Heat-shock response in Legionella pneumophila

The heat-shock response of Legionella pneumophila was examined by radiolabelling bacterial cell proteins with [35S]methionine following a temperature shift from 30 to 42 degrees C. Five heat-shock proteins were identified as having molecular masses of 17, 60, 70, 78, and 85 kilodaltons (kDa). The 85- and 60-kDa proteins were equally distributed between supernatant and pellet fractions following ultracentrifugation at 100,000 x g, the 70- and 78-kDa proteins were found primarily in the supernatant, and the 17-kDa protein was found primarily in the pellet. Synthesis of subsets of the heat-shock proteins could be stimulated by novobiocin, patulin, or puromycin. Ethanol, an effector of the heat-shock response in other microorganisms, had little effect on L. pneumophila, even at the highest concentration tolerated by the bacterial cells (1.9%). Finally, the 60-kDa heat-shock protein of L. pneumophila was immunologically cross-reactive with a polyclonal antibody prepared to the Escherichia coli groEL protein. However, a mouse monoclonal antibody reactive with the 60-kDa protein of all legionellae tested did not cross-react with the E. coli groEL protein, suggesting that the Legionella 60-kDa protein contains common and unique epitopes.     

Heat-shock response in germinating pine pollen

Summary The in vitro culture of pine pollen at various temperatures reveals only a moderate degree of thermotolerance, with considerably reduced levels of growth at and above 35° C. Unlike the pollen of many previously studied species, pine pollen shows some ability to recover from short periods of growth at temperatures as high as 40° C, especially when such exposures occur during the early stages of pollen germination. The pollen of Pinus taeda, unlike that of most other species, shows both quantitative and qualitative changes in the proteins synthesized during germination in vitro following a switch to elevated temperatures (37° C). This response, which can be elicited both during the very early stages of germination as well as during the later stages of pollen tube growth, is reversible following a shift back to the lower temperatures. As previously shown with vegetative tissue of other plant species, the heat-shock response not only involves the induction of high-molecular-weight proteins (most notably 82 kDa and 70 kDa proteins), but also a number of low-molecular-weight (10–20 kDa) species. Two-dimensional gel electrophoretic analysis reveals a small number of qualitative differences in the types of low-molecular-weight heat-shock proteins synthesized in pollen versus vegetative tissue.     

Cold stress response in Archaea

We live on a cold planet where more than 80% of the biosphere is permanently below 5°C, and yet comparatively little is known about the genetics and physiology of the microorganisms inhabiting these environments. Based on molecular probe and sequencing studies, it is clear that Archaea are numerically abundant in diverse low-temperature environments throughout the globe. In addition, non-low-temperature-adapted Archaea are commonly exposed to sudden decreases in temperature, as are other microorganisms, animals, and plants. Considering their ubiquity in nature, it is perhaps surprising to find that there is such a lack of knowledge regarding low-temperature adaptation mechanisms in Archaea, particularly in comparison to what is known about archaeal thermophiles and hyperthermophiles and responses to heat shock. This review covers what is presently known about adaptation to cold shock and growth at low temperature, with a particular focus on Antarctic Archaea. The review highlights the similarities and differences that exist between Archaea and Bacteria and eukaryotes, and addresses the potentially important role that protein synthesis plays in adaptation to the cold. By reviewing the present state of the field, a number of important areas for future research are identified. Received: August 10, 2000 / Accepted: September 26, 2000     

Heat-shock and general stress response in Bacillus subtilis

The induction of stress proteins is an important component of the adaptional network of a non-growing cell of Bacillus subtilis . A diverse range of stresses such as heat shock, salt stress, ethanol, starvation for oxygen or nutrients etc. induce the same set of proteins, called general stress proteins. Although the adaptive functions of these proteins are largely unknown, they are proposed to provide general and rather non-specific protection of the cell under these adverse conditions. In addition to these non-specific general stress proteins, all extracellular signals induce a set of specific stress proteins that may confer specific protection against a particular stress factor. In B. subtilis at least three different classes of heat-inducible genes can be defined by their common regulatory characteristics: Class I genes, as exemplified by the dnaK and groE operons, are most efficiently induced by heat stress. Their expression involves a σ^A-dependent promoter, an inverted repeat (called the CIRCE element) highly conserved among eubacteria, and probably a repressor interacting with the CIRCE element. The majority of general stress genes (class II, more than 40) are induced at σ^B-dependent promoters by different growth-inhibiting conditions. The activation of σ^B by stress or starvation is the crucial event in the induction of this large stress regulon. Only a few genes, including lon clpC clpP , and ftsH, can respond to different stress factors independently of σ^B or CIRCE (class III). Stress induction of these genes occurs at promoters presumably recognized by σ^A and probably involves additional regulatory elements which remain to be defined.     

