Structure of a bacterial pyridoxal 5'-phosphate synthase complex

Vitamin B₆ is an essential metabolic cofactor that has more functions in humans than any other single nutrient. Its de novo biosynthesis occurs through two mutually exclusive pathways that are absent in animals. The predominant pathway found in most prokaryotes, fungi, and plants has only recently b...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 103; no. 51; pp. 19284 - 19289
Main Authors Strohmeier, Marco, Raschle, Thomas, Mazurkiewicz, Jacek, Rippe, Karsten, Sinning, Irmgard, Fitzpatrick, Teresa B, Tews, Ivo
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 19.12.2006
National Acad Sciences
Subjects
Active sites
Amino acids
Ammonia
Architecture
Bacillus subtilis - chemistry
Bacteria
Biochemistry
Biological Sciences
Catalysis
Enzymes
Glutaminase - chemistry
Glutamine - chemistry
Models, Molecular
Multiprotein Complexes - chemistry
Mutagenesis
Nitrogen
Protein synthesis
Proteins
Pyridoxal Phosphate - biosynthesis
Pyridoxal Phosphate - chemistry
Tunnels
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Summary:Vitamin B₆ is an essential metabolic cofactor that has more functions in humans than any other single nutrient. Its de novo biosynthesis occurs through two mutually exclusive pathways that are absent in animals. The predominant pathway found in most prokaryotes, fungi, and plants has only recently been discovered. It is distinguished by a glutamine amidotransferase, which is remarkable in that it alone can synthesize the cofactor form, pyridoxal 5'-phosphate (PLP), directly from a triose and a pentose saccharide and glutamine. Here we report the 3D structure of the PLP synthase complex with substrate glutamine bound as well as those of the individual synthase and glutaminase subunits Pdx1 and Pdx2, respectively. The complex is made up of 24 protein units assembled like a cogwheel, a dodecameric Pdx1 to which 12 Pdx2 subunits attach. In contrast to the architecture of previously determined glutamine amidotransferases, macromolecular assembly is directed by an N-terminal α-helix on the synthase. Interaction with the synthase subunit leads to glutaminase activation, resulting in formation of an oxyanion hole, a prerequisite for catalysis. Mutagenesis permitted identification of the remote glutaminase and synthase catalytic centers and led us to propose a mechanism whereby ammonia shuttles between these active sites through a methionine-rich hydrophobic tunnel.
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Author contributions: M.S. and T.R. contributed equally to this work; K.R., T.B.F., and I.T. designed research; M.S., T.R., J.M., T.B.F., and I.T. performed research; M.S., T.R., J.M., K.R., I.S., T.B.F., and I.T. analyzed data; and I.S., T.B.F., and I.T. wrote the paper.
Edited by Robert M. Stroud, University of California, San Francisco, CA, and approved October 14, 2006
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0604950103