Nicholas R. Vance scite author profile

The caspase family of cysteine proteases are highly sought‐after drug targets owing to their essential roles in apoptosis, proliferation, and inflammation pathways. High‐throughput screening efforts to discover inhibitors have gained little traction. Fragment‐based screening has emerged as a powerful approach for the discovery of innovative drug leads. This method has become a central facet of drug discovery campaigns in the pharmaceutical industry and academia. A fragment‐based drug discovery campaign against human caspase‐7 resulted in the discovery of a novel series of allosteric inhibitors. An X‐ray crystal structure of caspase‐7 bound to a fragment hit and a thorough kinetic characterization of a zymogenic form of the enzyme were used to investigate the allosteric mechanism of inhibition. This work further advances our understanding of the mechanisms of allosteric control of this class of pharmaceutically relevant enzymes, and provides a new path forward for drug discovery efforts.

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Development, Optimization, and Structural Characterization of an Efficient Peptide-Based Photoaffinity Cross-Linking Reaction for Generation of Homogeneous Conjugates from Wild-Type Antibodies

Vance¹,

Zacharias²,

Ultsch³

et al. 2018

Bioconjugate Chem.

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Site-specific conjugation of small molecules to antibodies represents an attractive goal for the development of more homogeneous targeted therapies and diagnostics. Most site-specific conjugation strategies require modification or removal of antibody glycans or interchain disulfide bonds or engineering of an antibody mutant that bears a reactive handle. While such methods are effective, they complicate the process of preparing antibody conjugates and can negatively impact biological activity. Herein we report the development and detailed characterization of a robust photoaffinity cross-linking method for site-specific conjugation to fully glycosylated wild-type antibodies. The method employs a benzoylphenylalanine (Bpa) mutant of a previously described 13-residue peptide derived from phage display to bind tightly to the Fc domain; upon UV irradiation, the Bpa residue forms a diradical that reacts with the bound antibody. After the initial discovery of an effective Bpa mutant peptide and optimization of the reaction conditions to enable efficient conjugation without concomitant UV-induced photodamage of the antibody, we assessed the scope of the photoconjugation reaction across different human and nonhuman antibodies and antibody mutants. Next, the specific site of conjugation on a human antibody was characterized in detail by mass spectrometry experiments and at atomic resolution by X-ray crystallography. Finally, we adapted the photoconjugation method to attach a cytotoxic payload site-specifically to a wild-type antibody and showed that the resulting conjugate is both stable in plasma and as potent as a conventional antibody–drug conjugate in cells, portending well for future biological applications.

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An Atomistic Understanding of Allosteric Inhibition of Glutamate Racemase: a Dampening of Native Activation Dynamics

et al. 2020

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Glutamate racemases (GR) are members of the family of bacterial enzymes known as cofactor‐independent racemases and epimerases and catalyze the stereoinversion of glutamate. D‐amino acids are universally important for the proper construction of viable bacterial cell walls, and thus have been repeatedly validated as attractive targets for novel antimicrobial drug design. Significant aspects of the mechanism of this challenging stereoinversion remain unknown. The current study employs a combination of MD and QM/MM computational approaches to show that the GR from H. pylori must proceed via a pre‐activation step, which is dependent on the enzyme's flexibility. This mechanism is starkly different from previously proposed mechanisms. These findings have immediate pharmaceutical relevance, as the H. pylori GR enzyme is a very attractive allosteric drug target. The results presented in this study offer a distinctly novel understanding of how AstraZeneca's lead series of inhibitors cripple the H. pylori GR's native motions, via prevention of this critical chemical pre‐activation step. Our experimental studies, using SPR, fluorescence and NMR WaterLOGSY, show that H. pylori GR is not inhibited by the uncompetitive mechanism originally put forward by Lundqvist et al.. The current study supports a deep connection between native enzyme motions and chemical reactivity, which has strong relevance to the field of allosteric drug discovery.

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Elucidating the Catalytic Power of Glutamate Racemase by Investigating a Series of Covalent Inhibitors

et al. 2018

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The application of covalent inhibitors has experienced a renaissance within drug discovery programs in the last decade. To leverage the superior potency and drug target residence time of covalent inhibitors, there have been extensive efforts to develop highly specific covalent modifications to reduce off-target liabilities. Herein, we present a series of covalent inhibitors of an antimicrobial drug target, glutamate racemase, discovered through structure-based virtual screening. A combination of enzyme kinetics, mass spectrometry, and surface-plasmon resonance experiments details a highly specific 1,4-conjugate addition of a small molecule inhibitor with a catalytic cysteine of glutamate racemase. Molecular dynamics simulations and quantum mechanics-molecular mechanics geometry optimizations reveal the chemistry of the conjugate addition. Two compounds from this series of inhibitors display antimicrobial potency comparable to β-lactam antibiotics, with significant activity against methicillin-resistant S. aureus strains. This study elucidates a detailed chemical rationale for covalent inhibition and provides a platform for the development of antimicrobials with a novel mechanism of action against a target in the cell wall biosynthesis pathway.

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Allosteric Tuning of Caspase‐7: A Fragment‐Based Drug Discovery Approach

2017

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The caspase family of cysteine proteases are highly sought-after drug targets owing to their essential roles in apoptosis,p roliferation, and inflammation pathways. Highthroughput screening efforts to discover inhibitors have gained little traction. Fragment-based screening has emerged as ap owerfula pproach for the discovery of innovative drug leads.T his method has become ac entral facet of drug discovery campaigns in the pharmaceutical industry and academia. Afragment-based drug discovery campaign against human caspase-7 resulted in the discovery of anovel series of allosteric inhibitors.A nX -ray crystal structure of caspase-7 bound to af ragment hit and at horough kinetic characterization of az ymogenic form of the enzyme were used to investigate the allosteric mechanism of inhibition. This work further advances our understanding of the mechanisms of allosteric control of this class of pharmaceutically relevant enzymes,and provides anew path forwardfor drug discovery efforts.

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Nicholas R. Vance

Allosteric Tuning of Caspase‐7: A Fragment‐Based Drug Discovery Approach

Development, Optimization, and Structural Characterization of an Efficient Peptide-Based Photoaffinity Cross-Linking Reaction for Generation of Homogeneous Conjugates from Wild-Type Antibodies

An Atomistic Understanding of Allosteric Inhibition of Glutamate Racemase: a Dampening of Native Activation Dynamics

Elucidating the Catalytic Power of Glutamate Racemase by Investigating a Series of Covalent Inhibitors

Allosteric Tuning of Caspase‐7: A Fragment‐Based Drug Discovery Approach

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