Hai L. Tran scite author profile

The field of chemical modification of proteins has been dominated by random modification of lysines or more site-specific labeling of cysteines, each with attendant challenges. Recently, we have developed oxaziridine chemistry for highly selective modification of methionine called redox-activated chemical tagging (ReACT) but have not broadly tested the molecular parameters for efficient and stable protein modification. Here we systematically scanned methionines throughout one of the most popular antibody scaffolds, trastuzumab, used for antibody engineering and drug conjugation. We tested the expression, reactivities, and stabilities of 123 single engineered methionines distributed over the surface of the antibody when reacted with oxaziridine. We found uniformly high expression for these mutants and excellent reaction efficiencies with a panel of oxaziridines. Remarkably, the stability to hydrolysis of the sulfimide varied more than 10-fold depending on temperature and the site of the engineered methionine. Interestingly, the most stable and reactive sites were those that were partially buried, presumably because of their reduced access to water. There was also a 10-fold variation in stability depending on the nature of the oxaziridine, which was determined to be inversely correlated with the electrophilic nature of the sulfimide. Importantly, the stabilities of the best analogs were sufficient to support their use as antibody drug conjugates and potent in a breast cancer mouse xenograft model over a month. These studies provide key parameters for broad application of ReACT for efficient, stable, and site-specific antibody and protein bioconjugation to native or engineered methionines.

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Structure–Activity Relationship and Molecular Mechanics Reveal the Importance of Ring Entropy in the Biosynthesis and Activity of a Natural Product

Tran¹,

Lexa²,

Julien³

et al. 2017

J. Am. Chem. Soc.

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Macrocycles are appealing drug candidates due to their high-affinity, specificity, and favorable pharmacological properties. In this study, we explored the effects of chemical modifications to a natural product macrocycle upon its activity, 3D geometry, and conformational entropy. We chose thiocillin as a model system, a thiopeptide in the ribosomally-encoded family of natural products that exhibits potent antimicrobial effects against gram-positive bacteria. Since thiocillin is derived from a genetically-encoded peptide scaffold, site-directed mutagenesis allows for rapid generation of analogs. To understand thiocillin’s structure-activity relationship, we generated a site-saturation mutagenesis library covering each position along thiocillin’s macrocyclic ring. We report the identification of eight unique compounds more potent than WT thiocillin, the best having an 8-fold improvement in potency. Computational modeling of thiocillin’s macrocyclic structure revealed a striking requirement for a low entropy macrocycle for activity. The populated ensembles of the active mutants showed a rigid structure with few adoptable conformations while inactive mutants showed a more flexible macrocycle which is unfavorable for binding. This finding highlights the importance of macrocyclization in combination with rigidifying post-translational modifications to achieve high potency binding.

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Systematic identification of engineered methionines and oxaziridines for efficient, stable, and site-specific antibody bioconjugation

Elledge¹,

Tran²,

Christian³

et al. 2019

Preprint

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Chemical modification of antibodies is one of the most important bioconjugations utilized by biologists and biotechnology. To date, the field has been dominated by random modification of lysines or more site-specific labeling of cysteines, each with attendant challenges. Recently we have developed oxaziridine chemistry for highly selective and efficient sulfimide modification of methionine called redox-activated chemical tagging (ReACT). Here, we systematically scanned methionines throughout one of the most popular antibody scaffolds, trastuzumab, for antibody engineering and drug conjugation. We tested the expression, reactivities, and stabilities of 123 single engineered methionines distributed over the surface of the antibody when reacted with oxaziridine. We found uniformly high expression for these mutants and generally good reaction efficiencies with the panel of oxaziridines. Remarkably, the stability to hydrolysis of the sulfimide varied more than ten-fold depending on temperature and the site of the engineered methionine.Interestingly, the most stable and reactive sites were those that were partially buried, likely because of their reduced access to water. There was also a ten-fold variation in stability depending on the nature of the oxaziridine, which we determined was inversely correlated with the electrophilic nature of the sulfimide. Importantly, the stabilities of the best analogs and antibody drug conjugate potencies were comparable to those reported for cysteine-maleimide modifications of trastuzumab. We also found our antibody drug conjugates to be potent in a breast cancer mouse xenograft model. These studies provide a roadmap for broad application of ReACT for efficient, stable, and site-specific antibody and protein bioconjugation.3 Introduction:

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Selection of improved peptide ligases by yeast surface display

et al. 2012

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The ability to ligate synthetic peptides with high efficiency will be of tremendous value to the scientific community by enabling efficient labeling or assembly of proteins. Previously, we have engineered a first generation peptide ligase, called subtiligase, as a tool for semi‐protein synthesis, and for proteomics applications involving labeling N‐termini (N‐terminomics). Under conditions we use for N‐terminomics, subtiligase suffers from a low ligation efficiency. A second generation subtiligase was developed using phage display and a single catalytic turnover selection scheme. However, due to the binary nature of single turnover catalysis, it became difficult to select for enzymes with higher catalytic activities. Here we present a multiple turnover selection technology using yeast display whereby individual turnover events are accounted for by the ligation of a fluorophore‐tagged peptide. The advantages that yeast display provide are high‐copy number of enzymes and dual color fluorescence activated cell sorting for selection and normalization of multiple turnover events. This study provides a rare example of selecting for improved enzyme properties using yeast display. NIGMS 5R01GM081051

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Hai L. Tran

Systematic identification of engineered methionines and oxaziridines for efficient, stable, and site-specific antibody bioconjugation

Structure–Activity Relationship and Molecular Mechanics Reveal the Importance of Ring Entropy in the Biosynthesis and Activity of a Natural Product

Systematic identification of engineered methionines and oxaziridines for efficient, stable, and site-specific antibody bioconjugation

Selection of improved peptide ligases by yeast surface display

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