Responses induced by cold or heat are triggered following detection of temperature changes by specific sensing molecules, complexes or structures. Low temperature responses are often induced following sensing of cold-induced falls in membrane fluidity, such changes turning-on or -off enzymic activities in membrane proteins, although ribosomes and DNA may also function in cold perception. Many thermal sensors are components of structures damaged by the heat, with sensing involving changes to ribosomes, DNA, intracellular proteins and, less commonly, membrane fluidity. Additionally, secreted proteins (extracellular sensing components, ESCs) detect temperature increases i.e. act as thermometers, with ESC activation in the medium, by the stimulus, converting such sensors to extracellular signalling molecules, the extracellular induction components (EICs), which induce thermal responses. Several ESC/EIC pairs trigger thermal responses, and have the unique property of giving early warning of the stress by diffusing to regions (and organisms) not yet exposed to elevated temperatures.
NeidhardtF. C., IngrahamJ. L., and SchaechterM. (1990) In Physiology of the Bacterial Cell.Sinauer Associates Inc.: Sunderland, MA.
2.
RowburyR. J. (2001) Extracellular sensing components and extracellular induction component alarmones give early warning against stress in Escherichia coli.Adv. Microbial. Physiol., 44, 215–257.
3.
RowburyR. J. (2001) Cross-talk involving extracellular sensors and extracellular alarmones gives early warning to unstressed Escherichia coli of impending lethal chemical stress and leads to induction of tolerance responses. J. Appl. Microbiol., 90, 677–695.
4.
WeberM. H. W., and MarahielM. A. (2003) Bacterial cold shock responses. Sci. Prog., 86, 9–75.
5.
KandrorO., and GoldbergA. L. (1997) Trigger factor is induced upon cold shock and enhances viability of Escherichia coli at low temperatures. Proc. Nat. Acad. Sci. USA, 94, 4978–4981.
6.
FranksF. (1995) Protein destabilization at low temperatures. Adv. Protein Chem., 46, 105–139.
7.
NgH., IngrahamJ. L., and MarrA. G. (1962) Damage and derepression in Escherichia coli resulting from growth at low temperature. J. Bacteriol., 84, 331–339.
8.
ShawM. K., and IngrahamJ. L. (1967) Synthesis of macromolecules by Escherichia coli near the minimal temperature for growth. J. Bacteriol., 94, 157–164.
9.
WolffeA. P. (1995) The cold-shock response in bacteria. Sci. Prog., 78, 301–310.
10.
SuzukiL., LosD. A., KanesakiY., MikamiK., and MurataN. (2001) The pathway for perception and transduction of low-temperature signals in Synechocystis.EMBO J., 19, 1327–1334.
11.
AguilarP. S., Hernandez-ArriagaA. M., CybulskiL. E., ErazoA. C., and de MendozaD. (2001) Molecular basis of thermosensing, a two component signal transduction thermometer in Bacillus subtilis.EMBO J., 20, 1681–1691.
12.
LosD., HorvathI., VighL., and MurataN. (1993) The temperature-dependent expression of the desaturase gene desA in Synechocystis PCC6803. FEBS Lett., 318, 57–60.
13.
VighL., LosD. A., HorvathI., and MurataN. (1993) The primary signal in the biological perception of temperature, Pd-catalysed hydrogenation of membrane lipids stimulated the expression of the desA gene in Synechocystis PCC6803. Proc. Nat. Acad. Sci. USA, 90, 9090–9094.
14.
SuzukiI., KanesakiY., MikamiK., KanehisaM., and MurataN. (2001) Cold-regulated genes under control of the cold sensor Hik33 in Synechocystis.Mol. Microbiol., 40, 235–244.
15.
FabretC., FeherV. A., and HochJ. A. (1999) Two component signal transduction in Bacillus subtilis, how one organism sees its world. J. Bacteriol., 181, 1975–1983.
16.
AguilarP. S., CronanJ. E.Jr., and de MendozaD. (1998) A B. subtilis gene induced by cold shock encodes a membrane phospholipid desaturase. J. Bacterial., 180, 2194–2200.
