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CcpA Regulates Central Metabolism and Virulence Gene Expression in Streptococcus mutans ^,

Jacqueline Abranches ,^, Marcelle M. Nascimento, Lin Zeng, Christopher M. Browngardt, Zezhang T. Wen, Mercedes F. Rivera, and Robert A. Burne^*

Department of Oral Biology, University of Florida College of Dentistry, P.O. Box 100424, Gainesville, Florida 32610

Received 31 July 2007/ Accepted 6 January 2008

CcpA globally regulates transcription in response to carbohydrate availability in many gram-positive bacteria, but its role in Streptococcus mutans remains enigmatic. Using the fructan hydrolase (fruA) gene of S. mutans as a model, we demonstrated that CcpA plays a direct role in carbon catabolite repression (CCR). Subsequently, the expression of 170 genes was shown to be differently expressed (2-fold) in glucose-grown wild-type (UA159) and CcpA-deficient (TW1) strains (P 0.001). However, there were differences in expression of only 96 genes between UA159 and TW1 when cells were cultivated with the poorly repressing substrate galactose. Interestingly, 90 genes were expressed differently in wild-type S. mutans when glucose- and galactose-grown cells were compared, but the expression of 515 genes was altered in the CcpA-deficient strain in a similar comparison. Overall, our results supported the hypothesis that CcpA has a major role in CCR and regulation of gene expression but revealed that in S. mutans there is a substantial CcpA-independent network that regulates gene expression in response to the carbohydrate source. Based on the genetic studies, biochemical and physiological experiments demonstrated that loss of CcpA impacts the ability of S. mutans to transport and grow on selected sugars. Also, the CcpA-deficient strain displayed an enhanced capacity to produce acid from intracellular stores of polysaccharides, could grow faster at pH 5.5, and could acidify the environment more rapidly and to a greater extent than the parental strain. Thus, CcpA directly modulates the pathogenic potential of S. mutans through global control of gene expression.

Published ahead of print on 25 January 2008.

Supplemental material for this article may be found at http://jb.asm.org/.

J.A., M.M.N., and L.Z. contributed equally to this work.

Present address: University of Rochester Medical Center, Box 611, 601 Elmwood Avenue, Rochester, NY 14642.