment. An in vitro study was conducted to investigate the impact of a sublethal temperature (42°C) on heat shock protein (HSP) expression in 6 Salmonella strains (Salmonella Enteritidis, S. Typhimurium, S. Virchow, S. Shubra, S. Haifa and S. Eingedi). The 6 Salmonella strains were isolated from the tissues of ducklings that had died from avian salmonellosis. To determine the induction of HSP in the 6 Salmonella strains, they were exposed to the selected temperature level for 24 h and further kept for 48 h at culturing condition of 42°C. Growth under a sublethal temperature of 42°C increased the expression of several proteins of Salmonella, including a 63 kDa protein in addition to the generation and/or overexpression of 143 proteins which were specific to heat shock, concurrent to this acquired thermotolerance. The 6 Salmonella strains responded to 24 h of thermal stress at an elevated temperature 42°C by synthesizing different heat shock proteins (HSP) with molecular weights ranging between 13.62 and 96.61 kDa. At 48 h, the 6 Salmonella strains synthesized different HSPs with molecular weights ranging between 14.53 and 103.43 kDa. It follows that salmonellae would produce HSPs during the course of the infectious process. Salmonellosis produced several proteins after 24 and 48 h of infection. Seven of these proteins (100, 80, 60, 40, 30, 20 and 10 kDa) were recognized in the serum obtained from the ducklings infected with S. Enteritidis, S. Typhimurium, S. Virchow, S. Shubra, S. Haifa and S. Eingedi after 24 h of infection. After 48 h, the 1–7 kDa HSP became more evident and indicated their de novo generation.     

Okadaic acid,sphingosine, and phorbol ester reversibly modulate heat induction on protein kinase Fa/GSK-3α in A431 cells

Exposure of A431 cells to a rapid and sudden increase from 37°C to 46°C for 30 min could induce an increase in protein level and cellular activity of protein (kinase Fa /GSK-3α) up to ∼200% of control level. However, when cells were first treated with 500 nM tumor promoter phorbol ester TPA at 37°C for 30 min to activate cellular protein kinase C (PKC) or with 400 nM okadaic acid at 37°C for 30 min to inhibit cellular protein phosphatases followed by heat shock at 46°C for another 30 min, the heat induction on kinase Fa /GSK-3α was found to be completed blocked. In sharp contrast, when cells were first treated with 1 μM TPA at 37°C for 24 h or with 5 μM sphingosine at 37°C for 30 min to down-regulate cellular PKC, the heat induction on kinase Fa /GSK-3α was found to be reversely promoted up to ∼ 250% of control level, demonstrating that kinase Fa /GSK-3α may not represent a constitutively active/mitogen-inactivated protein kinase as previously conceived. Taken together, the results provide initial evidence that TPA/sphingosine and okadaic acid could reversibly modulate the heat induction on kinase Fa /GSK-3α in A431 cells, suggesting that phosphorylation/dephosphorylation mechanisms are involved in the regulation of the heat-shock induction of kinase Fa /GSK-3α, representing a new mode of signal transduction for the regulation of this multisubstrate protein kinase and a new mode of signaling pathway modulating the heat-induction process. © 1996 Wiley-Liss, Inc.     

The Arabidopsis HSP18.2 promoter/GUS gene fusion in transgenic Arabidopsis plants: a powerful tool for the isolation of regulatory mutants of the heat-shock response

A detailed study of the expression of the promoter of the HSP18.2 gene from Arabidopsis fused to the bacterial gene for β-glucuronidase (GUS) in transgenic Arabidopsis plants is described. High levels of GUS activity were induced in all organs of transformants except for seeds during heat shock. The optimum temperature for expression of GUS in Arabidopsis was 35°C regardless of the plant growth temperature. Heat shock of 40°C did not induce any detectable levels of GUS activity. Pre-incubation at 35°C was found to have a protective effect on the induction of GUS activity at 40°C. GUS activity was also increased in response to a gradual increase in temperature. Histochemical analysis revealed that basal levels of GUS activity were induced in the vascular tissue of leaves and sepals, as well as at the tips of carpels, at the normal growth temperature. Heat treatment of a limited part of the plant tissue did not appear to cause systemic induction of GUS activity. To extend the analysis of the plant heat-shock response, we attempted to screen mutations in genes involved in the regulation of the induction of heat-shock protein (HSP) genes, using the GUS gene as a selection marker in transgenic Arabidopsis plants, and the results of this analysis are described.     

