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Weining Jiang, Yan Hou, M. Inouye (1997)
CspA, the Major Cold-shock Protein of Escherichia coli, Is an RNA Chaperone*The Journal of Biological Chemistry, 272
D. Molenaar, J. Bosscher, B. Brink, A. Driessen, W. Konings (1993)
Generation of a proton motive force by histidine decarboxylation and electrogenic histidine/histamine antiport in Lactobacillus buchneriJournal of Bacteriology, 175
(1984)
E¡ects of growth conditions on the activities of superoxide dismutase and NADH-oxidase/NADH-peroxidase in Streptococcus lactis
X. Huang, D. Huang, G. Novel, M. Novel (1995)
Two Lactococcus lactis genes, including lacX, cooperate to trigger an SOS response in a recA-negative backgroundJournal of Bacteriology, 177
P. Graumann, M. Marahiel (1996)
Some like it cold: response of microorganisms to cold shockArchives of Microbiology, 166
H. Kobayashi, T. Suzuki, T. Unemoto (1986)
Streptococcal cytoplasmic pH is regulated by changes in amount and activity of a proton-translocating ATPase.The Journal of biological chemistry, 261 2
(1996)
Osmoregulation. In: Escherichia coli and Salmonella typhimurium
E. Glaasker, W. Konings, B. Poolman (1996)
Osmotic regulation of intracellular solute pools in Lactobacillus plantarumJournal of Bacteriology, 178
D. Molenaar, A. Hagting, H. Alkema, A. Driessen, W. Konings (1993)
Characteristics and osmoregulatory roles of uptake systems for proline and glycine betaine in Lactococcus lactisJournal of Bacteriology, 175
J. Sanders, G. Venema, J. Kok, K. Leenhouts (1998)
Identification of a sodium chloride-regulated promoter in Lactococcus lactis by single-copy chromosomal fusion with a reporter geneMolecular and General Genetics MGG, 257
J. Panoff, B. Thammavongs, J. Laplace, A. Hartke, P. Boutibonnes, Y. Auffray (1995)
Cryotolerance and Cold Adaptation in Lactococcus lactis Subsp. lactis IL1403Cryobiology, 32
A. Hartke, Sandrine Bouché, X. Gansel, P. Boutibonnes, Y. Auffray (1994)
Starvation-Induced Stress Resistance in Lactococcus lactis subsp. lactis IL1403Applied and Environmental Microbiology, 60
C. Georgopoulos, W. Welch (1993)
Role of the major heat shock proteins as molecular chaperones.Annual review of cell biology, 9
H. Bolhuis, H. Veen, B. Poolman, A. Driessen, W. Konings (1997)
Mechanisms of multidrug transporters.FEMS microbiology reviews, 21 1
A. Vollmer, Sylvia Kwakye, Matthew Halpern, E. Everbach (1998)
Bacterial Stress Responses to 1-Megahertz Pulsed Ultrasound in the Presence of MicrobubblesApplied and Environmental Microbiology, 64
(1994)
The e¡ect of extracellular pH and lactic acid on pH homeostasis in Lactococcus lactis and Streptococcus bovis
N. García-Quintáns, C. Magni, D. Mendoza, P. López (1998)
The Citrate Transport System of Lactococcus lactis subsp. lactis biovar diacetylactis Is Induced by Acid StressApplied and Environmental Microbiology, 64
B. Koch, M. Kilstrup, F. Vogensen, K. Hammer (1998)
Induced Levels of Heat Shock Proteins in adnaK Mutant of Lactococcus lactisJournal of Bacteriology, 180
G. Willimsky, H. Bang, G. Fischer, M. Marahiel (1992)
Characterization of cspB, a Bacillus subtilis inducible cold shock gene affecting cell viability at low temperaturesJournal of Bacteriology, 174
J. Wouters, J. Sanders, J. Kok, W. Vos, O. Kuipers, T. Abee (1998)
Clustered organization and transcriptional analysis of a family of five csp genes of Lactococcus lactis MG1363.Microbiology, 144 ( Pt 10)
Martien, van, Asseldonk, A. Simons, H. Visser, DE WILLEMM., Vos, G. Simons (1993)
Cloning, nucleotide sequence, and regulatory analysis of the Lactococcus lactis dnaJ geneJournal of Bacteriology, 175