17.
AguilarP. S., LopezP., and de MendozaD. (1999) Transcriptional control of the low temperature-inducible des gene, encoding the delta5 desaturase of Bacillus subtilis.J. Bacteriol., 181, 7028–7033.
18.
van BogelenR. A., and NeidhardtF. C. (1990) Ribosomes as sensors of heat and cold shock in Escherichia coli.Proc. Nat. Acad. Sci. USA, 87, 5589–5593.
19.
CashelM., GentryD. R., HernandezV. J., and VinellaD. (1996) The stringent response. In: NeidhardtF. C., CurtissR.III, IngrahamJ. L., LinE. C. C., LowK. B., MagasanikB., ReznikoffW. S., RileyM., SchaechterM., and UmbargerH. E. (eds.) Escherichia coli and Salmonella, Cellular and Molecular Biology.American Society for Microbiology, Washington, DC, pp. 1458–1496.
20.
MackowE. R., and ChangF. N. (1983) Correlation between RNA synthesis and ppGpp content in Escherichia coli during temperature shifts. Mol. Gen. Genet., 192, 5–9.
21.
JonesP. G., CashelM., GlaserG., and NeidhardtF. C. (1992) Function of a relaxed-like state following temperature downshifts in Escherichia coli.J. Bacterio., 174, 3903–3914.
22.
BeckeringC. L., SteilL., WeberM. H. W., VolkerU., and MarahielM. A. (2002) Genomewide transcriptional analysis of the cold shock response in Bacillus subtilis.J. Bacteriol., 184, 6395–6402.
23.
EtchegarayJ. P., and InouyeM. (1999) CspA, CspB and CspG, major cold shock proteins of Escherichia coli, are induced at low temperature under conditions that completely block protein synthesis. J. Bacteriol., 181, 1827–1830.
24.
JonesP. G., MittaM., KimY., JiangW., and InouyeM. (1996) Cold shock induces a major ribosomal-associated protein that unwinds double-stranded RNA in Escherichia coli.Proc. Nat. Acad. Sci. Wash., 93, 76–80.
25.
ChamotD., MageeW. C., YuE., and OwttrimG. W. (1999) A cold shock-induced cyanobacterial RNA helicase. J. Bacteriol., 181, 1728–1732.
26.
ChamotD., and OwttrimG. W. (2000) Regulation of cold shock-induced RNA helicase gene expression in the cyanobacterium Anabaena sp. strain PCC 7120. J. Bacteriol., 182, 1251–1256.
27.
O'ConnellK. P., GustafsonA. M., LehmannM. D., and ThomashowM. F. (2000) Identification of cold shock gene loci in Sinorhizobium meliloti by using a luxAB reporter transposon. Appl. Environ. Microbiol., 66, 401–405.
28.
MajdalaniN., CunnungC., SledjeskiD., ElliotT., and GottesmanS. (1998) DsrA RNA regulates translation of RpoS message by an anti-sense mechanism, independent of its action as an antisilencer of transcription. Proc. Nat. Acad. Sci. USA, 95, 12462–12467.
29.
RepoilaF., and GottesmanS. (2001) Signal transduction cascade for regulation of RpoS, temperature regulation of DsrA. J. Bacteriol., 183, 166–171.
30.
LeaseR. A., and BelfortM. (2000) A trans-acting RNA as a control switch in Escherichia coli, DsrA modulates function by forming alternative structures. Proc. Nat. Acad. Sci. USA, 97, 9919–9924.
31.
BrandiA., PietroniP., GualerziC. O., and PonC. L. (1996) Post-transcriptional regulation of CspA expression in Escherichia coli.Mol. Microbiol., 19, 231–240.
32.
GoldenbergD., AzarI., and OppenheimA. B. (1996) Differential m-RNA stability of the cspA gene in the cold-shock response. Mol. Microbiol., 19, 241–248.
33.
KrispinO., and AllmansbergerR. (1995) Changes in DNA supertwist as a response of B. subtilis towards different kinds of stress. FEMS Microbiol. Lett., 134, 129–135.
