Characterization of the heat shock response inEnterococcus faecalis

We have characterized the general properties of the heat shock response of the Gram-positive hardy bacteriumEnterococcus faecalis. The heat resistance (60°C or 62.5°C, 30 min) of log phase cells ofE. faecalis grown at 37°C was enhanced by exposing cells to a prior heat shock at 45°C or 50°C for 30 min. These conditioning temperatures also induced ethanol (22%, v/v) tolerance. The onset of thermotolerance was accompanied by the synthesis of a number of heat shock proteins. The most prominent bands had molecular weights in the range of 48 to 94kDa. By Western blot analysis two of them were found to be immunologically related to the well known DnaK (72 kDa) and GroEL (63 kDa) heat shock proteins ofEscherichia coli. Four other proteins showing little or no variations after exposure to heat are related to DnaJ, GrpE and Lon (La)E. coli proteins and to theBacillus subtilis ⁴³ factor. Ethanol (2% or 4%, v/v) treatments elicited a similar response although there was a weaker induction of heat shock proteins than with heat shock.     

Heat shock-induced protein synthesis inLactococcus lactis subsp.lactis

Heat shock inLactococcus lactis subsp.lactis may induce as many as 16 proteins after a temperature shift from 30° to 40°C. Five induced proteins were found to be immunologically related to theEscherichia coli GroEL, DnaK, DnaJ, and GrpE proteins, and to theBacillus subtilis ⁴³ factor. From these initial studies we conclude that, inL. lactis subsp.lactis, a heat shock response similar to that known to occur in other prokaryotes might exist.     

Synthesis of heat shock proteins inThermoanaerobacterium thermosulfurigenes EM1 (Clostridium thermosulfurogenes EM1)

The response to heat stress was examined inThermoanaerobacterium thermosulfurigenes EM1. Upon a temperature shift-up from 50° to 62°C, four heat shock proteins (hsps) were synthesized at an elevated level. Two proteins were found to be immunologically related to theEscherichia coli GroEL protein and theMycobacterium tuberculosis hsp71 (DnaK similar protein), and the correspondinggroE anddnaK homologous sequences were detected in the chromosome ofT. thermosulfurigenes EM1. The heat shock response in this thermophile was transient, with a maximum synthesis of hsps between 10 and 15 min after the shock. The enhanced synthesis of DnaK and GroEL was consistent with increased mRNA levels of the genes, which reached a maximum 15 min after heat treatment.     

Molecular characterization of specific heat shock proteins inBacillus subtilis

Heat shock inBacillus subtilis may induce as many as 66 proteins after temperature upshift from 37° to 48°C. Four induced proteins were analyzed by microsequencing techniques. These were identified as the homologues for GroEL, DnaK, enolase, and glyceraldehyde-3-phosphate dehydrogenase (GAPDH), which are heat shock proteins in other systems. The identities of GroEL and DnaK were confirmed additionally by Western blot analysis. As a control, a protein whose synthesis was repressed approximately threefold by heat shock was identified by microsequencing as flagellin.     

Characterization of the Heat Shock Response in Lactococcus lactis subsp. lactis

The heat shock response in Lactococcus lactis subsp. lactis was characterized with respect to synthesis of a unique set of proteins induced by thermal stress. A shift in temperature from 30 to 42°C was sufficient to arrest the growth of L. lactis subsp. lactis, but growth resumed after a shift back to 30°C. Heat shock at 50°C reduced the viable cell population by 10³; however, pretreatment of the cells at 42°C made them more thermoresistant to exposure at 50°C. The enhanced synthesis of approximately 13 proteins was observed in cells labeled with ³⁵S upon heat shock at 42°C. Of these heat shock-induced proteins, two appeared to be homologs of GroEL and DnaK, based on their molecular weights and reactivity with antiserum against the corresponding Escherichia coli proteins. Therefore, we conclude that L. lactis subsp. lactis displays a heat shock response similar to that observed in other mesophilic bacteria.     

