Publications

• CmaE: a transferase shuttling aminoacyl groups between carrier protein domains in the coronamic acid biosynthetic pathway.

  Strieter E.R., Vaillancourt F.H., Walsh C.T.

  During the biosynthesis of the cyclopropyl amino acid coronamic acid from l-allo-Ile by the phytotoxic Pseudomonas syringae, the aminoacyl group covalently attached to the pantetheinyl arm of CmaA is shuttled to the HS-pantetheinyl arm of the protein CmaD by the aminoacyltransferase CmaE. CmaE wil ... >> More

  During the biosynthesis of the cyclopropyl amino acid coronamic acid from l-allo-Ile by the phytotoxic Pseudomonas syringae, the aminoacyl group covalently attached to the pantetheinyl arm of CmaA is shuttled to the HS-pantetheinyl arm of the protein CmaD by the aminoacyltransferase CmaE. CmaE will only recognize deacylated CmaA for initial complexation. The aminoacyl group becomes covalently attached to the active site Cys of CmaE and can then be transferred out to the holo pantetheinylated form of CmaD. Both l-Val/l-[14C]Val exchange studies and MALDI-TOF support a reversible shuttling process. Aminoacylated-S-CmaE will transfer the l-Val moiety to the HS-pantetheinyl arm of other T domains, including CytC2, BarA, and ArfA C2-A2-T2 but not to free HS-pantetheine. CmaD could be loaded with other amino acids, for example, l-Leu and l-Thr, by the action of heterologous donor T domains containing alternative aminoacyl groups. Additionally, CmaE is able to accept l-Phe as a substrate when presented on CmaD and is able to load this aminoacyl moiety onto heterologous T domains, expanding the potential for CmaE to be used as a tool for generating chemical diversity within an NRPS assembly line. << Less

  Biochemistry 46:7549-7557(2007) [PubMed] [EuropePMC]

• Cryptic chlorination by a non-haem iron enzyme during cyclopropyl amino acid biosynthesis.

  Vaillancourt F.H., Yeh E., Vosburg D.A., O'Connor S.E., Walsh C.T.

  Enzymatic incorporation of chlorine, bromine or iodine atoms occurs during the biosynthesis of more than 4,000 natural products. Halogenation can have significant consequences for the bioactivity of these products so there is great interest in understanding the biological catalysts that perform th ... >> More

  Enzymatic incorporation of chlorine, bromine or iodine atoms occurs during the biosynthesis of more than 4,000 natural products. Halogenation can have significant consequences for the bioactivity of these products so there is great interest in understanding the biological catalysts that perform these reactions. Enzymes that halogenate unactivated aliphatic groups have not previously been characterized. Here we report the activity of five proteins-CmaA, CmaB, CmaC, CmaD and CmaE-in the construction of coronamic acid (CMA; 1-amino-1-carboxy-2-ethylcyclopropane), a constituent of the phytotoxin coronatine synthesized by the phytopathogenic bacterium Pseudomonas syringae. CMA derives from l-allo-isoleucine, which is covalently attached to CmaD through the actions of CmaA, a non-ribosomal peptide synthetase module, and CmaE, an unusual acyltransferase. We show that CmaB, a member of the non-haem Fe(2+), alpha-ketoglutarate-dependent enzyme superfamily, is the first of its class to show halogenase activity, chlorinating the gamma-position of l-allo-isoleucine. Another previously undescribed enzyme, CmaC, catalyses the formation of the cyclopropyl ring from the gamma-Cl-l-allo-isoleucine product of the CmaB reaction. Together, CmaB and CmaC execute gamma-halogenation followed by intramolecular gamma-elimination, in which biological chlorination is a cryptic strategy for cyclopropyl ring formation. << Less

  Nature 436:1191-1194(2005) [PubMed] [EuropePMC]