Recurrent heat shock impairs the proliferation and differentiation of C2C12 myoblasts

Heat-related illness and injury are becoming a growing safety concern for the farmers, construction workers, miners, firefighters, manufacturing workers, and other outdoor workforces who are exposed to heat stress in their routine lives. A primary response by a cell to an acute heat shock (HS) exposure is the induction of heat-shock proteins (HSPs), which chaperone and facilitate cellular protein folding and remodeling processes. While acute HS is well studied, the effect of repeated bouts of hyperthermia and the sustained production of HSPs in the myoblast-myotube model system of C2C12 cells are poorly characterized. In C2C12 myoblasts, we found that robust HS (43 °C, dose/time) significantly decreased the proliferation by 50% as early as on day 1 and maintained at the same level on days 2 and 3 of HS. This was accompanied by an accumulation of cells at G2 phase with reduced cell number in G1 phase indicating cell cycle arrest. FACS analysis indicates that there was no apparent change in apoptosis (markers) and cell death upon repeated HS. Immunoblot analysis and qPCR demonstrated a significant increase in the baseline expression of HSP25, 70, and 90 (among others) in cells after a single HS (43 °C) for 60 min as a typical HS response. Importantly, the repeated HS for 60 min each on days 2 and 3 maintained the elevated levels of HSPs compared to the control cells. Further, the continuous HS exposure resulted in significant inhibition of the differentiation of C2C12 myocytes to myotubes and only 1/10th of the cells underwent differentiation in HS relative to control. This was associated with significantly higher levels of HSPs and reduced expression of myogenin and Myh2 (P < 0.05), the genes involved in the differentiation process. Finally, the cell migration (scratch) assay indicated that the wound closure was significantly delayed in HS cells relative to the control cells. Overall, these results suggest that a repeated HS may perturb the active process of proliferation, motility, and differentiation processes in an in vitro murine myoblast-myotube model.     

Lamin B is a prompt heat shock protein

The cellular response to hyperthermia involves the increased synthesis of heat shock proteins (HSPs) within several hours after treatment. In addition, a subset of proteins has been shown to be increased immediately after heating. These “prompt” HSPs are predominantly found in the nuclear matrix–intermediate filament fraction and are not present or detectable in unheated cells. Since the nuclear matrix has been suggested to be a target for heat-induced cell killing, prompt HSPs may play a prominent role in the heat shock response. Using Western blotting and flow cytometry, we found that an increase in the synthesis of lamin B, one of the major proteins of the nuclear lamina, is induced during heating at 45.5°C but not during heating at 42°C. Since it is an abundant protein which is constitutively expressed in mammalian cells, lamin B appears to be a unique member of the prompt HSP family. The kinetics of induction of lamin B during 45.5°C heating did not correlate with the dose-dependent reduction in cell survival. While increased levels of lamin B during 45.5°C heating do not appear to confer a survival advantage directly, a possible role for lamin B in cellular recovery after heat shock cannot be discounted. J Cell Physiol 178:28–34, 1999. © 1999 Wiley-Liss, Inc.     

Thermotolerance and the heat-shock response in Candida albicans

At elevated temperatures, yeast cells of Candida albicans synthesized nine heat-shock proteins (HSPs) with apparent molecular masses of 98, 85, 81, 76, 72, 54, 34, 26 and 18 kDa. The optimum temperature for the heat-shock response was 45 degrees C although HSPs were detected throughout the range 41-46 degrees C. Protein synthesis was not observed in cells kept at 48 degrees C. Yeast cells survived exposure to an otherwise lethal temperature of 55 degrees C when they had previously been exposed to 45 degrees C. The thermotolerance induced during incubation at 45 degrees C required protein synthesis, since protection was markedly reduced by trichodermin. Mercury ions induced a set of three stress proteins, one of which corresponded in size to an HSP, and cadmium ions evoked one stress protein seemingly unrelated to the HSPs observed after temperature shift.     

