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Studies on a Novel System for Cell-free Protein Synthesis Based on the Hyperthermophilic Archaeon, Thermococcus kodakaraensis / 超好熱始原菌Thermococcus kodakaraensis を用いた無細胞タンパク合成系に関する研究 / チョウ コウネツ シゲンキン Thermococcus kodakaraensis オ モチイタ ムサイボウ タンパク ゴウセイケイ ニ カンスル ケンキュウEndoh, Takashi 24 March 2008 (has links)
Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第13792号 / 工博第2896号 / 新制||工||1427(附属図書館) / 26008 / UT51-2008-C708 / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 今中 忠行, 教授 青山 安宏, 教授 濵地 格 / 学位規則第4条第1項該当
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NMR Metabolomics for Optimizing Cell-Free Protein SynthesisCampo, Angela M. 09 June 2021 (has links)
No description available.
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Strategies to detoxify the mycotoxin deoxynivalenol and improve food safety in the U.S.Wilson, Nina Marie 06 June 2017 (has links)
Mycotoxins are toxic secondary metabolites produced by fungi that are a threat to the health of humans and domestic animals. The most important mycotoxin in the U.S. is deoxynivalenol (DON), which causes symptoms such as vomiting, feed refusal, and weight loss in farm animals. The fungus Fusarium graminearum produces DON in staple crops such as wheat, barley, and corn. It is estimated that the economic losses associated with DON contamination alone exceed $650 million per year in the U.S. New strategies are needed to mitigate DON and improve food safety in the U.S. The overall goal of my research is to discover and employ microorganisms and enzymes to detoxify DON. The specific objectives are to: (1) discover and characterize microorganisms that detoxify DON, (2) use a cell free protein synthesis (CFPS) system to study enzymes that modify DON, (3) engineer yeast to detoxify DON with a metabolic engineering strategy, and (4) deliver a high school unit to teach high school students about mycotoxins in food. In Objective 1, two mixed cultures were identified from environmental samples that converted DON into the less toxic 3-keto-deoxynivalenol (3-keto-DON). In Objective 2, a CFPS system was used to express three known acetyltransferase genes to convert DON to 3-acetyl-DON (3-A-DON). In Objective 3, we identified a potential DON transporter from a library of randomly amplified fragments from the genomes of mixed cultures of microbes isolated from the environment. In Objective 4, we developed and delivered a unique high school unit to educate high school students about potential mycotoxins in food and feed products. The work presented here represents new and improved methods for mitigating mycotoxin contamination in the United States. / Ph. D. / Some fungi produce dangerous toxins called mycotoxins that contaminate food and feed and cause adverse affects when consumed. The mycotoxin deoxynivalenol (DON) contaminates staple crops such as wheat, barley, and corn and when consumed by domesticated animals it can cause weight loss, feed refusal, vomiting, and even death. The goal of this research is to detoxify DON using miroorganisms such as bacteria or fungi as well as enzymes. The specific objectives are to: (1) discover and characterize microorganisms that detoxify DON, (2) utilize a cell free protein synthesis (CFPS) system to detoxify DON using known acetyltransferase genes, (3) engineer yeast to detoxify DON with a metabolic engineering strategy, and (4) deliver a high school unit to teach high school students about mycotoxins in food and strategies to mitigate them. For objective one, microorganisms were collected from plant and soil samples and incubated in solution containing 100 ppm DON. Two mixed cultures were discovered to convert DON to another metabolite, 3-keto-DON that is considered less toxic. In objective two, a cell free protein synthesis (CFPS) system was used to establish its functionality as a tool to screen for enzymes that will detoxify DON. Known acetyltransferase genes were expressed in the CFPS and DON was converted to the metabolite 3-acetyl-DON. The mixed cultures discovered in objective one were then utilized in objective three to determine what enzymes were responsible for the conversion of DON to 3-keto-DON. Objective four was established to shed light about the dangers of mycotoxins and how growers and scientists test for mycotoxins in food and feed.
