Rhizobium meliloti suhR suppresses the phenotype of an Escherichia coli RNA polymerase sigma 32 mutant.

sigma 32, the product of the Escherichia coli rpoH locus, is an alternative RNA polymerase sigma factor utilized to express heat shock genes upon a sudden rise in temperature. E. coli K165 [rpoH165(Am) supC(Ts)] is temperature sensitive for growth and does not induce heat shock protein synthesis. We have isolated a locus from Rhizobium meliloti called suhR that allows E. coli K165 to grow at high temperature and induce heat shock protein synthesis. R. meliloti suhR mutants were viable and symbiotically effective. suhR was found to have no DNA or derived amino acid sequence similarity to the genes of previously sequenced sigma factors or other data base entries, although a helix-turn-helix DNA-binding protein motif is present. suhR did not restore the phenotypic defects of delta rpoH E. coli; suppression of the E. coli K165 phenotype is thus likely to involve E. coli sigma 32. Western immunoblots showed that suhR caused an approximately twofold elevation of sigma 32 levels in K165; RNA blots indicated that rpoH mRNA level and stability were not altered. Stabilization of sigma 32 protein and increased rpoH mRNA translation are thus the most probable mechanisms of suppression.     

Heat shock response in mycoplasmas, genome-limited organisms.

We have measured the effect of heat shock on three mycoplasmas (Acholeplasma laidlawii K2 and JA1 and Mycoplasma capricolum Kid) and demonstrated the induction of mycoplasma heat shock proteins under these conditions. Increased synthesis of at least 5 heat shock proteins in A. laidlawii K2, 11 heat shock proteins in A. laidlawii JA1, and 7 heat shock proteins in M. capricolum was observed by electrophoretic analysis of proteins from heat-shocked cells in sodium dodecyl sulfate-polyacrylamide gels. In all three strains, major heat shock proteins (66 to 68 and 26 to 29 kilodaltons [kDa]) were found. The 66- to 68-kDa protein cross-reacted with antibody to Escherichia coli DnaK protein, suggesting that this heat shock protein has been conserved in spite of major reductions in genetic complexity during mycoplasma evolution. A. laidlawii also contained a 60-kDa protein that cross-reacted with eubacterial GroEL protein and a 40-kDa protein that cross-reacted with E. coli RecA protein. Unlike with coliphages, the mycoplasma virus L2 progeny yield was not increased when virus was plated on heat-shocked A. laidlawii host cells. However, UV-irradiated L2 virus could be host cell reactivated by both A. laidlawii SOS repair and heat shock systems.     

Heat shock protein synthesis during development in Caulobacter crescentus.

Caulobacter crescentus cells respond to a sudden increase in temperature by transiently inducing the synthesis of several polypeptides. Two of the proteins induced, Hsp62 and Hsp70, were shown to be analogous to the heat shock proteins of Escherichia coli, GroEL and DnaK, respectively, by immunological cross-reactivity with antibodies raised against the E. coli proteins. Two-dimensional gel electrophoretic resolution of extracts of cells labeled with [35S]methionine during heat shock led to the identification of 20 distinct Hsps in C. crescentus which are coordinately expressed, in response to heat, at the various stages of the cell division cycle. Thus, a developmental control does not seem to be superimposed on the transient activation of the heat shock genes. Nonetheless, under normal temperature conditions, four Hsps (Hsp70, Hsp62, Hsp24b, and Hsp23a) were shown to be synthesized, and their synthesis was cell cycle regulated.     

Small heat shock proteins, IbpA and IbpB, are involved in resistances to heat and superoxide stresses in Escherichia coli

To investigate the function of Escherichia coli small heat shock proteins, IbpA and IbpB, we constructed ibpA-, ibpB- and ibpAB-overexpressing strains and also an ibpAB-disrupted strain. The ibpA-, ibpB- and ibpAB-overexpressing strains were found to be resistant not only to heat but also to superoxide stress. However, the ibpAB-disrupted strain was not more sensitive to these stresses than the wild-type strain. The heat sensitivity of a rpoH amber mutant was partially suppressed by the overexpression of plac::ibpAB. These results suggest that IbpA and IbpB may be involved in the resistances to heat and oxidative stress.     