Importance of membrane fluidity in the induction of alkaline phosphatase,a periplasmic enzyme,in Escherichiacoli

An unsaturated fatty acid auxotroph was supplemented with either elaidate or oleate. After derepression of alkaline phosphatase by phosphate limitation at 38°C, the cells were shifted to incubation at various temperatures. Arrhenius plots of the rate of enzyme induction gave a steeper negative slope in the temperature range from 30°C to 35°C with elaidate-supplemented cells than with oleate-supplemented cells. At 25°C the induction was arrested in the former cells, while it was continued at a considerable rate in the latter. The arrest was released upon shift-back to 38°C, and precursors convertible to the active enzyme were not accumulated during incubation at 25°C. There was no marked difference in slope of Arrhenius plots of the rate of bulk protein synthesis between both types of cells, and the slope was almost equal to that of the rate of enzyme induction in the oleate-supplemented cells. The rate of β-galactosidase induction in the elaidate cells showed a similar temperature dependence to that of bulk protein synthesis.     

Response of preosteoblasts to thermal stress conditioning and osteoinductive growth factors

Conditioning protocols involving mechanical stress independently or with chemical cues such as growth factors (GFs) possess significant potential to enhance bone regeneration. However, utilization of thermal stress conditioning alone or with GFs for bone therapy has been under-investigated. In this study, a preosteoblast cell line (MC3T3-E1) was exposed to treatment with water bath heating (44°C, 4 and 8 min) and osteoinductive GFs (bone morphogenetic protein-2 and transforming growth factor-β1) individually or in combination to investigate whether these stimuli could promote induction of bone-related markers, an angiogenic factor, and heat shock proteins (HSPs). Cells remained viable when heating durations were less than 20 min at 40oC, 16 min at 42oC, and 10 min at 44oC. Increasing heating duration at 44°C, promoted gene expression of HSPs, osteocalcin (OCN), and osteopontin (OPN) at 8 h post-heating (PH). Heating in combination with GFs caused the greatest gene induction of osteoprotegerin (OPG; 6.9- and 1.6-fold induction compared to sham-treated and GF only treated groups, respectively) and vascular endothelial growth factor (VEGF; 16.0- and 1.6-fold compared to sham and GF-only treated groups, respectively) at 8 h PH. Both heating and GFs independently suppressed the matrix metalloproteinase-9 (MMP-9) gene. GF treatment caused a more significant decrease in MMP-9 protein secretion to non-detectable levels compared to heating alone at 72 h PH. Secretion of OCN, OPN, and OPG increased with the addition of GFs but diminished with heating as measured by ELISA at 72 h PH. These results suggest that conditioning protocols utilizing heating and GFs individually or in combination can induce HSPs, bone-related proteins, and VEGF while also causing downregulation of osteoclastic activity, potentially providing a promising bone therapeutic strategy.     

Role of Silicon in Diatom Metabolism

The in vivo uptake of ³¹Si-silicic acid and ⁶⁸Ge-germanic acid by cell organelles of Nitzschia alba Lewin and Lewin and Cylindrotheca fusiformis Reimann and Lewin was demonstrated. The organelles were isolated by fractionation of pre-labeled cells by differential centrifugation in 0.4 M sucrose medium. Electron micrographs showed that the isolated organelles were intact, with the exception of the N. alba mitochondria which appeared swollen and the C. fusiformis chloroplasts which had ruptured outer membranes and lacked stroma material. The amount of ³¹Si or ⁶⁸Ge per mg protein of the subcellular fractions decreased in the following general order for both organisms: cell wall, mitochondria, chloroplasts, vesicles, and microsomes. A portion of the ³¹Si or ⁶⁸Ge in the organelle fractions could be extracted into a distilled water wash. The uptake of silicon by the organelles suggests that silicon may be involved in some processes of the compartmentalized systems of the cell.