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Browsing by Author "Turner, Kendrick B."
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Item Affinity purification of bacterial outer membrane vesicles (OMVs) utilizing a His-tag mutant(Elsevier, 2017-02) Alves, Nathan J.; Turner, Kendrick B.; DiVito, Kyle A.; Daniele, Michael A.; Walper, Scott A.; Department of Emergency Medicine, School of MedicineTo facilitate the rapid purification of bacterial outer membrane vesicles (OMVs), we developed two plasmid constructs that utilize a truncated, transmembrane protein to present an exterior histidine repeat sequence. We chose OmpA, a highly abundant porin protein, as the protein scaffold and utilized the lac promoter to allow for inducible control of the epitope-presenting construct. OMVs containing mutant OmpA-His6 were purified directly from Escherichia coli culture media on an immobilized metal affinity chromatography (IMAC) Ni-NTA resin. This enabling technology can be combined with other molecular tools directed at OMV packaging to facilitate the separation of modified/cargo-loaded OMV from their wt counterparts. In addition to numerous applications in the pharmaceutical and environmental remediation industries, this technology can be utilized to enhance basic research capabilities in the area of elucidating endogenous OMV function.Item Directed Protein Packaging within Outer Membrane Vesicles from Escherichia coli: Design, Production and Purification(2016) Alves, Nathan J.; Turner, Kendrick B.; Walper, Scott A.; Department of Emergency Medicine, School of MedicineA protocol for the production, purification, and use of enzyme packaged outer membrane vesicles (OMV) providing for enhanced enzyme stability for implementation across diverse applications is presented.Item Emerging Therapeutic Delivery Capabilities and Challenges Utilizing Enzyme/Protein Packaged Bacterial Vesicles(Future Science, 2015-07) Alves, Nathan J.; Turner, Kendrick B.; Medintz, Igor L.; Walker, Scott A.; Emergency Medicine, School of MedicineNanoparticle-based therapeutics are poised to play a critical role in treating disease. These complex multifunctional drug delivery vehicles provide for the passive and active targeted delivery of numerous small molecule, peptide and protein-derived pharmaceuticals. This article will first discuss some of the current state of the art nanoparticle classes (dendrimers, lipid-based, polymeric and inorganic), highlighting benefits/drawbacks associated with their implementation. We will then discuss an emerging class of nanoparticle therapeutics, bacterial outer membrane vesicles, that can provide many of the nanoparticle benefits while simplifying assembly. Through molecular biology techniques; outer membrane vesicle hijacking potentially allows for stringent control over nanoparticle production allowing for targeted protein packaged nanoparticles to be fully synthesized by bacteria.Item Environmental Decontamination of a Chemical Warfare Simulant Utilizing a Membrane Vesicle-Encapsulated Phosphotriesterase(ACS, 2018) Alves, Nathan J.; Moore, Martin; Johnson, Brandy J.; Dean, Scott N.; Turner, Kendrick B.; Medintz, Igor L.; Walper, Scott A.; Emergency Medicine, School of MedicineWhile technologies for the remediation of chemical contaminants continue to emerge, growing interest in green technologies has led researchers to explore natural catalytic mechanisms derived from microbial species. One such method, enzymatic degradation, offers an alternative to harsh chemical catalysts and resins. Recombinant enzymes, however, are often too labile or show limited activity when challenged with nonideal environmental conditions that may vary in salinity, pH, or other physical properties. Here, we demonstrate how phosphotriesterase encapsulated in a bacterial outer membrane vesicle can be used to degrade the organophosphate chemical warfare agent (CWA) simulant paraoxon in environmental water samples. We also carried out remediation assays on solid surfaces, including glass, painted metal, and fabric, that were selected as representative materials, which could potentially be contaminated with a CWA.Item Protecting enzymatic function through directed packaging into bacterial outer membrane vesicles(Nature, 2016-04) Alves, Nathan J.; Turner, Kendrick B.; Medintz, Igor L.; Walper, Scott A.; Emergency Medicine, School of MedicineBacteria possess innate machinery to transport extracellular cargo between cells as well as package virulence factors to infect host cells by secreting outer membrane vesicles (OMVs) that contain small molecules, proteins, and genetic material. These robust proteoliposomes have evolved naturally to be resistant to degradation and provide a supportive environment to extend the activity of encapsulated cargo. In this study, we sought to exploit bacterial OMV formation to package and maintain the activity of an enzyme, phosphotriesterase (PTE), under challenging storage conditions encountered for real world applications. Here we show that OMV packaged PTE maintains activity over free PTE when subjected to elevated temperatures (>100-fold more activity after 14 days at 37 °C), iterative freeze-thaw cycles (3.4-fold post four-cycles), and lyophilization (43-fold). We also demonstrate how lyophilized OMV packaged PTE can be utilized as a cell free reagent for long term environmental remediation of pesticide/chemical warfare contaminated areas.