J. Sanders, K. Leenhouts, J. Burghoorn, J. Brands, G. Venemâ, J. Kok (1998)
A chloride‐inducible acid resistance mechanism in Lactococcus lactis and its regulationMolecular Microbiology, 27
Takeshi Higuchi, H. Hayashi, K. Abe (1997)
Exchange of glutamate and gamma-aminobutyrate in a Lactobacillus strainJournal of Bacteriology, 179
T. Araya, N. Ishibashi, S. Shimamura, K. Tanaka, H. Takahashi (1993)
Genetic and molecular analysis of the rpoD gene from Lactococcus lactis.Bioscience, biotechnology, and biochemistry, 57 1
FEMSRE
B. Mayo, S. Derzelle, María Fernández, C. Léonard, T. Ferain, P. Hols, J. Suárez, J. Delcour (1997)
Cloning and characterization of cspL and cspP, two cold-inducible genes from Lactobacillus plantarumJournal of Bacteriology, 179
J. Arnau, K. Sørensen (1997)
The isolation of novel heat shock genes in Lactococcus lactis using RNA subtractive hybridization.Gene, 188 2
J. Bacteriol
(812)
Regulation of Lactococcus ftsH expression
A. Mogk, A. Völker, S. Engelmann, M. Hecker, W. Schumann, U. Völker (1998)
Nonnative Proteins Induce Expression of the Bacillus subtilis CIRCE RegulonJournal of Bacteriology, 180
W. Kim, N. Dunn (1997)
Identification of a Cold Shock Gene in Lactic Acid Bacteria and the Effect of Cold Shock on CryotoleranceCurrent Microbiology, 35
A. Brandi, P. Pietroni, C. Gualerzi, C. Pon (1996)
Post‐transcriptional regulation of CspA expression in Escherichia coliMolecular Microbiology, 19
Pamela Jones, M. Inouye (1994)
The cold‐shock response — a hot topicMolecular Microbiology, 11
B. Poolman, A. Driessen, W. Konings (1987)
Regulation of arginine-ornithine exchange and the arginine deiminase pathway in Streptococcus lactisJournal of Bacteriology, 169
W. Vos, G. Simons (1994)
Gene cloning and expression systems in Lactococci.
M. Kilstrup, S. Jacobsen, K. Hammer, F. Vogensen (1997)
Induction of heat shock proteins DnaK, GroEL, and GroES by salt stress in Lactococcus lactisApplied and Environmental Microbiology, 63
N. Klijn, A. Weerkamp, W Vos (1995)
Detection and characterization of lactose-utilizing Lactococcus spp. in natural ecosystemsApplied and Environmental Microbiology, 61
A. Hartke, J. Frère, P. Boutibonnes, Y. Auffray (1997)
Differential Induction of the Chaperonin GroEL and the Co-Chaperonin GroES by Heat, Acid, and UV-Irradiation in Lactococcus lactis subsp. lactisCurrent Microbiology, 34
D. Goldenberg, Idit Azar, A. Oppenheim (1996)
Differential mRNA stability of the cspA gene in the cold‐shock response of Escherichia coliMolecular Microbiology, 19
P. Graumann, M. Marahiel (1998)
A superfamily of proteins that contain the cold-shock domain.Trends in biochemical sciences, 23 8
P. Recsei, E. Snell (1972)
Histidine Decarboxylaseless Mutants of Lactobacillus 30a: Isolation and Growth PropertiesJournal of Bacteriology, 112
P. Duwat, Sophie Sourice, S. Ehrlich, Alexandra Gruss (1995)
recA gene involvement in oxidative and thermal stress in Lactococcus lactis.Developments in biological standardization, 85
Christophe Herman, D. Thévenet, Richard D'Ari, Philippe Bouloc (1995)
Degradation of sigma 32, the heat shock regulator in Escherichia coli, is governed by HflB.Proceedings of the National Academy of Sciences of the United States of America, 92
B. Poolman, E. Smid, H. Veldkamp, W. Konings (1987)
Bioenergetic consequences of lactose starvation for continuously cultured Streptococcus cremorisJournal of Bacteriology, 169
D. Frees, H. Ingmer (1999)
ClpP participates in the degradation of misfolded protein in Lactococcus lactisMolecular Microbiology, 31
