Tyler H. Heibeck scite author profile

Antibody-drug conjugates (ADCs) are a targeted chemotherapeutic currently at the cutting edge of oncology medicine. These hybrid molecules consist of a tumor antigen-specific antibody coupled to a chemotherapeutic small molecule. Through targeted delivery of potent cytotoxins, ADCs exhibit improved therapeutic index and enhanced efficacy relative to traditional chemotherapies and monoclonal antibody therapies. The currently FDA-approved ADCs, Kadcyla (Immunogen/Roche) and Adcetris (Seattle Genetics), are produced by conjugation to surface-exposed lysines, or partial disulfide reduction and conjugation to free cysteines, respectively. These stochastic modes of conjugation lead to heterogeneous drug products with varied numbers of drugs conjugated across several possible sites. As a consequence, the field has limited understanding of the relationships between the site and extent of drug loading and ADC attributes such as efficacy, safety, pharmacokinetics, and immunogenicity. A robust platform for rapid production of ADCs with defined and uniform sites of drug conjugation would enable such studies. We have established a cell-free protein expression system for production of antibody drug conjugates through site-specific incorporation of the optimized non-natural amino acid, para-azidomethyl-l-phenylalanine (pAMF). By using our cell-free protein synthesis platform to directly screen a library of aaRS variants, we have discovered a novel variant of the Methanococcus jannaschii tyrosyl tRNA synthetase (TyrRS), with a high activity and specificity toward pAMF. We demonstrate that site-specific incorporation of pAMF facilitates near complete conjugation of a DBCO-PEG-monomethyl auristatin (DBCO-PEG-MMAF) drug to the tumor-specific, Her2-binding IgG Trastuzumab using strain-promoted azide-alkyne cycloaddition (SPAAC) copper-free click chemistry. The resultant ADCs proved highly potent in in vitro cell cytotoxicity assays.

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S-Glutathiolation of Ras Mediates Redox-sensitive Signaling by Angiotensin II in Vascular Smooth Muscle Cells

Adachi

Pimentel

Heibeck

et al. 2004

Journal of Biological Chemistry

277

209

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Angiotensin II (AII) increases production of reactive oxygen species from NAD(P)H oxidase, a response that contributes to vascular hypertrophy. Here we show in cultured vascular smooth muscle cells that S-glutathiolation of the redox-sensitive Cys 118 on the small GTPase, Ras, plays a critical role in AII-induced hypertrophic signaling. AII simultaneously increased the Ras activity and the S-glutathiolation of Ras (GSS-Ras) detected by biotin-labeled GSH or mass spectrometry. Both the increase in activity and GSS-Ras was labile under reducing conditions, suggesting the essential nature of this thiol modification to Ras activation. Overexpression of catalase, a dominant-negative p47 phox , or glutaredoxin-1 decreased GSS-Ras, Ras activation, p38, and Akt phosphorylation and the induction of protein synthesis by AII. Furthermore, expression of a Cys 118 mutant Ras decreased AII-mediated p38 and Akt phosphorylation as well as protein synthesis. These results show that H 2 O 2 from NAD(P)H oxidase forms GSS-Ras on Cys 118 and increases its activity leading to p38 and Akt phosphorylation, which contributes to the induction of protein synthesis. This study suggests that GSS-Ras is a redox-sensitive signaling switch that participates in the cellular response to AII.

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Isotope-Coded Affinity Tag (ICAT) Approach to Redox Proteomics: Identification and Quantitation of Oxidant-Sensitive Cysteine Thiols in Complex Protein Mixtures

et al. 2004

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An approach is described for the simultaneous identification and quantitation of oxidant-sensitive cysteine thiols in a complex protein mixture using a thiol-specific, acid-cleavable isotope-coded affinity tag (ICAT) reagent (Applied Biosystems, USA). The approach is based on the fact that only free cysteine thiols are susceptible to labeling by the iodoacetamide-based ICAT, and that mass spectrometry can be used to quantitate the relative labeling of free thiols. Applying this approach, we have identified cysteine thiols of proteins in a rabbit heart membrane fraction that are sensitive to a high concentration of hydrogen peroxide. Previously known and some novel proteins with oxidant-sensitive cysteines were identified. Of the many protein thiols labeled by the ICAT, only relatively few were oxidized more than 50% despite the high concentration of oxidant used, indicating that oxidant-sensitive thiols are relatively rare, and denoting their specificity and potential functional relevance.

