Supraoptimal growth-temperature reduces the heat-shock sensitivity of the chrysophycean flagellatePoterioochromonas malhamensis

Summary The chrysophycean flagellatePoterioochromonas malhamensis shows some characteristic alterations after a sublethal heat-shock (42 C, 16 minutes). Most cells round up and retract their cytoplasmic tail. The lorica formation is affected and, in nearly all cells, flagellar activity. Most membrane systems, especially the dictyosome, are severely damaged. In contrast the flagellar root apparatus and the cortical microtubules seem to be unaffected.After growth at a supraoptimal temperature of 33 C and a subsequent heat-shock (42 C, 16 minutes) the cells do not show the heat injuries reported above. The ability to form the lorica becomes also adapted to higher temperatures.Possible adaptation mechanisms are discussed.     

Heat sensitivity and protein synthesis during heat-shock in the tobacco hornworm,Manduca sexta

Summary Fifth instar larvae of the tobacco hornworm,Manduca sexta, tolerate 1-h exposures to temperatures as high as 42°C. Above 42°C, survival declines rapidly to 18% at 44°C and 0% at 48°C. As in other insects, the heat-shock response ofManduca sexta involves the induction of synthesis of heat-shock proteins very similar in size to theDrosophila heat-shock proteins (84, 73, 71, 27, 25, 23, and 22 kd). In the epidermis, heat-shock protein synthesis peaks at 42°C, correlating with the heat sensitivity of both the tissue itself and the intact larva. Some heat-shock proteins have different isoelectric forms depending on tissue. Also, the heat-shock proteins are synthesized over a wider range of temperatures in the imaginal discs and the fat body as compared to the epidermis. In contrast to dipteran insects,Manduca sexta does not exhibit a strong repression of non-heat-shock protein synthesis under tolerable conditions.Abbreviations TCA trichloroacetic acid - PAGE polyacrylamide gel electrophoresis - AZT arbitrary Zeitgeber time - kd kilodaltons     

Evidence for protection by heat-shock proteins against photoinhibition during heat-shock

The nuclear-coded 22 kd heat-shock protein (HSP-22) which is transported into the chloroplast and localized in the thylakoids was further characterized and found to be located in the grana lamellae (stacked thylakoids) as an extrinsic protein in the green alga Chlamydomonas reinhardtii. Inhibition of photosynthetic electron flow during heat-shock of Chlamydomonas cells was light-dependent, occurring at low-light intensities (<100 W/m²) as compared with photoinhibition at 25°C (>1000 W/m²). The site of the damage was localized at the photosystem II (PS II) reaction center. The damage was drastically increased when heat-shock treatment was carried out in the presence of the 80S ribosomal translation inhibitor, cycloheximide (CHI). Pre-incubation of Chlamydomonas cells at 42°C resulted in partial protection against photoinhibition during heat-shock, as compared with cells pre-incubated at 42°C in the presence of CHI which, therefore, did not translate the heat-shock proteins. Analysis of the thylakoid polypeptides' pattern by SDS-PAGE revealed that during heat-shock in the light, thylakoid proteins became aggregated proportionally to the light intensity. Heat-shock in the presence of CHI enhanced the aggregation process which, at low light intensities, was specific to the PS II reaction center D1-protein. The results suggest that the chloroplasts HSPs prevent damage to the PS II reaction center during heat-shock in the light.     

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.     

Functional mode of NtHSP17.6, a cytosolic small heat-shock protein fromNicotiana tabacum

Small heat-shock proteins (sHsps) are ubiquitous stress proteins with molecular chaperone activity. They share characteristic homology with the α-crystallin protein of the mammalian eye lens as well as being ATP-independent in their chaperone activity. We isolated a clone for a cytosolic class I sHsp,NtHSP17.6, fromNicotiana tabacum, and analyzed its functional mode for such activity. Following its transformation intoEscherichia coli and its over-expression, NtHSPI 7.6 was purified and examinedin vitro. This purified NtHSPI 7.6 exhibited typical chaperone activity in a light-scattering test. It was enable to protect a model substrate, firefly luciferase, from heat-induced aggregation. Non-denaturing PAGE showed that NtHSP17.6 formed a dodecamer in its native conformation, and was bound to its substrate under heat stress. A labeling test with bis-ANS indicated that this binding might be linked to newly exposed hydrophobic sites of the NtHSPI 7.6 complexes during heat shock. Based on these data, we suggest that NtHSP17.6 is a molecular chaperone that functions as a dodecamer in a heat-induced manner.     

