Abstract
Mycolic acids are major components of the cell wall of Mycobacterium tuberculosis. Several studies indicate that functional groups in the acyl chain of mycolic acids are important for pathogenesis and persistence. There are at least three mycolic acid cyclopropane synthases (PcaA, CmaA1, and CmaA2) that are responsible for these site-specific modifications of mycolic acids. To derive information on the specificity and enzyme mechanism of the family of proteins, the crystal structures of CmaA1, CmaA2, and PcaA were solved to 2-, 2-, and 2.65-A resolution, respectively. All three enzymes have a seven-stranded alpha/beta fold similar to other methyltransferases with the location and interactions with the cofactor S-adenosyl-l-methionine conserved. The structures of the ternary complexes demonstrate the position of the mycolic acid substrate binding site. Close examination of the active site reveals electron density that we believe represents a bicarbonate ion. The structures support the hypothesis that these enzymes catalyze methyl transfer via a carbocation mechanism in which the bicarbonate ion acts as a general base. In addition, comparison of the enzyme structures reveals a possible mechanism for substrate specificity. These structures provide a foundation for rational-drug design, which may lead to the development of new inhibitors effective against persistent bacteria.
Highlights
Tuberculosis remains a leading cause of mortality worldwide, with ϳ2 million people dying of the disease in 1997 (1)
This points to an urgent need for new anti-mycobacterials, therapies effective against persistent bacteria that could clear infection, rapidly reducing treatment times
Given this priority for the discovery of new anti-tuberculosis drugs, interest has been focused on a family of proteins that is involved in modifications of mycolic acids, very long chain lipids that are found either covalently attached to the cell wall or in the form of cord factor and have been demonstrated to be important in the persistent phase of infection
Summary
The first protein to be identified from M. tuberculosis involved in carrying out these modifications at either the distal or proximal position of mycolic acids was a cyclopropane mycolic acid synthase (cmaA1) (9). Comparison of the structure of CmaA1, which is believed to catalyze cyclopropanation at the distal position versus the structures of CmaA2 and PcaA, both of which catalyze this reaction at the proximal position of the meromycolate chain, suggest a possible basis for substrate specificity within this group of homologous enzymes. These high resolution structures, which are the first of an enzyme catalyzing synthesis of a cyclopropane ring to a lipid acceptor to be presented, are invaluable for rationaldrug design against these new targets in mycolic acid biosynthesis
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