Changes in Glycolytic Activity of Lactococcus lactis Induced by Low Temperature

ABSTRACT The effects of low-temperature stress on the glycolytic activity of the lactic acid bacterium Lactococcus lactis were studied. The maximal glycolytic activity measured at 30°C increased approximately 2.5-fold following a shift from 30 to 10°C for 4 h in a process that required protein synthesis. Analysis of cold adaptation of strains with genes involved in sugar metabolism disrupted showed that both the phosphoenolpyruvate-dependent sugar phosphotransferase system (PTS) subunit HPr and catabolite control protein A (CcpA) are involved in the increased acidification at low temperatures. In contrast, a strain with the PTS subunit enzyme I disrupted showed increased acidification similar to that in the wild-type strain. This indicates that the PTS is not involved in this response whereas the regulatory function of 46-seryl phosphorylated HPr [HPr(Ser-P)] probably is involved. Protein analysis showed that the production of both HPr and CcpA was induced severalfold (up to two- to threefold) upon exposure to low temperatures. The lasoperon, which is subject to catabolite activation by the CcpA-HPr(Ser-P) complex, was not induced upon cold shock, and no increased lactate dehydrogenase (LDH) activity was observed. Similarly, the rate-limiting enzyme of the glycolytic pathway under starvation conditions, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), was not induced upon cold shock. This indicates that a factor other than LDH or GAPDH is rate determining for the increased glycolytic activity upon exposure to low temperatures. Based on their cold induction and involvement in cold adaptation of glycolysis, it is proposed that the CcpA-HPr(Ser-P) control circuit regulates this factor(s) and hence couples catabolite repression and cold shock response in a functional and mechanistic way.

[1]  J. Sanders Environmental stress response in Lactococcus lactis , 1997 .

[2]  M. Inouye,et al.  Cold shock induces a major ribosomal-associated protein that unwinds double-stranded RNA in Escherichia coli. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[3]  M. Inouye,et al.  The CspA family in Escherichia coli : multiple gene duplication for stress adaptation , 1998, Molecular microbiology.

[4]  B. E. Davidson,et al.  Identification of a novel operon in Lactococcus lactis encoding three enzymes for lactic acid synthesis: phosphofructokinase, pyruvate kinase, and lactate dehydrogenase , 1993, Journal of bacteriology.

[5]  W. D. de Vos,et al.  Analysis of the role of 7 kDa cold-shock proteins of Lactococcus lactis MG1363 in cryoprotection. , 1999, Microbiology.

[6]  M. Inouye,et al.  The cold‐shock response — a hot topic , 1994, Molecular microbiology.

[7]  B. Poolman,et al.  Bioenergetic consequences of lactose starvation for continuously cultured Streptococcus cremoris , 1987, Journal of bacteriology.

[8]  M. Marahiel,et al.  Cold shock stress-induced proteins in Bacillus subtilis , 1996, Journal of bacteriology.

[9]  W. D. de Vos,et al.  Transcriptional activation of the glycolytic las operon and catabolite repression of the gal operon in Lactococcus lactis are mediated by the catabolite control protein CcpA , 1998, Molecular microbiology.

[10]  L. R. Finch,et al.  Cloning, nucleotide sequence, expression, and chromosomal location of ldh, the gene encoding L-(+)-lactate dehydrogenase, from Lactococcus lactis , 1992, Journal of bacteriology.

[11]  M. Inouye,et al.  RbfA, a 30S ribosomal binding factor, is a cold‐shock protein whose absence triggers the cold‐shock response , 1996, Molecular microbiology.

[12]  M. Marahiel,et al.  A superfamily of proteins that contain the cold-shock domain. , 1998, Trends in biochemical sciences.

[13]  W. D. de Vos,et al.  Identification of mesophilic lactic acid bacteria by using polymerase chain reaction-amplified variable regions of 16S rRNA and specific DNA probes , 1991, Applied and environmental microbiology.

[14]  W. D. de Vos,et al.  Molecular Characterization of the Lactococcus lactis ptsHI Operon and Analysis of the Regulatory Role of HPr , 1999, Journal of bacteriology.

[15]  W. D. de Vos,et al.  Clustered organization and transcriptional analysis of a family of five csp genes of Lactococcus lactis MG1363. , 1998, Microbiology.

[16]  V. Crow,et al.  Galactose fermentation by Streptococcus lactis and Streptococcus cremoris: pathways, products, and regulation , 1980, Journal of bacteriology.

[17]  W. D. de Vos,et al.  Controlled gene expression systems for Lactococcus lactis with the food-grade inducer nisin , 1996, Applied and environmental microbiology.

[18]  B E Davidson,et al.  Lactococcus lactis glyceraldehyde-3-phosphate dehydrogenase gene, gap: further evidence for strongly biased codon usage in glycolytic pathway genes. , 1995, Microbiology.

[19]  J. Sambrook,et al.  Molecular Cloning: A Laboratory Manual , 2001 .

[20]  Y. Fujita,et al.  Specific recognition of the Bacillus subtilis gnt cis‐acting catabolite‐responsive element by a protein complex formed between CcpA and seryl‐phosphorylated HPr , 1995, Molecular microbiology.

[21]  G. Stanley,et al.  Product formation and phosphoglucomutase activities in Lactococcus lactis: cloning and characterization of a novel phosphoglucomutase gene. , 1997, Microbiology.

[22]  F. Vogensen,et al.  Induction of heat shock proteins DnaK, GroEL, and GroES by salt stress in Lactococcus lactis , 1997, Applied and environmental microbiology.

[23]  B. Poolman,et al.  Control of glycolysis by glyceraldehyde-3-phosphate dehydrogenase in Streptococcus cremoris and Streptococcus lactis , 1987, Journal of bacteriology.

[24]  Jeroen Hugenholtz,et al.  Citrate Fermentation by Lactococcus and Leuconostoc spp , 1991, Applied and environmental microbiology.

[25]  W. D. de Vos,et al.  Characterization of the nisin gene cluster nisABTCIPR of Lactococcus lactis. Requirement of expression of the nisA and nisI genes for development of immunity. , 1993, European journal of biochemistry.

[26]  P. Loubière,et al.  Control of the shift from homolactic acid to mixed-acid fermentation in Lactococcus lactis: predominant role of the NADH/NAD+ ratio , 1997, Journal of bacteriology.

[27]  M. Kleerebezem,et al.  Making more of milk sugar by engineering lactic acid bacteria , 1998 .

[28]  Hillier Aj,et al.  [63] l-Lactate dehydrogenase,1 FDP-activated, from Streptococcus cremoris , 1982 .

[29]  G. Rapoport,et al.  The HPr protein of the phosphotransferase system links induction and catabolite repression of the Bacillus subtilis levanase operon , 1995, Journal of bacteriology.

[30]  G. Venemâ,et al.  Environmental stress responses in Lactococcus lactis , 1999 .