Wound-induced PAL activity is suppressed by heat-shock treatments that induce the synthesis of heat-shock proteins

Wounding lettuce leaves induces the de novo synthesis of phenylalanine ammonia-lyase (PAL, EC 4.3.1.5), the accumulation of phenolic compounds, and subsequent tissue browning. A brief heat-shock at 45°C reduces the rise in wound-induced PAL, the accumulation of phenolic compounds, and tissue browning. The activity of PAL measured 24 h after wounding and the content of phenolic compounds (absorbance of methanol extract at 320 nm) measured 48 h after wounding was highly correlated (R² > 0.90) in tissue developing the normal wound response and in tissue subjected to 0–180 s of heat-shock after wounding. The synthesis of a unique set of proteins called heat-shock proteins (hsps) is induced by these heat-shock treatments. Western-blot analyses of proteins isolated from wounded and heat-shocked Iceberg and Romaine lettuce mid-rib leaf tissue was done using antibodies against hsp 23. Only those heat-shock treatments that were effective at inducing the synthesis of hsp 23 were effective in reducing the activity of PAL induced by wounding and the subsequent accumulation of phenolic compounds. Hsps induced in non-wounded, whole leaves by exposure to 45°C for 150 s did not significantly interact with PAL previously synthesized in non-heat-shocked wounded leaves to limit its activity. The preferential synthesis of hsps over that of wound-induced PAL, rather than the presence of hsps, may be responsible for the ability of a heat-shock treatment to reduce the wound-induced increase in PAL activity. Our results support this novel concept, and the possibility that heat-shock treatments can have significant physiological effects on the response of the tissue to other stresses, not because of the specific genes they induce or repress, or the products they cause to be synthesized, but by their secondary action of influencing the synthesis of other proteins (e.g. PAL) by the suppression of non-hsps protein synthesis.     

Isolation and physical mapping of temperature-sensitive mutants defective in heat-shock induction of proteins in Escherichia coli

Summary Mutants of Escherichia coli K12 that are partially or totally defective in induction of major heat-shock proteins and cannot grow at high temperature (42° C) were isolated by localized mutagenesis. These mutants carry a single mutation in the gene htpR (formerly hin) located at min 76 on the E. coli genetic map. Some mutants exhibit delayed (partial) induction of heat-shock proteins or require a higher temperature for induction than the wild type, whereas others are not induced under any of these conditions. The maximum temperature that allows growth varies among different mutants and is correlated with the residual induction capacity. Temperature-resistant revertants obtained from each mutant are fully or partially recovered in heat-shock induction. These results indicate that the inability of htpR mutants to grow at high temperature is due to the defect in heat-shock induction. In addition, a couple of mutants was found that produce significantly higher amounts of heat-shock proteins even at 30° C.The htpR gene has been cloned into plasmid pBR322 using the above mutants, and was localized to a DNA segment of 1.6 kilobase pairs. The mutants harboring certain palsmids that carry a part of htpR produce temperature-resistant recombinants at high frequency. This permits further localization of mutations within the htpR gene. Analysis of proteins encoded by each of the recombinant plasmids including the one carrying a previously isolated amber mutation (htpR165) led to the identification of a protein with an apparent molecular weight of about 36,000 daltons as the htpR gene product.     

