Kristen M. Wilding scite author profile

Although polyethylene glycol (PEG) is commonly used to improve protein stability and therapeutic efficacy, the optimal location for attaching PEG onto proteins is not well understood. Here, we present a cell-free protein synthesis-based screening platform that facilitates site-specific PEGylation and efficient evaluation of PEG attachment efficiency, thermal stability, and activity for different variants of PEGylated T4 lysozyme, including a di-PEGylated variant. We also report developing a computationally efficient coarse-grain simulation model as a potential tool to narrow experimental screening candidates. We use this simulation method as a novel tool to evaluate the locational impact of PEGylation. Using this screen, we also evaluated the predictive impact of PEGylation site solvent accessibility, conjugation site structure, PEG size, and double PEGylation. Our findings indicate that PEGylation efficiency, protein stability, and protein activity varied considerably with PEGylation site, variations that were not well predicted by common PEGylation guidelines. Overall our results suggest current guidelines are insufficiently predictive, highlighting the need for experimental and simulation screening systems such as the one presented here.

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Thermostable lyoprotectant-enhanced cell-free protein synthesis for on-demand endotoxin-free therapeutic production

Wilding

Zhao

Earl

et al. 2019

New Biotechnology

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The emerging age of cell‐free synthetic biology

et al. 2014

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a b s t r a c tThe engineering of and mastery over biological parts has catalyzed the emergence of synthetic biology. This field has grown exponentially in the past decade. As increasingly more applications of synthetic biology are pursued, more challenges are encountered, such as delivering genetic material into cells and optimizing genetic circuits in vivo. An in vitro or cell-free approach to synthetic biology simplifies and avoids many of the pitfalls of in vivo synthetic biology. In this review, we describe some of the innate features that make cell-free systems compelling platforms for synthetic biology and discuss emerging improvements of cell-free technologies. We also select and highlight recent and emerging applications of cell-free synthetic biology.

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Endotoxin-Free E. coli- Based Cell-Free Protein Synthesis: Pre-Expression Endotoxin Removal Approaches for on-Demand Cancer Therapeutic Production

et al. 2018

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Approximately one third of protein therapeutics are produced in Escherichia coli, targeting a wide variety of diseases. However, due to immune recognition of endotoxin (a lipid component in the E. coli cell membrane), these protein products must be extensively purified before application to avoid adverse reactions such as septic shock. E. coli-based cell-free protein synthesis (CFPS), which has emerged as a promising platform for the development and production of enhanced protein therapeutics, provides a unique opportunity to remove endotoxins prior to protein expression due to its open environment and the absence of live cells. Pre-expression endotoxin removal from CFPS reagents could simplify downstream processing, potentially enabling on-demand production of unique protein therapeutics. Herein, three strategies for removing endotoxins from E. coli cell lysate are evaluated: Triton X-114 two-phase extraction, polylysine affinity chromatography, and extract preparation from genetically engineered, endotoxin-free ClearColi cells. It is demonstrated that current protocols for endotoxin removal treatments insufficiently reduce endotoxin and significantly reduce protein synthesis yields. Further, the first adaptation of ClearColi cells to prepare cell-free extract with high protein synthesis capability is demonstrated. Finally, production of the acute lymphoblastic leukemia therapeutic crisantaspase from reduced-endotoxin extract and endotoxin-free ClearColi extract is demonstrated.

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Non-canonical amino acid labeling in proteomics and biotechnology

et al. 2019

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Metabolic labeling of proteins with non-canonical amino acids (ncAAs) provides unique bioorthogonal chemical groups during de novo synthesis by taking advantage of both endogenous and heterologous protein synthesis machineries. Labeled proteins can then be selectively conjugated to fluorophores, affinity reagents, peptides, polymers, nanoparticles or surfaces for a wide variety of downstream applications in proteomics and biotechnology. In this review, we focus on techniques in which proteins are residue- and site-specifically labeled with ncAAs containing bioorthogonal handles. These ncAA-labeled proteins are: readily enriched from cells and tissues for identification via mass spectrometry-based proteomic analysis; selectively purified for downstream biotechnology applications; or labeled with fluorophores for in situ analysis. To facilitate the wider use of these techniques, we provide decision trees to help guide the design of future experiments. It is expected that the use of ncAA labeling will continue to expand into new application areas where spatial and temporal analysis of proteome dynamics and engineering new chemistries and new function into proteins are desired.

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