Heat-shock response of rat hepatoma variant cells

The effect of mild heat shock on protein synthesis was examined in differentiated and dedifferentiated, glucocorticoid-sensitive and resistant clones of H4IIEC3 rat hepatoma cells by one- and two-dimensional gel electrophoresis of [35S]methionine-labeled proteins. Among the major heat-shock proteins, five were induced in all hepatoma clones. Certain members of the HSP70 family and the corresponding mRNAs were only slightly inducible in the glucocorticoid-resistant variants, but were strongly inducible in the sensitive ones. Three other proteins lacked heat inducibility in the dedifferentiated clones. The constitutive level of one major heat-shock protein was elevated in all dedifferentiated variants. These results show that the stage of differentiation influences the expression of heat-shock genes of hepatoma cells. We found no correlation between the elevated constitutive or induced level of heat-shock proteins and heat resistance.     

Heat-shock response in Fonsecaea pedrosoi, a pathogenic fungus.

Using two-dimensional electrophoresis we have investigated the heat-shock response in a pathogenic fungus, Fonsecaea pedrosoi. Fungal cultures were transferred from 37 to 45 degrees C for either 30 or 90 min and then returned back to the initial temperature. Analysis of the total proteins resolved on two-dimensional gels indicated important changes in the accumulation of several peptides according to the duration of treatment and the temperature. The 30-min incubation at 45 degrees C resulted in the induction of several new proteins, whereas other proteins were either increased or decreased. These inductions and repressions of proteins (called heat-shock and heat-stroke proteins, respectively) were either specific to this time period or still present after a 90-min incubation. In addition, the 90-min incubation period led to the enhancement of several proteins, which were therefore called late heat-shock proteins to distinguish them from the early ones detected after 30 min. Finally, when cultures were shifted back to 37 degrees C most of the heat-shock proteins decreased or disappeared; in parallel, most of the heat-stroke proteins were reinduced at this time. These results are in good agreement with previous studies on the heat-shock response and provide additional evidence that this phenomenon is highly conserved among species.     

Heat-shock response in Xenopus oocytes during meiotic maturation and activation

After a 60 min heat-shock at 36 degrees C, Xenopus oocytes are still able to accomplish a complete meiotic maturation in response to a progesterone treatment. The 36 degrees C heat-shock applied to maturing oocytes strongly enhances the synthesis of a single heat-shock protein of approx. 70 000 molecular weight (hsp70); after activation with the Ca2+-ionophore A 23187, matured oocytes still display the ability to synthesize hsp70 and to survive a heat-shock. A cycloheximide treatment combined with a heat-shock induces, during the recovery period, the synthesis of two heat-shock proteins, of approx. 70 000 and 83 000 molecular weight.     

Heat-shock response in Arabidopsis thaliana explored by multiplexed quantitative proteomics using differential metabolic labeling

We have developed a general method for multiplexed quantitative proteomics using differential metabolic stable isotope labeling and mass spectrometry. The method was successfully used to study the dynamics of heat-shock response in Arabidopsis thaliana. A number of known heat-shock proteins were confirmed, and some proteins not previously associated with heat shock were discovered. The method is applicable in stable isotope labeling and allows for high degrees of multiplexing.     

植物热激蛋白

对近年来高等植物热激蛋白和主要热激蛋白在植物抗高温响应中的作用及其功能机理作了介绍和评述。     

Heat-shock response in cultured chick embryo chondrocytes. Osteonectin is a secreted heat-shock protein.

We investigated the induction of specific protein expression by heat shock in dedifferentiated and hypertrophic chick embryo chondrocytes in a culture system that allows 'in vitro' differentiation of cartilage cells [Castagnola, P., Moro, G., Descalzi-Cancedda, F. and Cancedda, R. (1986) J. Cell. Biol. 102, 2310-2317]. As control, we used cultures of embryonic fibroblasts from the whole body and from the skin. In the cell lysates of all cultures we identified four major heat-shock proteins (HSP), with a molecular size corresponding to HSP families previously described (HSP 90, HSP 70, HSP 47 and HSP 26). Some of these proteins were constantly induced when the temperature was raised, others were expressed in a more variable manner. Differences also existed in the relative amount of the HSP synthesized by the four cultures. When we specifically investigated HSP species released into the culture medium, we observed a 43-45 kDa protein constantly expressed and secreted in large amount by the cells. On the basis of its biochemical characteristic and its precipitation by specific antibodies, this protein has been identified as osteonectin (SPARC, BM-40).     