Relationship between heat-shock protein synthesis and thermotolerance in rainbow trout fibroblasts

Summary The role of heat-shock protein synthesis in the development of thermotolerance by rainbow trout fibroblasts was examined. During the first 6 h after being shifted from 22°C to 28°C, cells of the rainbow trout fibroblast line, RTG-2, rapidly synthesized the major heat-shock proteins (hsps), hsps 87, 70 and 27, and developed tolerance to 32°C. After 24 h at 28°C hsp synthesis was drastically reduced but thermotolerance was maintained. If these thermotolerant cells were shifted to 32°C, hsp synthesis continued at a very low level, but if they were subsequently returned to 22°C, synthesis of hsps 70 and 27 was induced again. The addition of actinomycin D during the first 6 h at 28°C prevented hsp synthesis and the development of thermotolerance. The presence of actinomycin D during the incubation of thermotolerant cultures at 32°C blocked the reinitiation of hsps synthesis at 22°C but had no effect on survival. Therefore, the hsps that accumulated at 28°C were sufficient to allow cells to survive a subsequent thermal stress at 32°C.     

Spinach leaf 70-kilodalton heat-shock cognate stabilizes bovine adrenal glucose-6-phosphate dehydrogenase in vitro without apparent stable binding

Spinach (Spinacia oleracea L.) leaf tissue 70-kilodalton heat-shock cognate was purified by ATP-agarose affinity and gel filtration. Gel filtration of the affinity-purified protein resolved it into three forms: monomer, dimer, and oligomer. In the absence of ATP, the majority of the heat-shock cognate existed as a monomeric form with lesser amounts of dimer and oligomer. Addition of 3 mM ATP to the purified protein, containing all three forms, converted the dimeric and monomeric forms to a high-molecular-weight complex. Removal of ATP from the complex by dialysis resulted in the reappearance of the dimeric and monomeric forms. Addition of ATP to the highly purified monomer had no effect on its gel-filtration migration. Neither purified monomeric or dimeric forms showed stable binding to denatured proteins; however, both forms of the purified heat-shock cognate were able to stabilize the enzymatic activity of bovine adrenal glucose-6-phosphate dehydrogenase over a 48-h period at 25° C. In addition, the activity of glucose-6-phosphate dehydrogenase in the presence of purified heat-shock cognate dimer or monomer could be rapidly decreased in an ATP-dependent fashion depending on the order of the substrate addition to the reaction mixture. Circular-dichroism studies indicated that addition of ATP to the spinach 70-kDa heat-shock cognate caused a conformation change from -helical to a greater -sheet content. How conformational character may influence the stabilizing activity of the heat-shock cognate in a mechanism which does not require stable peptide binding is discussed.Abbreviations BiP immunoglobulin binding protein - BSA bovine serum albumin - CA carbonic anhydrase - CD circular dichroism - G6PDH glucose-6-phosphate dehydrogenase - HSP heat shock protein - HSP70 70-kilodalton heat shock protein - HSC70 70-kilodalton heat-shock cognate - MDH malate dehydrogenase - PVDF polyvinylidene difluoride The authors wish to thank C. Kaye and R. Henry for their critical review and discussion of this paper. The antibody for tobacco BiP was the generous gift of J. Denecke. Financial support for this work was provided by the National Science Foundation DCB 9017625. This is Florida Agricultural Experiment Station Journal Series No. R-04110.     

Connections between dictyosomes,ER and GERL in cotyledons of mung bean (Vigna radiata L.)

Summary The connections and structural inter-relations of dictyosomes and endoplasmic reticulum (ER) in cotyledons of germinating mung beans were studied using thick (0.3 m) sections of aldehyde fixed, zinc iodide-osmium tetroxide (ZIO) impregnated tissue. The sections were examined by conventional (100 kV), rather than high voltage, transmission electron microscopy.Continuity of cisternal ER with tubular ER was confirmed and a direct connection of tubular ER totrans dictyosome cisternae was observed as were GERL networks associated withtrans dictyosome cisternae.Dictyosomes also gave rise to an extensive system of very fine tubules (10–20 nm diam) which have not been described previously in plant tissue. These tubules, which originated at thetrans dictyosome face, extended throughout the cytoplasm and were found connected to cisternal ER and tubular ER.The implications of these observations are discussed with regard to present ideas concerning endomembrane flow and protein sorting by the Golgi apparatus.     