34.
MizushimaT., KataokaK., OgataY., InoueR., and SekimizuK. (1997) Increase in negative supercoiling of plasmid DNA in Escherichia coli exposed to cold shock. Mol. Microbiol., 23, 381–386.
35.
La TeanaA., BrandiA., FalconiM., SpurioR., PonC. L., and GualerziC. O. (1991) Identification of a cold shock transcriptional enhancer of the Escherichia coli gene encoding nucleoid protein H-NS. Proc. Nat. Acad. Sci. USA, 88, 10907–10911.
36.
DerschP., KneipS., and BremerE. (1994) The nucleoid-associated DNA binding protein H-NS is required for the efficient adaptation of Escherichia coli K12 to a cold environment. Mol. Gen. Genet., 245, 255–259.
37.
RowburyR. J. (1997) Regulatory components, including integration host factor, CysB and H- NS, that influence pH responses in Escherichia coli.Lett. Appl. Microbiol., 24, 319–328.
38.
RowburyR. J., and GoodsonM. (2001) Extracellular sensing and signalling pheromones switch-on thermotolerance and other stress responses in Escherichia coli.Sci. Prog., 84, 205–233.
39.
NikolaevY. A. (1996) General protective effect of exometabolite(s) produced by tetracycline-treated Escherichia coli.Microbiology (Moscow), 65, 652–655.
40.
NikolaevY. A. (1997) Involvement of exometabolites in stress adaptation of Escherichia coli.Microbiology (Moscow), 66, 28–31.
41.
NikolaevY. A. (1997) Comparative study of two extracellular protectants secreted by Escherichia coli cells at elevated temperatures. Microbiology (Moscow), 66, 661–665.
42.
NikolaevY. A. (1997) Two novel extracellular adaptogenic factors of Escherichia coli K12. Microbiology (Moscow), 66, 657–660.
43.
CronanJ. E.Jr., and RockC. O. (1996) Biosynthesis of membrane lipids. Pp. 612–636. In: NeidhardtF. C., CurtissR.III, IngrahamJ. L., LinE. C. C., LowK. B., MagasanikB., ReznikoffW. S., RileyM., SchaechterM., and UmbargerH. E. (eds.) Escherichia coli and Salmonella, Cellular and Molecular Biology. American Society for Microbiology, Washington, DC.
44.
PaoC. C., and DyasB. T. (1981) Stringent control of RNA synthesis in the absence of guanosine 5'- diphosphate-3'-diphosphate. J. Biol. Chem., 256, 2252–2257.
45.
FalconiM., ColonnaB., ProssedaG., MicheliG., and GualerziC. O. (1998) Thermoregulation of Shigella and Escherichia coli EIEC pathogenicity. A temperature-dependent structural transition of DNA modulates accessibility of virF promoter to transcriptional repressor H-NS. EMBO J., 17, 7033–7043.
46.
HoeN. P., and GougenJ. D. (1993) Temperature sensing in Yersinia pestis, translation of the LcrF activator protein is thermally regulated. J. Bacterio., 175, 7901–7909.
47.
BrenA., and EisenbachM. (2000) How signals are heard during bacterial Chemotaxis, protein- protein interactions in sensory signal propagation. J. Bacterial., 182, 6865–6873.
48.
NishiyamaS., MaruyamaI. N., HommaM., and KawagishiI. (1999) Inversion of thermosensing property of the bacterial receptor Tar by mutations in the second transmembrane region. J. Mol. Biol., 286, 1275–1284.
49.
VighL., MarescaB., and HarwoodJ. L. (1998) Does the membrane's physical state control the expression of heat shock and other genes?Trends Biochem. Sci., 23, 369–374.
50.
HurmeR., BerndtK., NamorkE., and RhenM. (1996) DNA binding exerted by a bacterial gene regulator with extensive coiled coil domains. J. Biol. Chem., 271, 12626–12631.
51.
HurmeR., BerndtK., NormarkS. J., and RhenM. (1997) A proteinaceous gene regulatory thermometer in Salmonella.Cell, 90, 55–64.