Cold-active DnaK of an Antarctic psychrotroph Shewanella sp. Ac10 supporting the growth of dnaK-null mutant of Escherichia coli at cold temperatures

Shewanella sp. Ac10 is a psychrotrophic bacterium isolated from the Antarctica that actively grows at such low temperatures as 0°C. Immunoblot analyses showed that a heat-shock protein DnaK is inducibly formed by the bacterium at 24°C, which is much lower than the temperatures causing heat shock in mesophiles such as Escherichia coli. We found that the Shewanella DnaK (SheDnaK) shows much higher ATPase activity at low temperatures than the DnaK of E. coli (EcoDnaK): a characteristic of a cold-active enzyme. The recombinant SheDnaK gene supported neither the growth of a dnaK-null mutant of E. coli at 43°C nor phage propagation at an even lower temperature, 30°C. However, the recombinant SheDnaK gene enabled the E. coli mutant to grow at 15°C. This is the first report of a DnaK supporting the growth of a dnaK-null mutant at low temperatures.     

Co-induction of DNA relaxation and synthesis of DnaK and GroEL proteins inEscherichia coli by expression of LetD (CcdB) protein, an inhibitor of DNA gyrase encoded by the F factor

We examined the influence of overexpression of LetD (CcdB) protein, an inhibitor of DNA gyrase encoded by the F factor ofEscherichia coli, on DNA supercoiling and induction of heat shock proteins. Cells were transformed with a plasmid carrying the structural gene for LetD protein under control of thetac promoter, and LetD protein was induced by adding isopropyl-d-thiogalactopyranoside (IPTG) to the culture medium. Analysis by agarose gel electrophoresis in the presence of chloroquine revealed relaxation of plasmid DNA in cells depending on the concentration of IPTG employed for induction. Protein pulse-labeling experiments with [³⁵S]methionine and cysteine revealed that synthesis of DnaK and GroEL proteins was also induced by IPTG, and concentrations necessary for DNA relaxation and induction of the heat shock proteins were much the same. Expression of mutant LetD protein lacking two amino acid residues at the C-terminus induced neither DNA relaxation nor the synthesis of DnaK and GroEL proteins. Induction of wild-type LetD protein but not mutant LetD protein markedly enhanced synthesis of ³². We interpret these results to mean that DNA relaxation in cells caused by the expression of LetD protein induces heat shock proteins via increased synthesis of ³².     

Stress proteins of<Emphasis Type="Italic"> Clostridium perfringens</Emphasis> type A immunoreact with antiserum from rabbits infected with gas gangrene

Various stressors were used to induce stress proteins in Clostridium perfringens. Cultures of C. perfringens FD-1041 were subjected to cold shock (28°C for 1 h), acid shock (pH 4.5 for 30 min), or heat shock (50°C for 30 min). Cells were lysed and protein samples were analyzed by immunoblotting with antiserum derived from rabbits suffering from gas gangrene. Eight cold shock proteins (approximate M_r 101, 82, 70, 37, 22, 12, 10 and 6 kDa) and also eight heat shock proteins (approximate M_r 101, 82, 70, 27, 22, 16, 12 and 10 kDa) were immunoreactive with the serum. No immunoreactive proteins were detected in samples subjected to acid shock proteins and purified DnaK protein was also non-immunoreactive with the serum. These immunogenic stress proteins may be important in regulating diseases caused by C. perfringens. Such proteins could be involved in cell survival mechanisms, serve as targets during infection, or play a role in recognition of the bacteria by the host.     

The heat shock response inLocusta migratoria

Summary Locusta migratoria adults reared at 27–30°C die after 2 h at 50°C, but they survive this temperature stress if first exposed to 45°C for 0.5 to 4.5 h. Fat bodies from adult females produce a set of at least six specific polypeptides with molecular weights of 81, 73, 68, 42, 28, and 24×10³ in reponse to heat shock (39–47°C for 1.5 h). These molecular weights closely match those of the heat shock proteins (hsps) observed inDrosophila, with the possible exception of the 42 kd protein of locusts. The optimal temperature for induction of hsps in locusts is 45°C, which is one of the highest heat shock temperatures reported in metazoans. The correspondence between the optimal temperature for hsp induction and the temperature at which enhanced heat tolerance is acquired (both 45 °C) suggests that the hsps may be associated with thermal protection in these insects.There appears to be no substantial translational control in the locust heat shock response, since other proteins are produced, albeit with some reduction, under heat shock conditions. Vitellogenin synthesis in fat bodies at 45°C is 55% of that observed at 30°C. The high optimal heat shock induction temperature and the continued synthesis of non-heat shock proteins may be adaptive to the locust's natural environment.     