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Isotope-coded Affinity Tag Approach to Identify and Quantify Oxidant-sensitive Protein Thiols

Mahadevan

McComb

Heibeck

et al. 2004

Molecular & Cellular Proteomics

116

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An approach is described for identifying and quantifying oxidant-sensitive protein thiols using a cysteine-specific, acid-cleavable isotope-coded affinity tag (ICAT) reagent (Applied Biosystems, Foster City, CA). The approach is based on the fact that only free cysteine thiols are susceptible to labeling by the iodoacetamide-based ICAT reagent, and that mass spectrometry can be used to quantitate the relative labeling of free thiols. To validate our approach, creatine kinase with four cysteine residues, one of which is oxidant-sensitive, was chosen as an experimental model. ICAT-labeled peptides derived from creatine kinase were used to evaluate the relative abundance of the free thiols in samples subjected (or not) to treatment with hydrogen peroxide. As predicted, hydrogen peroxide decreased the relative abundance of the unmodified oxidant-sensitive thiol residue of cysteine-283 in creatine kinase, providing proof of principle that an ICAT-based quantitative mass spectrometry approach can be used to identify and quantify oxidation of cysteine thiols. This approach opens an avenue for proteomics studies of the redox state of protein thiols. Regulation of cellular homeostasis through post-translational modification of proteins is one of the major responses to oxidative and nitrosative stress (1). Proteins containing cysteine thiol groups are particularly susceptible to oxidation by free radicals, electrophilic molecules, and nitric oxide donors (2, 3). One or more reduced thiol groups are essential for the function of many proteins. Oxidation of these critical thiol groups can increase or decrease the activity of these proteins and represents not only a major mechanism of normal cell signaling via S-nitrosation (4) or S-glutathiolation (5), but also a mechanism by which disease and aging interferes with protein function by irreversible thiol oxidation (6). Thus, it is essential to identify the proteins containing Cys residues and their relative sensitivity to oxidation. As a step in the development of a proteomic approach to identify post-translational modification of Cys residues in proteins involved in redox signaling or those affected by disease, this report describes a method to identify and quantify oxidant-sensitive protein thiols by mass spectrometric peptide fingerprinting.The procedure is based on the fact that oxidized Cys residues are not susceptible to modification by iodoacetamide (IAM) 1 analogues (7). Isotope-coded affinity tag (ICAT) reagents that are IAM analogues have been used extensively in quantitative proteomics to evaluate the abundance of expressed proteins (8). The ICAT approach is based on affinity tag targeting of free cysteines in proteins that are labeled after the proteins are isolated under strong reducing conditions. This study was designed to determine the feasibility of using the acid-cleavable IAM-based ICAT reagent (catalogue no. 4337335; Applied Biosystems, Foster City, CA) to quantitate the extent of thiol oxidation under nonreducing conditions. The principle of the ICAT app...

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Application of Pressurized Solvents for Ultrafast Trypsin Hydrolysis in Proteomics: Proteomics on the Fly

et al. 2008

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A new method for rapid proteolytic digestion of proteins under high pressure that uses pressure cycling technology in the range of 5 to 35 kpsi was demonstrated for proteomic analysis. Successful in-solution digestions of single proteins and complex protein mixtures were achieved in 60 s and then analyzed by reversed phase liquid chromatography-electrospray ionization ion trap-mass spectrometry. Method performance in terms of the number of Shewanella oneidensis peptides and proteins identified in a shotgun approach was evaluated relative to a traditional "overnight" sample preparation method. Advantages of the new method include greatly simplified sample processing, easy implementation, no cross contamination among samples, and cost effectiveness.

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Tyler H. Heibeck

Production of Site-Specific Antibody–Drug Conjugates Using Optimized Non-Natural Amino Acids in a Cell-Free Expression System

S-Glutathiolation of Ras Mediates Redox-sensitive Signaling by Angiotensin II in Vascular Smooth Muscle Cells

Isotope-Coded Affinity Tag (ICAT) Approach to Redox Proteomics: Identification and Quantitation of Oxidant-Sensitive Cysteine Thiols in Complex Protein Mixtures

Isotope-coded Affinity Tag Approach to Identify and Quantify Oxidant-sensitive Protein Thiols

Application of Pressurized Solvents for Ultrafast Trypsin Hydrolysis in Proteomics: Proteomics on the Fly

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