Heat-shock response and antioxidant defense during air exposure in Patagonian shallow-water limpets from different climatic habitats

Climate warming involves not only a rise of air temperature means, but also more frequent heat waves in many regions on earth, and is predicted to intensify physiological stress especially in extremely changeable habitats like the intertidal. We investigated the heat-shock response (HSR) and enzymatic antioxidant defense levels of Patagonian shallow-water limpets, adapted to distinct tidal exposure conditions in the sub- and intertidal. Limpets were sampled in the temperate Northern Patagonia and the subpolar Magellan region. Expression levels of two Hsp70 genes and activities of the antioxidants superoxide dismutase (SOD) and catalase (CAT) were measured in submerged and 2- and 12-h air-exposed specimens. Air-exposed Patagonian limpets showed a tiered HSR increasing from South to North on the latitudinal gradient and from high to low shore levels on a tidal gradient. SOD activities in the Magellan region correlated with the tidal rhythm and were higher after 2 and 12 h when the tide was low at the experimental site compared to the 6 h value taken at high tide. This pattern was observed in intertidal and subtidal specimens, although subtidal individuals are little affected by tides. Our study shows that long-term thermal adaptation shapes the HSR in limpets, while the oxidative stress response is linked to the tidal rhythm. Close to the warm border of their distribution range, energy expenses to cope with stress might become overwhelming and represent one cause why the limpets are unable to colonize the shallow intertidal zone.     

Thymidine Kinases in Archaea

Twenty-six fully sequenced archaeal genomes were searched for genes coding for putative deoxyribonucleoside kinases (dNKs). We identified only 5 human-like thymidine kinase 1 genes (TK1s) and none for non-TK1 kinases. Four TK1s were identified in the Euryarchaea and one was found in the Crenarchaea, while none was found in Nanoarchaeum. The identified TK1s have high identity to Gram-positive bacteria TK1s. The TK1s from archaea, Gram-positive bacteria and eukaryotes share the same common ancestor, while the TK1s from Gram-negative bacteria belong to a less-related subgroup. It seems that a functional deoxyribonucleoside salvage pathway is not crucial for the archaeal cell.     

Heat-shock response of the upper intertidal barnacle Balanus glandula: thermal stress and acclimation

In the intertidal zone in the Pacific Northwest, body temperatures of sessile marine organisms can reach 35 degrees C for an extended time during low tide, resulting in potential physiological stress. We used immunochemical assays to examine the effects of thermal stress on endogenous Hsp70 levels in the intertidal barnacle Balanus glandula. After thermal stress, endogenous Hsp70 levels did not increase above control levels in B. glandula exposed to 20 and 28 degrees C. In a separate experiment, endogenous Hsp70 levels were higher than control levels when B. glandula was exposed to 34 degrees C for 8.5 h. Although an induced heat-shock response was observed, levels of conjugated ubiquitin failed to indicate irreversible protein damage at temperatures up to 34 degrees C. With metabolic labeling, we examined temperature acclimation and thermally induced heat-shock proteins in B. glandula. An induced heat-shock response of proteins in the 70-kDa region (Hsp70) occurred in B. glandula above 23 degrees C. This heat-shock response was similar in molting and non-molting barnacles. Acclimation of B. glandula to relatively higher temperatures resulted in higher levels of protein synthesis in the 70-kDa region and lack of an upward shift in the induction temperature for heat-shock proteins. Our results suggest that B. glandula may be well adapted to life in the high intertidal zone but may lack the plasticity to acclimate to higher temperatures.     

Transcriptional regulation in Archaea

During the past few decades, it has become clear that microorganisms can thrive under the most diverse conditions, including extremes of temperature, pressure, salinity and pH. Most of these extremophilic organisms belong to the third domain of life, that of the Archaea. The organisms of this domain are of particular interest because most informational systems that are associated with archaeal genomes and their expression are reminiscent of those seen in Eucarya, whereas, most of their metabolic aspects are similar to those of Bacteria. A better understanding of the regulatory mechanisms of gene expression in Archaea will, therefore, help to integrate the body of knowledge regarding the regulatory mechanisms that underlie gene expression in all three domains of life.