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     

Assessment of the tolerance of Lactococcus lactis cells at elevated temperatures

When Lactococcus lactis strains were exposed directly to the lethal temperature of 50 C for 30 ;min, 0.1–31% of the cells survived. However, when pre-exposed to 40 °C, prior to exposure at 50 °C, 4–61% of the cells survived. A plasmid carrying a unique heat shock gene from the thermophile Streptococcus thermophilus was cloned into L. ;lactis. When the transformed cells were cultivated at 30 °C the introduction of the plasmid had no obvious effect on the growth of L. ;lactis. However, when the temperature was abruptly shifted from 30 °C to 42 °C at mid-growth phase the growth decreased by 50%.     

Co-induction of DNA relaxation and synthesis of DnaK and GroEL proteins inEscherichia coli by expression of LetD (CcdB) protein,an inhibitor of DNA gyrase encoded by the F factor

We examined the influence of overexpression of LetD (CcdB) protein, an inhibitor of DNA gyrase encoded by the F factor ofEscherichia coli, on DNA supercoiling and induction of heat shock proteins. Cells were transformed with a plasmid carrying the structural gene for LetD protein under control of thetac promoter, and LetD protein was induced by adding isopropylβ-d-thiogalactopyranoside (IPTG) to the culture medium. Analysis by agarose gel electrophoresis in the presence of chloroquine revealed relaxation of plasmid DNA in cells depending on the concentration of IPTG employed for induction. Protein pulse-labeling experiments with [³⁵S]methionine and cysteine revealed that synthesis of DnaK and GroEL proteins was also induced by IPTG, and concentrations necessary for DNA relaxation and induction of the heat shock proteins were much the same. Expression of mutant LetD protein lacking two amino acid residues at the C-terminus induced neither DNA relaxation nor the synthesis of DnaK and GroEL proteins. Induction of wild-type LetD protein but not mutant LetD protein markedly enhanced synthesis ofσ ³². We interpret these results to mean that DNA relaxation in cells caused by the expression of LetD protein induces heat shock proteins via increased synthesis ofσ ³².     

Heat shock and cold shock in Deinococcus radiodurans

On the basis of acquired thermotolerance and cryotolerance, the optimal heat shock and cold shock temperatures have been determined for Deinococcus radiodurans. A heat shock at 42°C maximized survival at the lethal temperature of 52°C and a cold shock at 20°C maximized survival after repeated freeze-thawing. Enhanced survival from heat shock was found to be strongly dependent on growth stage, with its greatest effect shortly after phase. Increased synthesis of a total of 67 proteins during heat shock and 42 proteins during cold shock were observed by two-dimensional polyacrylamide gel electrophoresis (2D PAGE) and autoradiography. Eight of the most highly induced heat shock proteins shown by 2D PAGE were identified by MALDI-MS as Hsp20, GroEL, DnaK, SodA, Csp, Protease I and two proteins of unknown function.     

The Lactic Acid Stress Response of Lactococcus lactis subsp. lactis

The lactic acid tolerance response (LATR) of the lactic acid bacterium Lactococcus lactis subsp. lactis has been studied. A dramatic increase in survival to a severe acid stress (pH 3.9) was obtained by preexposing the cells for 30 min to a mildly acid shock at pH 5.5. Whole-cell protein extract analysis revealed that during the acid tolerance response 33 polypeptides are induced over the level of naive cells. Among these are the major heat shock proteins DnaK and GroEL. In conjunction with a previous report (Hartke et al. 1994), the results establish that L. lactis can adapt to lactic acid exposure in two different ways: a logarithmic phase LATR, which may be activated by protons, and a stationary-phase LATR, which needs no activation by protons. Both systems are independent of de novo protein synthesis. Received: 8 February 1996 / Accepted: 11 March 1996     

Dependence on thelon gene of the thermal induction of resistance to ultraviolet light inEscherichia coli

Our previous studies have shown thatEscherichia coli JE1011 possesses an errorfree DNA repair system that is inducible by heat shock or thiamine deprivation. However, it appears to be lacking inE. coli B, which islon ^–. We now show that a similar, thermally inducible, error-free system is present inE. coli AB1157, although it requires more severe heat shock for its induction. Thelon mutant of this strain is similar toE. coli B and does not become more UV-resistant after heat shock, so this gene appears to play an essential role in the process. All three strains become more resistant to heat inactivation at 55°C following a 30°C48°C heat shock; this confirms that the induced UV and thermal resistances must arise by different mechanisms.     

