Keyword search (4,163 papers available)

"Orabi EA" Authored Publications:

Title Authors PubMed ID
1 Modeling CH sub 3 /sub SOH-aromatic complexes to probe cysteine sulfenic acid-aromatic interactions in proteins Orabi EA; English AM; 40994121
CHEMBIOCHEM
2 Modeling predicts facile release of nitrite but not nitric oxide from the thionitrate CH3SNO2 with relevance to nitroglycerin bioactivation Parmar V; Orabi EA; English AM; Peslherbe GH; 39738238
CERMM
3 Ammonium transporters achieve charge transfer by fragmenting their substrate Wang S; Orabi EA; Baday S; Bernèche S; Lamoureux G; 22631217
CERMM
4 New Megastigmane and Polyphenolic Components of Henna Leaves and Their Tumor-Specific Cytotoxicity on Human Oral Squamous Carcinoma Cell Lines Orabi MAA; Orabi EA; Awadh AAA; Alshahrani MM; Abdel-Wahab BA; Sakagami H; Hatano T; 38001804
CHEMBIOCHEM
5 Structural determination and anticholinesterase assay of C-glycosidic ellagitannins from Lawsonia inermis leaves: A study supported by DFT calculations and molecular docking Orabi MAA; Orabi EA; Abdel-Sattar ES; English AM; Hatano T; Elimam H; 36423882
CHEMBIOCHEM
6 Modeling Shows that Rotation about the Peroxide O-O Bond Assists Protein and Lipid Functional Groups in Discriminating between H2O2 and H2O Orabi EA; English AM; 33356279
CHEMBIOCHEM
7 Drude polarizable force field for cation-π interactions of alkali and quaternary ammonium ions with aromatic amino acid side chains Orabi EA; Davis RL; Lamoureux G; 31652004
CERMM
8 Computational insight into hydrogen persulfide and a new additive model for chemical and biological simulations Orabi EA; Peslherbe GH; 31297500
CHEMBIOCHEM
9 Expanding the range of binding energies and oxidizability of biologically relevant S-aromatic interactions: imidazolium and phenolate binding to sulfoxide and sulfone Orabi EA; English AM; 31214677
CHEMBIOCHEM
10 Predicting structural and energetic changes in Met-aromatic motifs on methionine oxidation to the sulfoxide and sulfone Orabi EA; English AM; 30168822
CHEMBIOCHEM

 

Title:Ammonium transporters achieve charge transfer by fragmenting their substrate
Authors:Wang SOrabi EABaday SBernèche SLamoureux G
Link:https://pubmed.ncbi.nlm.nih.gov/22631217/
DOI:10.1021/ja300129x
Publication:Journal of the American Chemical Society
Keywords:
PMID:22631217 Category: Date Added:2012-05-29
Dept Affiliation: CERMM
1 Department of Chemistry and Biochemistry and Centre for Research in Molecular Modeling (CERMM), Concordia University, 7141 Sherbrooke Street West, Montréal, Québec H4B?1R6, Canada.

Description:

Proteins of the Amt/MEP family facilitate ammonium transport across the membranes of plants, fungi, and bacteria and are essential for growth in nitrogen-poor environments. Some are known to facilitate the diffusion of the neutral NH(3), while others, notably in plants, transport the positively charged NH(4)(+). On the basis of the structural data for AmtB from Escherichia coli , we illustrate the mechanism by which proteins from the Amt family can sustain electrogenic transport. Free energy calculations show that NH(4)(+) is stable in the AmtB pore, reaching a binding site from which it can spontaneously transfer a proton to a pore-lining histidine residue (His168). The substrate diffuses down the pore in the form of NH(3), while the excess proton is cotransported through a highly conserved hydrogen-bonded His168-His318 pair. This constitutes a novel permeation mechanism that confers to the histidine dyad an essential mechanistic role that was so far unknown.





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