The heat-shock response in xenopus oocytes is controlled at the translational level

Xenopus laevis oocytes respond to high temperature (>31°C) by the synthesis of one major (70 kilodalton) protein and by a gradual reduction in the rate of normal protein synthesis. In contrast with most other cells, the heat-shock response of Xenopus oocytes is controlled exclusively at the translational level. Enucleated or α-amanitin-injected oocytes synthesize normal levels of heat-shock protein. Thus high temperature induces the translation of preformed heat-shock mRNA. This continues for more than a day after a shift back to a normal temperature, but ceases within 2 days. Heat-shock protein synthesis can be sequentially induced and inactivated in the same oocyte over several days. We conclude that an oocyte contains 10–100 pg of heat-shock mRNA, which is synthesized during oogenesis at the normal temperature, and which is stored in an inactive state by a “masking” mechanism.     

Characterization of the thermotolerant cell. II. Effects on the intracellular distribution of heat-shock protein 70, intermediate filaments, and small nuclear ribonucleoprotein complexes

Here we further characterize a number of properties inherent to the thermotolerant cell. In the preceding paper, we showed that the acquisition of the thermotolerant state (by a prior induction of the heat-shock proteins) renders cells translationally tolerant to a subsequent severe heat-shock treatment and thereby results in faster kinetics of both the synthesis and subsequent repression of the stress proteins. Because of the apparent integral role of the 70-kD stress proteins in the acquisition of tolerance, we compared the intracellular distribution of these proteins in both tolerant and nontolerant cells before and after a severe 45 degrees C/30-min shock. In both HeLa and rat embryo fibroblasts, the synthesis and migration of the major stress-induced 72-kD protein into the nucleolus and its subsequent exit was markedly faster in the tolerant cells as compared with the nontolerant cells. Migration of preexisting 72-kD into the nucleolus was shown to be dependent upon heat-shock treatment and independent of active heat-shock protein synthesis. Using both microinjection and immunological techniques, we observed that the constitutive and abundant 73-kD stress protein similarly showed a redistribution from the cytoplasm and nucleus into the nucleolus as a function of heat-shock treatment. We show also that other lesions that occur in cells after heat shock can be prevented or at least minimized if the cells are first made tolerant. Specifically, the heat-induced collapse of the intermediate filament cytoskeleton did not occur in cells rendered thermotolerant. Similarly, the disruption of intranuclear staining patterns of the small nuclear ribonucleoprotein complexes after heat-shock treatment was less apparent in tolerant cells exposed to a subsequent heat-shock treatment.     

Synthesis of heat-shock proteins in Saccharomyces cerevisiae protoplasts

The effect of cellular capsule elimination in Saccharomyces cerevisiae yeasts (protoplast formation) on the heat-shock protein synthesis and the synthesis of the proteins in protoplasts were studied. The methods of mono- and dimeric electrophoresis have demonstrated that (1) about 18 heat-shock proteins with the molecular masses 26-98 Kd are synthesized in cells at 41 degrees C; (2) protoplast formation per se does not induce the synthesis of heat-shock proteins, but the induction of these proteins in protoplasts at 41 degrees C is similar to the one in intact cells. The protoplast formation induces the synthesis of specific proteins different from heat-shock proteins and the synthesis is inhibited by the heat-shock. The heat-shock induces modification of 88 and 86 Kd heat-shock proteins. It inhibits the synthesis of a number of peptides (15-50 Kd) in cells and protoplasts.     

