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Literature DB >> 19807062

The ATP-dependent amide ligases DdaG and DdaF assemble the fumaramoyl-dipeptide scaffold of the dapdiamide antibiotics.

Marie A Hollenhorst¹, Jon Clardy, Christopher T Walsh.

Abstract

The enzymes DdaG and DdaF, encoded in the Pantoea agglomerans dapdiamide antibiotic biosynthetic gene cluster, when expressed in Escherichia coli, form the tandem amide bonds of the dapdiamide scaffold at the expense of ATP cleavage. DdaG uses fumarate, 2,3-diaminopropionate (DAP), and ATP to make fumaroyl-AMP transiently on the way to the N(beta)-fumaroyl-DAP regioisomer. Then DdaF acts as a second ATP-dependent amide ligase, but this enzyme cleaves ATP to ADP and P(i) during amide bond formation. However, DdaF will not accept N(beta)-fumaroyl-DAP; the enzyme requires the fumaroyl moiety to be first converted to the fumaramoyl half-amide in N(beta)-fumaramoyl-DAP. DdaF adds Val, Ile, or Leu to the carboxylate of fumaramoyl-DAP to make dapdiamide A, B, or C, respectively. Thus, to build the dapdiamide antibiotic scaffold, amidation must occur on the fumaroyl-DAP scaffold, after DdaG action but before DdaF catalysis. This is an unusual instance of two ligases acting sequentially in untemplated amide bond formations using attack of substrate carboxylates at P(alpha) (AMP-forming) and then at P(gamma) (ADP-forming) of ATP cosubstrates.

Entities: CellLine Chemical Disease Gene Species

Mesh：

Substances：

Year: 2009 PMID： 19807062 PMCID： PMC2783456 DOI： 10.1021/bi9013165

Source DB: PubMed Journal: Biochemistry ISSN： 0006-2960 Impact factor: 3.162

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