A Computational Approach to Enzyme Design: Predicting ω-Aminotransferase Catalytic Activity Using Docking and MM-GBSA Scoring

Sirin, Sarah; Kumar, Rajesh; Martínez, Carlos A.; Karmilowicz, Michael J.; Ghosh, Preeyantee; Abramov, Yuriy A.; Martin, Van A.; Sherman, Woody

doi:10.1021/ci5002185

Cited by 80 publications

(62 citation statements)

References 56 publications

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“…Similarly to what reported by others, the MM-GBSA approach, as implemented in the program Prime [29–31], was used to estimate relative binding free energies of ligands in docking complexes of Primary and Secondary Sites (Glide pose viewer files, XP level). Calculations were run in parallel using two different set-ups.…”

Section: Methodsmentioning

confidence: 99%

Computational analysis of EBNA1 “druggability” suggests novel insights for Epstein-Barr virus inhibitor design

Gianti

Messick

Lieberman

et al. 2016

J Comput Aided Mol Des

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The Epstein-Barr Nuclear Antigen 1 (EBNA1) is a critical protein encoded by the Epstein-Barr Virus (EBV). During latent infection, EBNA1 is essential for DNA replication and transcription initiation of viral and cellular genes and is necessary to immortalize primary B-lymphocytes. Nonetheless, the concept of EBNA1 as drug target is novel. Two EBNA1 crystal structures are publicly available and the first small-molecule EBNA1 inhibitors were recently discovered. However, no systematic studies have been reported on the structural details of EBNA1 “druggable” binding sites. We conducted computational identification and structural characterization of EBNA1 binding pockets, likely to accommodate ligand molecules (i.e. “druggable” binding sites). Then, we validated our predictions by docking against a set of compounds previously tested in vitro for EBNA1 inhibition (PubChem AID-2381). Finally, we supported assessments of pocket druggability by performing induced fit docking and molecular dynamics simulations paired with binding affinity predictions by Molecular Mechanics Generalized Born Surface Area calculations for a number of hits belonging to druggable binding sites. Our results establish EBNA1 as a target for drug discovery, and provide the computational evidence that active AID-2381 hits disrupt EBNA1:DNA binding upon interacting at individual sites. Lastly, structural properties of top scoring hits are proposed to support the rational design of the next generation of EBNA1 inhibitors.

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Section: Methodsmentioning

confidence: 99%

Computational analysis of EBNA1 “druggability” suggests novel insights for Epstein-Barr virus inhibitor design

Gianti

Messick

Lieberman

et al. 2016

J Comput Aided Mol Des

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“…The assembly of nano-and micro-scale particles into self-folding strings could enable the cost-effective production of responsive meta-materials with unprecedented spatial control over the single particle positions. Indeed, the possible applications of such materials are extremely diverse: from nanoscale switches and sensors that respond to, for instance, temperature, light or pH, to catalysts (mimicking the spatially defined catalysis of proteins) [179][180][181] and materials with three-dimensional connectivity that can be used, e.g., to optimize charge separation in photovoltaics. 182,183 In order to reproduce the protein folding process at the nano-and micro-scale level, patchy particles can prove themselves essential: anisotropically interacting units arranged in strings could play the same role as the residues constituting the proteins, effectively constructing functionalized colloidal chains, the so-called ''patchy polymers'' [184][185][186] (see panel (a) of Fig.…”

Section: Patchy Polymersmentioning

confidence: 99%

Limiting the valence: advancements and new perspectives on patchy colloids, soft functionalized nanoparticles and biomolecules

Bianchi

Capone

Coluzza

et al. 2017

Phys. Chem. Chem. Phys.

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Limited bonding valence, usually accompanied by well-defined directional interactions and selective bonding mechanisms, is nowadays considered among the key ingredients to create complex structures with tailored properties: even though isotropically interacting units already guarantee access to a vast range of functional materials, anisotropic interactions can provide extra instructions to steer the assembly of specific architectures. The anisotropy of effective interactions gives rise to a wealth of self-assembled structures both in the realm of suitably synthesized nano-and micro-sized building blocks and in nature, where the isotropy of interactions is often a zero-th order description of the complicated reality.In this review, we span a vast range of systems characterized by limited bonding valence, from patchy colloids of new generation to polymer-based functionalized nanoparticles, DNA-based systems and proteins, and describe how the interaction patterns of the single building blocks can be designed to tailor the properties of the target final structures.

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“…An in silico model of the HEWT was generated to aid with the design of key mutations, 13 specifically introduced to probe the steric effect of the substituents. The three-dimensional structure was simulated on the resolved structure of the homologs amino transaminase from Cromobacterium violaceum.…”

Section: Resultsmentioning

confidence: 99%

Stereoelectronic effects in the reaction of aromatic substrates catalysed by Halomonas elongata transaminase and its mutants

et al. 2016

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A transaminase from Halomonas elongata and four mutants generated by an in silico-based design, were recombinantly produced in E. coli, purified and applied to the amination of mono-substituted aromatic carbonyl-derivatives. While benzaldehyde derivatives resulted excellent substrates, only NO2-acetophenones were transformed into the (S)-amine with high enantioselectivity. The different behaviour of wild-type and mutated transaminases was assessed by in silico substrate binding mode studies.

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A Computational Approach to Enzyme Design: Predicting ω-Aminotransferase Catalytic Activity Using Docking and MM-GBSA Scoring

Cited by 80 publications

References 56 publications

Computational analysis of EBNA1 “druggability” suggests novel insights for Epstein-Barr virus inhibitor design

Computational analysis of EBNA1 “druggability” suggests novel insights for Epstein-Barr virus inhibitor design

Limiting the valence: advancements and new perspectives on patchy colloids, soft functionalized nanoparticles and biomolecules

Stereoelectronic effects in the reaction of aromatic substrates catalysed by Halomonas elongata transaminase and its mutants

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