Activity of linked HIV-1 proteinase dimers containing mutations in the active site region

β-lactam antibiotics have been used effectively over several decades against many types of highly virulent bacteria. The predominant cause of resistance to these antibiotics in Gram-negative bacterial pathogens is the production of serine β-lactamase enzymes. A key aspect of the class A serine β-lactamase mechanism that remains unresolved and controversial is the identity of the residue acting as the catalytic base during the acylation reaction. Multiple mechanisms have been proposed for the formation of the acyl-enzyme intermediate that are predicated on understanding the protonation states and hydrogen-bonding interactions among the important residues involved in substrate binding and catalysis of these enzymes. For resolving a controversy of this nature surrounding the catalytic mechanism, neutron crystallography is a powerful complement to X-ray crystallography that can explicitly determine the location of deuterium atoms in proteins, thereby directly revealing the hydrogen-bonding interactions of important amino acid residues. Neutron crystallography was used to unambiguously reveal the ground-state active site protonation states and the resulting hydrogen-bonding network in two ligand-free Toho-1 β-lactamase mutants which provided remarkably clear pictures of the active site region prior to substrate binding and subsequent acylation [1,2] and an acylation transition-state analog, benzothiophene-2-boronic acid (BZB), which was also isotopically enriched with 11B. The neutron structure revealed the locations of all deuterium atoms in the active site region and clearly indicated that Glu166 is protonated in the BZB transition-state analog complex. As a result, the complete hydrogen-bonding pathway throughout the active site region could then deduced for this protein-ligand complex that mimics the acylation tetrahedral intermediate [3].

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Digital dissection of arsenate reductase enzyme from an arsenic hyperccumulating fern Pteris vittata

10.1101/056036 ◽

2016 ◽

Author(s):

Zarrin Basharat ◽

Deeba Noreen Baig ◽

Azra Yasmin

Keyword(s):

Neural Network ◽

Active Site ◽

Tertiary Structure ◽

Pteris Vittata ◽

Arsenate Reductase ◽

Dynamics Simulation ◽

Reduction Mechanism ◽

Arsenic Reduction ◽

Secondary And Tertiary Structure ◽

Active Site Region

Action of arsenate reductase is crucial for the survival of an organism in arsenic polluted area. Pteris vittata, also known as Chinese ladder brake, was the first identified arsenic hyperaccumulating fern with the capability to convert [As(V)] to arsenite [As(III)]. This study aims at sequence analysis of the most important protein of the arsenic reduction mechanism in this specie. Phosphorylation potential of the protein along with possible interplay of phosphorylation with O-β-GlcNAcylation was predicted using neural network based webservers. Secondary and tertiary structure of arsenate reductase was then analysed. Active site region of the protein comprised a rhodanese-like domain. Cursory dynamics simulation revealed that folds remained conserved in the rhodanese main but variations were observed in the structure in other regions. This information sheds light on the various characteristics of the protein and may be useful to enzymologists working on the improvement of its traits for arsenic reduction.

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Salicylhydrazine-Containing Inhibitors of HIV-1 Integrase: Implication for a Selective Chelation in the Integrase Active Site

Journal of Medicinal Chemistry ◽

10.1021/jm9801760 ◽

1998 ◽

Vol 41 (17) ◽

pp. 3202-3209 ◽

Cited By ~ 65

Author(s):

Nouri Neamati ◽

Huixiao Hong ◽

Joshua M. Owen ◽

Sanjay Sunder ◽

Heather E. Winslow ◽

...

Keyword(s):

Active Site ◽

Hiv 1

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Theoretical study on the mechanism of a ring-opening reaction of oxirane by the active-site aspartic dyad of HIV-1 protease

Organic & Biomolecular Chemistry ◽

10.1039/b715828a ◽

2008 ◽

Vol 6 (2) ◽

pp. 359-365 ◽

Cited By ~ 7

Author(s):

Juraj Kóňa

Keyword(s):

Active Site ◽

Ring Opening ◽

Theoretical Study ◽

Ring Opening Reaction ◽

Hiv 1

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Structural Basis for the Inhibition of RNase H Activity of HIV-1 Reverse Transcriptase by RNase H Active Site-Directed Inhibitors

Journal of Virology ◽

10.1128/jvi.00353-10 ◽

2010 ◽

Vol 84 (15) ◽

pp. 7625-7633 ◽

Cited By ~ 70

Author(s):

Hua-Poo Su ◽

Youwei Yan ◽

G. Sridhar Prasad ◽

Robert F. Smith ◽

Christopher L. Daniels ◽

...

Keyword(s):

Active Site ◽

Thermal Denaturation ◽

Binding Mode ◽

Rnase H ◽

New Drugs ◽

Structural Basis ◽

Independent Manner ◽

Approved Drugs ◽

Hiv 1 ◽

Rapid Emergence

ABSTRACT HIV/AIDS continues to be a menace to public health. Several drugs currently on the market have successfully improved the ability to manage the viral burden in infected patients. However, new drugs are needed to combat the rapid emergence of mutated forms of the virus that are resistant to existing therapies. Currently, approved drugs target three of the four major enzyme activities encoded by the virus that are critical to the HIV life cycle. Although a number of inhibitors of HIV RNase H activity have been reported, few inhibit by directly engaging the RNase H active site. Here, we describe structures of naphthyridinone-containing inhibitors bound to the RNase H active site. This class of compounds binds to the active site via two metal ions that are coordinated by catalytic site residues, D443, E478, D498, and D549. The directionality of the naphthyridinone pharmacophore is restricted by the ordering of D549 and H539 in the RNase H domain. In addition, one of the naphthyridinone-based compounds was found to bind at a second site close to the polymerase active site and non-nucleoside/nucleotide inhibitor sites in a metal-independent manner. Further characterization, using fluorescence-based thermal denaturation and a crystal structure of the isolated RNase H domain reveals that this compound can also bind the RNase H site and retains the metal-dependent binding mode of this class of molecules. These structures provide a means for structurally guided design of novel RNase H inhibitors.

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