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Protein evolution in the presence of an unnatural amino acidSingh, Amrita, active 2012 04 March 2014 (has links)
The field of protein engineering has been greatly augmented by the expansion of the genetic code using unnatural amino acids as well as the development of cell-free synthesis systems with high protein yield. Cell-free synthesis systems have improved considerably since they were first described almost 40 years ago. Residue specific incorporation of non-canonical amino acids into proteins is usually performed in vivo using amino acid auxotrophic strains and replacing the natural amino acid with an unnatural amino acid analog. Herein, we present an amino acid depleted cell-free protein synthesis system that can be used to study residue specific replacement of a natural amino acid by an unnatural amino acid analog. This system combines high protein expression yields with a high level of analog substitution in the target protein. To demonstrate the productivity and efficacy of a cell-free synthesis system for residue-specific incorporation of unnatural amino acids in vitro, we use this system to show that 5-fluorotryptophan and 6-fluorotryptophan substituted streptavidin retain the ability to bind biotin despite protein wide replacement of a natural amino acid for the amino acid analog. We envisage this amino acid-depleted cell-free synthesis system being an economical and convenient format for the high-throughput screening of a myriad of amino acid analogs with a variety of protein targets for the study and functional characterization of proteins substituted with unnatural amino acids when compared to the currently employed in vivo format. We use this amino acid depleted cell-free synthesis system for the directed evolution of streptavidin, a protein that finds wide application in molecular biology and biotechnology. We evolve streptavidin using in vitro compartmentalization in emulsions to bind to desthiobiotin and find, at the conclusion of our experiment, that our evolved streptavidin variants are capable of binding to both biotin and desthiobiotin equally well. We also discover a set of mutations for streptavidin that are potentially powerful stabilizing mutations that we believe will be of great use to the greater research community. / text
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Identification and Characterization of Functional Biomolecules by In Vitro SelectionJanuary 2015 (has links)
abstract: In vitro selection technologies allow for the identification of novel biomolecules endowed with desired functions. Successful selection methodologies share the same fundamental requirements. First, they must establish a strong link between the enzymatic function being selected (phenotype) and the genetic information responsible for the function (genotype). Second, they must enable partitioning of active from inactive variants, often capturing only a small number of positive hits from a large population of variants. These principles have been applied to the selection of natural, modified, and even unnatural nucleic acids, peptides, and proteins. The ability to select for and characterize new functional molecules has significant implications for all aspects of research spanning the basic understanding of biomolecules to the development of new therapeutics. Presented here are four projects that highlight the ability to select for and characterize functional biomolecules through in vitro selection.
Chapter one outlines the development of a new characterization tool for in vitro selected binding peptides. The approach enables rapid screening of peptide candidates in small sample volumes using cell-free translated peptides. This strategy has the potential to accelerate the pace of peptide characterization and help advance the development of peptide-based affinity reagents.
Chapter two details an in vitro selection strategy for searching entire genomes for RNA sequences that enhance cap-independent initiation of translation. A pool of sequences derived from the human genome was enriched for members that function to enhance the translation of a downstream coding region. Thousands of translation enhancing elements from the human genome are identified and the function of a subset is validated in vitro and in cells.
Chapter three discusses the characterization of a translation enhancing element that promotes rapid and high transgene expression in mammalian cells. Using this ribonucleic acid sequence, a series of full length human proteins is expressed in a matter of only hours. This advance provides a versatile platform for protein synthesis and is espcially useful in situations where prokaryotic and cell-free systems fail to produce protein or when post-translationally modified protein is essential for biological analysis.
Chapter four outlines a new selection strategy for the identification of novel polymerases using emulsion droplet microfluidics technology. With the aid of a fluorescence-based activity assay, libraries of polymerase variants are assayed in picoliter sized droplets to select for variants with improved function. Using this strategy a variant of the 9°N DNA polymerase is identified that displays an enhanced ability to synthesize threose nucleic acid polymers. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2015
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Development of a high throughput cell-free metagenomic screening platformNevondo, Walter January 2016 (has links)
Philosophiae Doctor - PhD / The estimated 5 × 10³⁰ prokaryotic cells inhabiting our planet sequester some 350–550 Petagrams (1 Pg = 1015 g) of carbon, 85–130 Pg of nitrogen, and 9–14 Pg of phosphorous, making them the largest reservoir of those nutrients on Earth (Whitman et al. 1998). However, reports suggest that only less than 1% of these microscopic organisms are cultivable (Torsvik et al. 1990; Sleator et al. 2008). Until recently with the development of metagenomic techniques, the knowledge of microbial diversity and their metabolic capabilities has been limited to this small fraction of cultivable organisms (Handelsman et al. 1998). While metagenomics has