A. Nauta, Ouwe Sinderen, Harma Karsens, E. Smit, G. Venemâ, J. Kok (1996)
Inducible gene expression mediated by a repressor‐operator system isolated from Lactococcus lactis bacteriophage r1tMolecular Microbiology, 19
M. Hecker, W. Schumann, U. Völker (1996)
Heat‐shock and general stress response in Bacillus subtilisMolecular Microbiology, 19
(1962)
J. Biol. Chem
Edinburgh Research Explorer Identification of the lactococcal exonuclease/recombinase and its modulation by the putative Chi sequence
J. Sanders, K. Leenhouts, A. Haandrikman, G. Venemâ, J. Kok (1995)
Stress response in Lactococcus lactis: cloning, expression analysis, and mutation of the lactococcal superoxide dismutase geneJournal of Bacteriology, 177
A. Hartke, Sandrine Bouché, J. Giard, A. Benachour, P. Boutibonnes, Y. Auffray (1996)
The Lactic Acid Stress Response of Lactococcus lactis subsp. lactisCurrent Microbiology, 33
Harry Holms (1996)
Flux analysis and control of the central metabolic pathways in Escherichia coli.FEMS microbiology reviews, 19 2
R. Marquis, G. Bender, D. Murray, A. Wong (1987)
Arginine deiminase system and bacterial adaptation to acid environmentsApplied and Environmental Microbiology, 53
P. Duwat, A. Cochu, S. Ehrlich, A. Gruss (1997)
Characterization of Lactococcus lactis UV-sensitive mutants obtained by ISS1 transpositionJournal of Bacteriology, 179
A. Nauta, B. Burg, Harma Karsens, G. Venemâ, J. Kok (1997)
Design of thermolabile bacteriophage repressor mutants by comparative molecular modelingNature Biotechnology, 15
B. Poolman, Rmj Nijssen, W. Konings (1987)
Dependence of Streptococcus lactis phosphate transport on internal phosphate concentration and internal pHJournal of Bacteriology, 169
C. Marty-Teysset, C. Posthuma, J. Lolkema, P. Schmitt, C. Diviès, W. Konings (1996)
Proton motive force generation by citrolactic fermentation in Leuconostoc mesenteroidesJournal of Bacteriology, 178
P. Jensen, K. Hammer (1993)
Minimal Requirements for Exponential Growth of Lactococcus lactisApplied and Environmental Microbiology, 59
X. Gansel, A. Hartke, P. Boutibonnes, Y. Auffray (1993)
Nucleotide sequence of the Lactococcus lactis NCDO 763 (ML3) rpoD gene.Biochimica et biophysica acta, 1216 1
W. Konings, B. Poolman (1996)
Glycine betaine fluxes in Lactobacillus plantarum during osmostasis and hyper- and hypo-osmotic shock
(1995)
Repair of oxidative DNA damage in gram-positive bacteria: the Lactococcus lactis Fpg protein.Microbiology, 141 ( Pt 2)
Weining Jiang, L. Fang, Masayori Inouye (1996)
The role of the 5'-end untranslated region of the mRNA for CspA, the major cold-shock protein of Escherichia coli, in cold-shock adaptationJournal of Bacteriology, 178
E. Kashket (1987)
Bioenergetics of lactic acid bacteria: cytoplasmic pH and osmotoleranceFems Microbiology Letters, 46
T. Eaton, C. Shearman, M. Gasson (1993)
Cloning and sequence analysis of the dnaK gene region of Lactococcus lactis subsp. lactis.Journal of general microbiology, 139 12
M. O'Connell-Motherway, G. Fitzgerald, D. Sinderen (1997)
Cloning and sequence analysis of putative histidine protein kinases isolated from Lactococcus lactis MG1363Applied and Environmental Microbiology, 63
D. Nilsson, A. Lauridsen, T. Tomoyasu, T. Ogura (1994)
A Lactococcus lactis gene encodes a membrane protein with putative ATPase activity that is homologous to the essential Escherichia coli ftsH gene product.Microbiology, 140 ( Pt 10)
K. Wiederholt, J. Steele (1994)
Glutathione Accumulation in LactococciJournal of Dairy Science, 77
L. Fernandes, J. Steele (1993)
Glutathione Content of Lactic Acid BacteriaJournal of Dairy Science, 76