Isolation and sequence analysis of rpoH genes encoding sigma 32 homologs from gram negative bacteria: conserved mRNA and protein segments for heat shock regulation.

The rpoH genes encoding homologs of Escherichia coli sigma 32 (heat shock sigma factor) were isolated and sequenced from five gram negative proteobacteria (gamma or alpha subgroup): Enterobacter cloacae (gamma), Serratia marcescens (gamma), Proteus mirabilis (gamma), Agrobacterium tumefaciens (alpha) and Zymomonas mobilis (alpha). Comparison of these and three known genes from E.coli (gamma), Citrobacter freundii (gamma) and Pseudomonas aeruginosa (gamma) revealed marked similarities that should reflect conserved function and regulation of sigma 32 in the heat shock response. Both the sequence complementary to part of 16S rRNA (the 'downstream box') and a predicted mRNA secondary structure similar to those involved in translational control of sigma 32 in E.coli were found for the rpoH genes from the gamma, but not the alpha, subgroup, despite considerable divergence in nucleotide sequence. Moreover, a stretch of nine amino acid residues Q(R/K)(K/R)LFFNLR, designated the 'RpoH box', was absolutely conserved among all sigma 32 homologs, but absent in other sigma factors; this sequence overlapped with the segment of polypeptide thought to be involved in DnaK/DnaJ chaperone-mediated negative control of synthesis and stability of sigma 32. In addition, a putative sigma E (sigma 24)-specific promoter was found in front of all rpoH genes from the gamma, but not alpha, subgroup. These results suggest that the regulatory mechanisms, as well as the function, of the heat shock response known in E.coli are very well conserved among the gamma subgroup and partially conserved among the alpha proteobacteria.     

Genetic mapping and biochemical characterization of suppressor mutations sukA and sukB for a dnaK7(Ts) mutation of Escherichia coli K-12.

Temperature-resistant pseudorevertants were isolated from a dnaK7(Ts) mutant of Escherichia coli K-12. Two of these pseudorevertants were shown to carry suppressor mutations, sukA and sukB, respectively. Genetic mapping by conjugation and P1-transduction revealed that these suppressor mutations were located at two distinct sites between 76 and 77 min close to the suhA and rpoH genes. Labeled cellular proteins were extracted from suppressor mutants grown at various temperatures and subjected to SDS-gel electrophoresis. Autoradiograms of the gels indicated that these suppressor mutations each resulted in increased synthesis of the heat shock protein Lon (an ATP-dependent protease, La) at both permissive and nonpermissive temperatures.     

Sensitization of Escherichia coli cells to oxidative stress by deletion of the rpoH gene, which encodes the heat shock sigma factor.

A deletion in the rpoH gene greatly increased the sensitivity of Escherichia coli sodA sodB mutants to oxidative stress. The effect of the rpoH deletion on sodA+ sodB+ cells was only marginal. Mutations in heat shock genes singly sensitized sodA sodB double mutant cells to plumbagin. sodA sodB double mutants were neither more sensitive nor more resistant to thermal stress than the wild type.     

Tissue-specific variations in the induction of Hsp70 and Hsp64 by heat shock in insects