undoubtedly revolutionised the field of microbiology and biotechnology it has been generally acknowledged that the current approaches for metagenomic bio- rospecting / screening have limitations which hinder this approach to fully access the metabolic potentials and genetic variations contained in microbial genomes (Beloqui et al. 2008). In particular, the construction of metagenomic libraries and heterologous expression are amongst the major obstacles. The aim of this study was to develop an ultra-high throughput approach for screening enzyme activities using uncloned metagenomic DNA, thereby eliminating cloning steps, and employing
in vitro heterologous expression. To achieve this, three widely used techniques: cell-free transcription-translation, in vitro compartmentalisation (IVC) and Fluorescence Activated Cell Sorting (FACS) were combined to develop this robust technique called metagenomic in vitro compartmentalisation (mIVC-FACS). Moreover, the E. coli commercial cell-free system was used in parallel to a novel, in-house Rhodococcus erythropolis based cell-free system. The versatility of this technique was tested by identifying novel beta-xylosidase encoding genes derived from a thermophilic compost metagenome. In addition, the efficiency of mIVC-FACS was compared to the traditional metagenomic approaches; function-based (clone library screening) and sequence-based (shotgun sequencing and PCR screening). The results obtained here show that the R. erythropolis cell-free system was over thirty-fold more effective than the E. coli based system based on the number of hits obtained per million double emulsions (dE) droplets screened. Six beta-xylosidase encoding genes were isolated and confirmed from twenty-eight positive dE droplets. Most of the droplets that were isolated from the same gate encoded the same enzyme, indicating that this technique is highly selective. A comparison of the hit rate of this screening approach with the traditional E. coli based fosmid library method shows that mIVC-FACS is at least 2.5 times more sensitive. Although only a few hits from the mIVC-FACS screening were selected for confirmation of beta-xylosidase activity, the proposed hit rate suggests that a significant number of positive hits are left un-accessed through the traditional clone library screening system. In addition, these results also suggest that E. coli expression system might be intrinsically sub-optimal for screening for hemicellulases from environmental genomes compared to R. erythropolis system. The workflow required for screening one million clones in a fosmid library was estimated to be about 320 hours compared to 144 hours required via the mIVC-FACS screening platform. Some of the gene products obtained in both screening platforms show multiple substrate activities, suggesting that the microbial consortia of composting material consist of microorganisms that produce enzymes with multiple lignocellulytic activities. While this platform still requires optimisation, we have demonstrated that this technique can be used to isolate genes encoding enzymes from mixed microbial genomes. mIVC-FACS is a promising technology with the potential to take metagenomic studies to the second generation of novel natural products bio-prospecting. The astonishing sensitivity and ultra-high throughput capacity of this technology offer numerous advantages in metagenomic bio-prospecting. / National Research Foundation (NRF)
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The Democratization and Development of Cell-Free Protein SynthesisLevine, Max Z 01 November 2019 (has links) (PDF)
Cell-free protein synthesis (CFPS) using crude lysates has developed into a robust platform technology over the last 60 years to express numerous types of recombinant proteins. The open-nature, elimination of reliance on cell viability, and focus of all energy towards production of the protein of interest represent substantial advantages of CFPS over in vivo protein expression methods. CFPS has provided new opportunities across a series of research fields that include metabolic engineering, therapeutic and vaccine development, education, biosensors, and many more. In recent years, optimizations of CFPS have even allowed the platform to reach the industrial level of protein production. Although there have been many advancements toward CFPS development, the democratization of the platform to a wide variety of educational, research, and industrial institutions has lacked due to an absence of resources for new users as well as a limited number of developments toward redesigning the tedious and time-consuming protocols to generate robust cell extract. To address these challenges to CFPS implementation, a comprehensive review spanning numerous cell lines with their respective applications, methodologies, and reaction formats were provided in addition to detailed protocols outlining the process of going from E. coli cells to a completed CFPS reaction. Together, these resources provide the scientific community with easily accessible resources for CFPS implementation. Moreover, the aforementioned protocols were redesigned from a four-day process into one that may be completed in under 24-hour’s time with very little researcher oversight. The resulting workflow maintained the robustness of prior methods but generated 400% more extract compared to traditional methods via a set-it-and-forget-it approach. To date, the works presented herein have garnered tremendous viewership from the CFPS research community with a substantial following among all three of the articles. Moving forward, I anticipate that these works will continue to bring new users into the CFPS field through the ease of access to these resources and through the advance of the simplistic and reproducible new workflow for preparation of robust E. coli cell extract.