52.
McCartyJ. S., and WalkerG. C. (1991) DnaK as a thermometer, threonine-199 is site of autophosphorylation and is critical for ATPase activity. Proc. Nat. Acad. Sci. USA, 88, 9513–9517.
53.
StrausD., WalterW., and GrossC. (1990) DnaK, DnaJ and GrpE heat shock proteins negatively regulate heat shock gene expression by controlling the synthesis and stability of σ32. Genes Dev., 4, 2202–2209.
54.
GamerJ., MulthaupG., TomoyasuT., McCartyJ. S., RadigerS., SchonfeldH. J., SchirraC., BujardH., and BukauB. (1996) A cycle of binding and release of the DnaK, DnaJ and GrpE chaperones regulates the activity of the Escherichia coli heat shock transcription factor σ32. EMBO J., 15, 607–617.
55.
RowburyR. J. (1982) Methionine biosynthesis and its regulation. In: SomervilleR., and HermannK.M. (eds.) Amino acids, biosynthesis and genetic regulation, pp. 191–211. Addison-Wesley, New York.
56.
RonE. Z., and DavisB. D. (1971) Growth rate of Escherichia coli at elevated temperatures, limitation by methionine. J. Bacteriol., 107, 391–396.
57.
BakerR. C., HotchkissJ. H., and QuereshiR. A. (1985) Elevated CO2 atmospheres for packaging poultry. 1. Effects on ground chicken. Poultry Sci., 64, 328–332.
58.
KnocheW. (1980) Chemical reactions of CO2 in water. In: BauerC., GrosG., and BartelsH. (eds.) Biophysics and Physiology of CO2; p. 3. Springer-Verlag, New York.
59.
OgrydziakD. M., and BrownW. D. (1982) Temperature effects in modified atmosphere storage of seafoods. Food Technol., 5, 86–88, 90–91, 94–96.
60.
RowburyR. J. (2003) Extracellular proteins as enterobacterial thermometers. Sci. Prog., 86, 139–156.
61.
RowburyR. J., and GoodsonM. (1999) An extracellular acid stress-sensing protein needed for acid tolerance induction in Escherichia coli.FEMS Microbiol. Lett., 174, 49–55.
62.
RowburyR. J. (1999) Acid tolerance induced by metabolites and secreted proteins and how tolerance can be counteracted. In: ChadwickD. J., and CardewG. (eds.) Bacterial Responses to pH. Novartis Found Symp.221, 93–111. Wiley, New York.
63.
RowburyR. J. (2003) Physiology and molecular basis of stress adaptation, with particular reference to the subversion of stress adaptation, and to the involvement of extracellular components in adaptation. In: YousefA. E., and JunejaV. K. (eds.) Microbial stress adaptation and food safety, pp. 247–302. CRC Press, Boca Raton.
64.
RowburyR. J., and GoodsonM. (1999) An extracellular stress-sensing protein is activated by heat and UV irradiation as well as by mild acidity, the activation producing an acid tolerance-inducing protein. Lett. Appl. Microbiol., 29, 10–14.
65.
MackeyB. M., and DerrickC. M. (1986) Changes in the heat resistance of Salmonella typhimurium during heating at rising temperatures. Lett. Appl. Microbiol., 4, 13–16.
66.
RowburyR. J. (2002) Microbial disease, recent studies show that novel extracellular components can enhance microbial resistance to lethal host chemicals and increase virulence. Sci. Prog., 85, 1–11.
67.
WalkerG. C. (1984) Mutagenesis and inducible responses to deoxyribonucleic acid damage in Escherichia coli.Microbiol. Rev., 48, 60–93.
68.
SpiessC., BeilA., and EhrmannM. (1999) A temperature-dependent switch from chaperone to protease in a widely conserved heat-shock protein. Cell, 97, 339–347.
69.
HazelJ. R. (1995) Thermal adaptation in biological membranes, is homeoviscous adaptation the explanation?Ann. Rev. Physio., 57, 19–42.