The patterns of heat-induced synthesis (37 degrees C to 45 degrees C) of heat shock proteins (Hsps) in different tissues of grasshoppers and cockroaches from natural populations and in laboratory-reared gram-pest (Heliothis armigera) were examined by 35S-methionine labeling and sodium dodecyl sulfate-polyacrylamide gel electrophoresis fluorography. Whereas 45 degrees C was lethal in most cases, optimal induction of Hsp synthesis was seen between 37 degrees C and 42 degrees C. The ongoing protein synthesis was not much affected at these temperatures, except in the tissues of adult H. armigera exposed to 42 degrees C. The profiles of the Hsps induced in the tissues of the insects, however, were different. From the relative abundance of the synthesis of 70-kDa (Hsp70) and 64-kDa (Hsp64) polypeptides, three categories of heat shock response were identified: (1) induction of abundant Hsp70 but little Hsp64 (malpighian tubules, male accessory glands, and ovaries of adult grasshoppers), (2) abundant Hsp64 but little Hsp70 (testes of adult grasshoppers, testes and malpighian tubules of adult cockroaches, and testes, malpighian tubules, and fat bodies of H. armigera larvae), and (3) induction of both Hsp70 and Hsp64 in more or less equal abundance (ovaries of adult cockroaches, salivary glands of H. armigera larvae, and malpighian tubules, male accessory glands, testes, and ovaries of adult H. armigera). Cockroaches collected from storerooms showed detectable synthesis of Hsp64 and/or Hsp70 only after heat shock, but those collected from drains showed detectable synthesis of both Hsp70 and Hsp64 in different tissues without heat stress. Western blotting showed that the 64-kDa polypeptide in these insects is a member of the Hsp60 family. Grasshopper testes, which synthesized negligible Hsp70 but abundant Hsp64 after heat shock, developed thermotolerance. Thus, heat shock response is modulated by developmental and environmental factors in different tissues of insects.     

Deletion and insertion mutations in the rpoH gene of Escherichia coli that produce functional sigma 32.

Escherichia coli K-12 strain 285c contains a short deletion mutation in rpoD, the gene encoding the sigma 70 subunit of RNA polymerase. The sigma 70 protein encoded by this allele (rpoD285) unstable, and this instability leads to temperature-sensitive growth. Pseudorevertants of 285c that can grow at high temperature contain mutations in the rpoH gene (encoding the heat shock sigma factor sigma 32), and their mutant sigma 70 proteins have increased stability. We characterized the alterations in three of these rpoH alleles. rpoH111 was a point mutation resulting in a single amino acid substitution. rpoH107 and rpoH113, which are known to be incompatible with rpoD+, altered the restriction map of rpoH. rpoH113 was deleted for 72 base pairs of the rpoH gene yet retained some sigma 32 activity. rpoH107 had two IS1 elements that flanked an unknown DNA segment of more than 6.4 kilobases inserted in the rpoH promoter region. The insertion decreased the amount of rpoH mRNA to less than 0.5% of the wild-type level at 30 degrees C. However, the mRNA from several heat shock promoters was decreased only twofold, suggesting that the strain has a significant amount of sigma 32.     

Effects of mild heat shock on glycogenesis and its regulation by insulin in cultured fetal hepatocytes

The effects of a mild heat shock were investigated using cultured 15-day-old fetal rat hepatocytes in which an acute glucocorticoid-dependent glycogenic response to insulin was present. After exposure from 15 min to 2 h at 42.5°C, cell surface [¹²⁵I]insulin binding progressively decreased down to 60% of the value shown in cells kept at 37°C, due to a decrease in the apparent number of insulin binding sites with little change in insulin receptor affinity. In parallel cultures, protein labeling with [³⁵S]methionine exhibited stimulated synthesis of specific proteins, in particular, 73-kDa Hsc (heat shock cognate) and 72-kDa Hsp (heat shock protein). When cells were returned to 37°C after 2 h at 42.5°C, cell surface insulin binding showed a two-third restoration within 3 h (insulin receptor half-life = 13 h), with similar concomitant return of Hsps72,73 synthesis to preinduction levels. The rate of [¹⁴C]glucose incorporation into glycogen measured at 37°C after 1- to 2-h heat treatment revealed a striking yet transient increase in basal glycogenesis (up to 5-fold). At the same time, the glycogenesis stimulation by insulin was reduced (from 3.2 to 1.4—fold), whereas that induced by a glucose load was maintained. Induction of thermotolerance after a first heating was obtained for the heat shock-dependent events except for the enhanced basal glycogenesis. In insulin-unresponsive cells grown in the absence of glucocorticoids, heat shock decreased the glycogenic capacity without modifying the glucose load stimulation, supporting the hypothesis that insulin and thermal stimulation of glycogenesis share at least part of the same pathway. Inverse variations were observed between Hsps72,73 synthesis and both cell surface insulin receptor level and insulin glycogenic response in fetal hepatocytes experiencing heat stress. © 1995 Wiley-Liss, Inc.