PLoS Pathogens (Feb 2015)

Characterization of the mycobacterial acyl-CoA carboxylase holo complexes reveals their functional expansion into amino acid catabolism.

  • Matthias T Ehebauer,
  • Michael Zimmermann,
  • Arjen J Jakobi,
  • Elke E Noens,
  • Daniel Laubitz,
  • Bogdan Cichocki,
  • Hedia Marrakchi,
  • Marie-Antoinette Lanéelle,
  • Mamadou Daffé,
  • Carsten Sachse,
  • Andrzej Dziembowski,
  • Uwe Sauer,
  • Matthias Wilmanns

DOI
https://doi.org/10.1371/journal.ppat.1004623
Journal volume & issue
Vol. 11, no. 2
p. e1004623

Abstract

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Biotin-mediated carboxylation of short-chain fatty acid coenzyme A esters is a key step in lipid biosynthesis that is carried out by multienzyme complexes to extend fatty acids by one methylene group. Pathogenic mycobacteria have an unusually high redundancy of carboxyltransferase genes and biotin carboxylase genes, creating multiple combinations of protein/protein complexes of unknown overall composition and functional readout. By combining pull-down assays with mass spectrometry, we identified nine binary protein/protein interactions and four validated holo acyl-coenzyme A carboxylase complexes. We investigated one of these--the AccD1-AccA1 complex from Mycobacterium tuberculosis with hitherto unknown physiological function. Using genetics, metabolomics and biochemistry we found that this complex is involved in branched amino-acid catabolism with methylcrotonyl coenzyme A as the substrate. We then determined its overall architecture by electron microscopy and found it to be a four-layered dodecameric arrangement that matches the overall dimensions of a distantly related methylcrotonyl coenzyme A holo complex. Our data argue in favor of distinct structural requirements for biotin-mediated γ-carboxylation of α-β unsaturated acid esters and will advance the categorization of acyl-coenzyme A carboxylase complexes. Knowledge about the underlying structural/functional relationships will be crucial to make the target category amenable for future biomedical applications.