Article

Identification of malic and soluble oxaloacetate decarboxylase enzymes in Enterococcus faecalis.

Instituto de Biología Molecular y Celular de Rosario (IBR-CONICET), Universidad Nacional de Rosario, Argentina.
FEBS Journal (impact factor: 3.79). 04/2011; 278(12):2140-51. DOI:10.1111/j.1742-4658.2011.08131.x pp.2140-51
Source: PubMed

ABSTRACT Two paralogous genes, maeE and citM, that encode putative malic enzyme family members were identified in the Enterococcus faecalis genome. MaeE (41 kDa) and CitM (42 kDa) share a high degree of homology between them (47% identities and 68% conservative substitutions). However, the genetic context of each gene suggested that maeE is associated with malate utilization whereas citM is linked to the citrate fermentation pathway. In the present work, we focus on the biochemical characterization and physiological contribution of these enzymes in E. faecalis. With this aim, the recombinant versions of the two proteins were expressed in Escherichia coli, affinity purified and finally their kinetic parameters were determined. This approach allowed us to establish that MaeE is a malate oxidative decarboxylating enzyme and CitM is a soluble oxaloacetate decarboxylase. Moreover, our genetic studies in E. faecalis showed that the citrate fermentation phenotype is not affected by citM deletion. On the other hand, maeE gene disruption resulted in a malate fermentation deficient strain indicating that MaeE is responsible for malate metabolism in E. faecalis. Lastly, it was demonstrated that malate fermentation in E. faecalis is associated with cytoplasmic and extracellular alkalinization which clearly contributes to pH homeostasis in neutral or mild acidic conditions.

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    Article: CcpA represses the expression of the divergent cit operons of Enterococcus faecalis through multiple cre sites.
    Cristian A Suárez, Víctor S Blancato, Sandrine Poncet, Josef Deutscher, Christian Magni
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    ABSTRACT: In Enterococcus faecalis the genes encoding the enzymes involved in citrate metabolism are organized in two divergent operons, citHO and oadHDB-citCDEFX-oadA-citMG (citCL locus). Expression of both operons is specifically activated by adding citrate to the medium. This activation is mediated by binding of the GntR-like transcriptional regulator (CitO) to the cis-acting sequences located in the cit intergenic region. Early studies indicated that citrate and glucose could not be co-metabolized suggesting some form of catabolite repression, however the molecular mechanism remained unknown. In this study, we observed that the citHO promoter is repressed in the presence of sugars transported by the Phosphoenolpyruvate:carbohydrate Phosphotranserase System (PTS sugars). This result strongly suggested that Carbon Catabolic Repression (CCR) impedes the expression of the activator CitO and the subsequent induction of the cit pathway. In fact, we demonstrate that CCR is acting on both promoters. It is partially relieved in a ccpA-deficient E. faecalis strain indicating that a CcpA-independent mechanism is also involved in regulation of the two operons. Furthermore, sequence analysis of the citH/oadH intergenic region revealed the presence of three putative catabolite responsive elements (cre). We found that they are all active and able to bind the CcpA/P-Ser-HPr complex, which downregulates the expression of the cit operons. Systematic mutation of the CcpA/P-Ser-HPr binding sites revealed that cre1 and cre2 contribute to citHO repression, while cre3 is involved in CCR of citCL. In conclusion, our study establishes that expression of the cit operons in E. faecalis is controlled by CCR via CcpA-dependent and -independent mechanisms.
    BMC Microbiology 01/2011; 11:227. · 3.04 Impact Factor
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Keywords

47% identities
 
68% conservative substitutions
 
affinity purified
 
biochemical characterization
 
citM deletion
 
citrate fermentation phenotype
 
E. faecalis
 
Enterococcus faecalis genome
 
extracellular alkalinization
 
genetic context
 
genetic studies
 
maeE gene disruption
 
malate fermentation
 
malate fermentation deficient strain
 
malate oxidative decarboxylating enzyme
 
malate utilization
 
mild acidic conditions
 
pH homeostasis
 
physiological contribution
 
soluble oxaloacetate decarboxylase
 

Guillermo D Repizo