Thermostability of lactate dehydrogenase LDH-A4 isoenzyme: Effect of heat shock protein DnaK on the enzyme activity

Cells exposed to temperature a few degrees higher than their growth temperature synthesize heat shock proteins (hsp) which may then compose even 20% of total protein content. This paper examined the in vitro protective effect of heat shock protein DnaK (70 kDa) from Escherichia coli against the heat inactivation of lactate dehydrogenase isoenzyme LDH-A₄. The LDH-A₄ isoenzyme was purified from fish skeletal muscle using the affinity chromatography on Oxamate-agarose. The enzyme was then heated in the absence and the presence of DnaK protein in a water bath at either 51 or 55°C. The LDH activity was determined by measuring the change in absorbency at 340 nm min⁻¹ at 30°C. The addition of DnaK protein to the LDH-A₄ isoenzyme before heat treatment can protect enzyme activity against mild thermal inactivation. Incubation of the LDH-A₄ isoenzyme at 51°C in the presence of DnaK protein stimulates its activity by about 30%. The presence of 2 mM ATP can raise LDH activity by another 10%. No significant recovery was observed when DnaK protein was added to LDH at 25°C following earlier inactivation. The maximal activities (V_max) in the presence of DnaK protein are almost twice those without DnaK protein in the case of heat-treated LDH-A₄ isoenzyme at 51°C. The observed protection of LDH-A₄ activity increased with the increasing DnaK protein concentration in the incubation medium. Results suggested that the presence of DnaK protein can protect LDH-A₄ from heat inactivation. This action may be important as a part of cellular chaperone machinery capable of repairing heat-induced protein damage. It may have a fundamental role in the acquisition of the thermotolerance to stress temperatures.     

Lactic acid bacteria display on the cell surface cytosolic proteins that recognize yeast mannan

Fluorescent-labeled invertase, a hyperglycosylated mannoprotein from Saccharomyces cerevisiae, was found to bind to Lactococcus lactis IL1403 at acidic pH. Proteins on the cell wall of the bacterium affinity-purified using invertase as a ligand were identified to be heat shock proteins such as DnaK and GroEL and glycolytic enzymes such as pyruvate kinase and glyceraldehyde-3-phosphate dehydrogenase. DnaK bound to both the bacterium and yeast at pH 4 and aggregated them at above 0.1 mg/ml, whereas no significant difference between the circular dichroism spectra of DnaK at pH 4 and 7 was observed. These results indicate that the cytosolic proteins, including DnaK displayed on the cell wall, cause the lactic acid bacterium to adhere to the yeast.     

The heat shock response and acquired thermotolerance in three strains of cyanobacteria

The heat shock response of three cyanobacterial strains,Anabaena sp. Strain PCC (paris Culture Collection) 7120,Plectonema boryanum Strain PCC 6306, andSynechococcus sp. Strain PCC 7942, was characterized by polyacrylamide gel electrophoresis.Anabaena produced 33 heat shock proteins,P. boryanum 35 proteins, andSynechoccus 19 proteins. The rapid response to heat shock was consistent for all three strains, although the number of time-dependent proteins varied. All strains developed thermotolerance when first pretreated with a sublethal heat shock and then challenged with a previously lethal temperature. A 30-min 30°C incubation was required between the heat shock and challenge forSynechococcus, but not forAnabaena andP. boryanum. Synechococcus cells required a higher challenge temperature (51° vs. 49°C) than the other two strains to destroy control cells that were not pretreated with a heat shock.     

Lysozyme reactivation using immobilized molecular chaperonin GroEL

The molecular chaperonin, GroEL, was immobilized to a porous matrix and used to reactivate denatured lysozyme. The maximum reactivation yield was obtained at 37°C and pH 6–8 and about 90% activity of the denatured lysozyme was restored under the conditions. The coupling density of GroEL had little effect on the chaperoning activity of GroEL up to 48 mg g^–1 gel. The immobilized GroEL was reusable, indicating the possibility of using it on a large scale for the refolding of proteins.