P. Wouters, E. Glaasker, J. Smelt (1998)
Effects of High Pressure on Inactivation Kinetics and Events Related to Proton Efflux in Lactobacillus plantarumApplied and Environmental Microbiology, 64
Roland Lange, R. Hengge-aronis (1994)
The cellular concentration of the sigma S subunit of RNA polymerase in Escherichia coli is controlled at the levels of transcription, translation, and protein stability.Genes & development, 8 13
S. Condon (1987)
Responses of lactic acid bacteria to oxygenFems Microbiology Letters, 46
Andjamesa. Imlay (1996)
Superoxide accelerates DNA damage by elevating free-iron levels.Proceedings of the National Academy of Sciences of the United States of America, 93 24
G. Davey, H. Heap (1993)
Appearance of the arginine phenotype in Lactococcus lactis subsp. cremoris 2204 following phage transductionCanadian Journal of Microbiology, 39
F. Neidhardt, J. Ingraham (1987)
Escherichia Coli and Salmonella: Typhimurium Cellular and Molecular Biology
P. Duwat, S. Ehrlich, A. Gruss (1999)
Effects of metabolic flux on stress response pathways in Lactococcus lactisMolecular Microbiology, 31
M. Zúñiga, M. Champomier-Vergès, M. Zagorec, G. Pérez-Martínez (1998)
Structural and Functional Analysis of the Gene Cluster Encoding the Enzymes of the Arginine Deiminase Pathway ofLactobacillus sakeJournal of Bacteriology, 180
ScienceDirect (1993)
FEMS microbiology reviews
M. Chapot-Chartier, C. Schouler, A. Lepeuple, J. Gripon, M. Chopin (1997)
Characterization of cspB, a cold-shock-inducible gene from Lactococcus lactis, and evidence for a family of genes homologous to the Escherichia coli cspA major cold shock geneJournal of Bacteriology, 179
(1996)
Exchange of aspartate and alanine: mechanism for development of a proton-motive force in bacteria
A. Mogk, G. Homuth, C. Scholz, L. Kim, F. Schmid, W. Schumann (1997)
The GroE chaperonin machine is a major modulator of the CIRCE heat shock regulon of Bacillus subtilisThe EMBO Journal, 16
Woojin Kim, Jun Ren, N. Dunn (1999)
Differentiation of Lactococcus lactis subspecies lactis and subspecies cremoris strains by their adaptive response to stresses.FEMS microbiology letters, 171 1
P. Duwat, S. Ehrlich, A. Gruss (1995)
The recA gene of Lactococcus lactis: characterization and involvement in oxidative and thermal stressMolecular Microbiology, 17
M. Gasson, J. Godon, C. Pillidge, T. Eaton, K. Jury, C. Shearman (1995)
Characterization and exploitation of conjugation in Lactococcus lactisInternational Dairy Journal, 5
J. Arnau, K. Sørensen, K. Appel, F. Vogensen, K. Hammer (1996)
Analysis of heat shock gene expression in Lactococcus lactis MG1363.Microbiology, 142 ( Pt 7)
W. Sandine, P. Radich, P. Elliker (1972)
ECOLOGY OF THE LACTIC STREPTOCOCCI. A REVIEWJournal of milk and food technology, 35
P. Bourgeois, Martine Lautier, Loic, Van Den, Berghe, Mike Gasson, P. Ritzenthaler (1995)
Physical and genetic map of the Lactococcus lactis subsp. cremoris MG1363 chromosome: comparison with that of Lactococcus lactis subsp. lactis IL 1403 reveals a large genome inversionJournal of Bacteriology, 177
(1993)
Lactococcal plasmid vectors
Robert Fahey, Willie Brown, William Adams, Michael Worsham (1978)
Occurrence of glutathione in bacteriaJournal of Bacteriology, 133
E. Kashket (1987)
MetabolismBioenergetics of lactic acid bacteria: cytoplasmic pH and osmotolerance☆Fems Microbiology Letters, 46
J. Sanders, G. Venemâ, J. Kok (1997)
A chloride-inducible gene expression cassette and its use in induced lysis of Lactococcus lactisApplied and Environmental Microbiology, 63
(812)
Engineering of a pH-regulated promoter from Lactococcus lactis
