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|a Luo, Lingqi
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|a Massachusetts Institute of Technology. Department of Biology
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|a Massachusetts Institute of Technology. Department of Chemistry
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|a Imperiali, Barbara
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|a Lukose, Vinita
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|a Imperiali, Barbara
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|a Kozakov, Dima
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|a Vajda, Sandor
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|a Allen, Karen N.
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|a Lukose, Vinita
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|a Imperiali, Barbara
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|a Conservation and Covariance in Small Bacterial Phosphoglycosyltransferases Identify the Functional Catalytic Core
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|b American Chemical Society (ACS),
|c 2017-01-25T21:11:15Z.
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|z Get fulltext
|u http://hdl.handle.net/1721.1/106626
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|a Phosphoglycosyltransferases (PGTs) catalyze the transfer of a C1'-phosphosugar from a soluble sugar nucleotide diphosphate to a polyprenol phosphate. These enzymes act at the membrane interface, forming the first membrane-associated intermediates in the biosynthesis of cell-surface glycans and glycoconjugates, including glycoproteins, glycolipids, and the peptidoglycan in bacteria. PGTs vary greatly in both their membrane topologies and their substrate preferences. PGTs, such as MraY and WecA, are polytopic, while other families of uniquely prokaryotic enzymes have only a single predicted transmembrane helix. PglC, a PGT involved in the biosynthesis of N-linked glycoproteins in the enteropathogen Campylobacter jejuni, is representative of one of the structurally most simple members of the diverse family of small bacterial PGT enzymes. Herein, we apply bioinformatics and covariance-weighted distance constraints in geometry- and homology-based model building, together with mutational analysis, to investigate monotopic PGTs. The pool of 15000 sequences that are analyzed include the PglC-like enzymes, as well as sequences from two other related PGTs that contain a "PglC-like" domain embedded in their larger structures (namely, the bifunctional PglB family, typified by PglB from Neisseria gonorrheae, and WbaP-like enzymes, typified by WbaP from Salmonella enterica). Including these two subfamilies of PGTs in the analysis highlights key residues conserved across all three families of small bacterial PGTs. Mutagenesis analysis of these conserved residues provides further information about the essentiality of many of these residues in catalysis. Construction of a structural model of the cytosolic globular domain utilizing three-dimensional distance constraints, provided by conservation covariance analysis, provides additional insight into the catalytic core of these families of small bacterial PGT enzymes.
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|a National Institutes of Health (U.S.) (NIH Grant Number: R21 AI101807)
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|a National Institutes of Health (U.S.) (NIH Grant Number: GM039334)
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|a National Institutes of Health (U.S.) (NIH Grant Number: R01 GM064700)
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|a National Institutes of Health (U.S.) (NIH Grant Number: R01 GM 061867)
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|a en_US
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|a Article
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|t Biochemistry
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