Induction of Hsp70 by desiccation, ionising radiation and heat-shock in the eutardigrade Richtersius coronifer

The physiology and biochemistry behind the extreme tolerance to desiccation shown by the so-called anhydrobiotic animals represents an exciting challenge to biology. The current knowledge suggests that both carbohydrates and proteins are often involved in protecting the dry cell from damage, or in the repair of induced damage. Tardigrades belong to the most desiccation-tolerant multicellular organisms, but very little research has been reported on the biochemistry behind desiccation tolerance in this group. We quantified the induction of the heat-shock protein Hsp70, a very wide-spread stress protein, in response to desiccation, ionising radiation, and heating, in the anhydrobiotic tardigrade Richtersius coronifer using an immuno-westernblot method. Elevated levels of Hsp70 were recorded after treatment of both heat and ionising radiation, and also in rehydrated tardigrades after a period of desiccation. In contrast, tardigrades in the desiccated (dry) state had reduced Hsp70 levels compared to the non-treated control group. Our results suggest that Hsp70 may be involved in the physiological and biochemical system underlying desiccation (and radiation) tolerance in tardigrades, and that its role may be connected to repair processes after desiccation rather than to biochemical stabilization in the dry state.     

Heat-resistance and heat-shock response in the nosocomial pathogen Enterococcus faecium

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 degrees C, and no growth at 52 degrees C or 55 degrees C. In agreement, a marked decrease of general protein synthesis was observed at 52 degrees C, and very light synthesis was detected at 55 degrees C. The heat resistance of E. faecium cells was analyzed by measuring the survival at temperatures higher than 52 degrees C and, after 2 h of incubation, viable cells were still observed at 70 degrees 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.     

Production of stress-inducible form of heat-shock protein 70 in mouse peritoneal adherent cells afterin Vivo infection byFrancisella tularensis

Heat-shock proteins (hsp) are ubiquitously produced molecules which participate in the protection of cells from environmental perturbation. Moreover, the members of the heat-shock protein 60 (hsp60) and 70 (hsp70) families play an important role in pathogen-host interactions. We studiedin vivo production of the 70-kDa heat-shock proteins in the extract of peritoneal exudate cells (PEC) from mice injected intraperitoneally with an attenuated vaccine strain (LVS) ofFrancisella tularensis. We found a differential production of a highly stress-inducible member of the hsp70 family, designated hsp72, in three inbred strains of mice exhibiting either resistance or susceptibility toF. tularensis LVS infection. Whereas in tularemia-resistant mice hsp72 was even expressed in PEC without injection of bacteria and its production further increased on day 3 and slowly declined on days 5 and 7 after injection, in susceptible mice hsp72 production was highly inducble and restricted only to day 3 afterin vivo infection. Further analysis of hsp72 expression revealed intracellular hsp72 accumulation and its preferential production by peritoneal adherent cells.     

The endomembrane system and mechanism of membrane flow in the green alga,Gloeomonas kupfferi (Volvocales,Chlorophyta) I. An ultrastructural analysis

Summary The endomembrane system of the chlamydomonad flagellate,Gloeomonas kupfferi (Chlorophyta), is complex. It consists of a proliferating ER network, a perinuclear complex of 14–18 dictyosomes and 8–12 vacuoles and an anterior contractile vacuole complex. The ER network extends from the nuclear envelope outwards, ensheafhs a dictyosome, extends out through a lobe of the chloroplast and terminates in the thin zone of peripheral cytoplasm between the chloroplast and plasmamembrane. The individual dictyosome is polar with distinct cis- and trans-faces. The cis-face is closely associated with transition vesicles emerging from the adjacent ER. Large vesicles emerge from peripheral swellings of terminal cisternae. The dictyosome-associated ER is connected to the peripheral vacuolar system. During cell division and cytokinesis, changes in the endomembrane system occur. Dictyosomes divide and quickly separate to form perinuclear complexes around the daughter nuclei. Each dictyosome undergoes morphological changes during this wall precursor-producing stage. ER lines the furrow zone and is closely associated with phycoplast microtubules. A discussion of the endomembrane system in membrane flow mechanics is provided.Abbreviations ER endoplasmic reticulum - OsFeCN Osmium ferricyanide