K. Yamanaka, L. Fang, M. Inouye (1998)
The CspA family in Escherichia coli : multiple gene duplication for stress adaptationMolecular Microbiology, 27
A. Casiano-Colón, R. Marquis (1988)
Role of the arginine deiminase system in protecting oral bacteria and an enzymatic basis for acid toleranceApplied and Environmental Microbiology, 54
H. Israelsen, Soeren Madsen, A. Vrang, E. Hansen, Eric Johansen (1995)
Cloning and partial characterization of regulated promoters from Lactococcus lactis Tn917-lacZ integrants with the new promoter probe vector, pAK80Applied and Environmental Microbiology, 61
R. Whitaker, C. Batt (1991)
Characterization of the Heat Shock Response in Lactococcus lactis subsp. lactisApplied and Environmental Microbiology, 57
S. Amachi, K. Ishikawa, S. Toyoda, Y. Kagawa, A. Yokota, F. Tomita (1998)
Characterization of a mutant of Lactococcus lactis with reduced membrane-bound ATPase activity under acidic conditions.Bioscience, biotechnology, and biochemistry, 62 8
P. Graumann, T. Wendrich, Michael Weber, K. Schröder, M. Marahiel (1997)
A family of cold shock proteins in Bacillus subtilis is essential for cellular growth and for efficient protein synthesis at optimal and low temperaturesMolecular Microbiology, 25
J. Smart, T. Thomas (1987)
Effect of Oxygen on Lactose Metabolism in Lactic StreptococciApplied and Environmental Microbiology, 53
N. Nannen, R. Hutkins (1991)
Proton-Translocating Adenosine Triphosphatase Activity in Lactic Acid BacterialJournal of Dairy Science, 74
AbstractBacteria can encounter a variety of physical conditions during their life. Bacterial cells are able to survive these (often adverse) conditions by the induction of specific or general protection mechanisms. The lactic acid bacterium Lactococcus lactis is widely used for the production of cheese. Before and during this process as well as in its natural habitats, it is subjected to several stressful conditions. Such conditions include oxidation, heating and cooling, acid, high osmolarity/dehydration and starvation. In many environments combinations of these parameters occur. Understanding the stress response behaviour of L. lactis is important to optimize its application in industrial fermentations and is of fundamental interest as L. lactis is a non-differentiating Gram-positive bacterium. The stress response mechanisms of L. lactis have drawn increasing attention in recent years. The presence in L. lactis of a number of the conserved systems (e.g. the heat shock proteins) has been confirmed. Some of the regulatory mechanisms responding to an environmental stress condition are related to those found in other Gram-positive bacteria. Other stress response systems are conserved at the protein level but are under control of mechanisms unique for L. lactis. In a number of cases exposure to a single type of stress provides resistance to other adverse conditions. The unravelling of the underlying regulatory systems gives insight into the development of such cross resistance. Taken together, L. lactis has a unique set of stress response mechanisms, most of which have been identified on the basis of homology with proteins known from other bacteria. A number of the regulatory elements may provide attractive tools for the development of food grade inducible gene expression systems. Here an overview of the growth limits of L. lactis and the molecular characterization of its stress resistance mechanisms is presented.
FEMS Microbiology Reviews – Oxford University Press
Published: Jul 17, 1999
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