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Insight into the mitochondrial apoptotic pathway : The interplay of the pro-apoptotic Bax protein with oxidized phospholipids and its counterplayer, the pro-survival Bcl-2 proteinWallgren, Marcus January 2012 (has links)
Apoptosis plays a crucial role in multicellular organisms by preserving tissue homeostasis and removing harmful cells. The anti-apoptotic B-cell CLL/lymphoma 2 (Bcl-2) and the pro-apoptotic Bcl-2-associated X protein (Bax) act as major regulators of the mitochondrial apoptotic pathway. Activation of Bax via stress signals causes its translocation to the mitochondrial outer membrane (MOM). There, Bax forms homo-oligomeric pores, leading to the release of apoptogenic factors, caspase activation and ultimately cell death. However, the underlying mechanism for the recruitment and pore forming activity of Bax is still not elucidated. Nevertheless, the mitochondrial membrane system seems to play an active and crucial role, presumably being directly involved in the onset of the mitochondrial apoptosis. Since the formation of reactive oxygen species (ROS) is a common stress signal and one of the hallmarks of the mitochondrial apoptosis, direct damage can occur to these membranes by the generation of oxidized phospholipids (OxPls), whose presence can crucially influence the pro-apoptotic action of Bax there. To better understand the impact of OxPls on membranes as well as their potential role in the mitochondrial apoptotic process, defined OxPl species were incorporated into phospholipid vesicles and studied with various biophysical techniques. Differential scanning calorimetry (DSC) and solid state nuclear magnetic resonance (NMR) spectroscopy were used to gain insight into changes in membrane properties in the presence of OxPls. In addition to circular dichroism (CD) spectroscopy, DSC and solid state NMR were furthermore performed to elucidate the impact of OxPls on Bax-membrane interactions. The occurrence of OxPls gave rise to dramatic changes in membrane organization and dynamics, manifested as lateral phase separation into OxPl-rich and -poor domains and modified hydration at the membrane interface. The presence of OxPls also had a great impact on the interaction between Bax and mitochondria-mimicking vesicles, strongly promoting the association of the protein with the membrane. At the MOM, Bax is believed to be inhibited by Bcl-2. How this inhibition occurs is still a mystery due to the lack of biophysical information on Bcl-2, in particular on the full-length protein variant. Since Bcl-2 is also one of the main culprits in the progression of various forms of cancer, knowledge of the structural and mechanistic properties of the full-length protein is essential for a fundamental understanding of its function at a molecular level. To this end, a method for the production of full-length Bcl-2 was developed. By performing cell-free protein synthesis, preparative amounts of the protein were obtained, which enabled a biophysical characterization of the putative interaction between Bax and Bcl-2 using CD and fluorescence spectroscopy. A protocol for the reconstitution of Bcl-2 into proteoliposomes was also developed, promising for future studies of the full-length protein in its native membrane environment; a prerequisite to fully understand its pro-survival functions as well as providing crucial information for the design of novel anti-cancer drugs.
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Engineering Cell-Free Biosystems for On-Site Production and Rapid Design of Next-Generation TherapeuticsWilding, Kristen Michelle 01 December 2018 (has links)
While protein therapeutics are indispensable in the treatment of a variety of diseases, including cancer, rheumatoid arthritis, and diabetes, key limitations including short half-lives, high immunogenicity, protein instability, and centralized production complicate long-term use and on-demand production. Site-specific polymer conjugation provides a method for mitigating these challenges while minimizing negative impacts on protein activity. However, the location-dependent effects of polymer conjugation are not well understood. Cell-free protein synthesis provides direct access to the synthesis environment and rapid synthesis times, enabling rapid evaluation of multiple conjugation sites on a target protein. Here, work is presented towards developing cell-free protein synthesis as a platform for both design and on-demand production of next generation polymer-protein therapeutics, including (1) eliminating endotoxin contamination in cell-free reagents for simplified therapeutic preparation, (2) improving shelf-stability of cell-free reagents via lyophilization for on-demand production, (3) coupling coarse-grain simulation with high-throughput cell-free protein synthesis to enable rapid identification of optimal polymer conjugation sites, and (4) optimizing cell-free protein synthesis for production of therapeutic proteins
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Engineering Cell-Free Systems for Vaccine Development, Self-Assembling Nanoparticles and Codon Reassignment ApplicationsSmith, Mark T 01 April 2014 (has links) (PDF)
This dissertation reports on the technology of cell-free protein synthesis (CFPS) including 1) stabilized lyophilized cell-free systems and 2) enhanced heterogeneous cell extracts. This work further considers applications of CFPS systems in 1) rapid vaccine development, 2) functional virus-based nanoparticles, 3) site-specific protein immobilization, and 4) expanding the language of biology using unnatural amino acids. CFPS technology is a versatile protein production platform that has many features unavailable in in vivo expression systems. The primary benefit cell-free systems provide is the direct access to the reaction environment, which is no longer hindered by the presence of a cell-wall. The “openness" of the system makes it a compelling candidate for many technologies. One limitation of CFPS is the necessity of freezing for long-term viable storage. We demonstrate that a lyophilized CFPS system is more stable against nonideal storage than traditional CFPS reagents. The Escherichia coli-based CFPS system in this work is limited by the biocatalytic machinery found natively in E. coli. To combat these limitations, exogenous biocatalysts can be expressed during fermentation of cells prepared into extract. We demonstrate that simple adjustments in the fermentation conditions can significantly increase the activity of the heterogeneous extract. Towards virus-based particles and vaccines, we demonstrate that the open nature of CFPS can be utilized for coexpression of virus proteins and self-assembly of virus particles. This technique allows for the rapid production of potential vaccines and novel functional virus-based nanoparticles. Unnatural amino acids expand the effective language of protein biology. Utilizing CFPS as an expression system, we demonstrated that the incorporation of a single specific unnatural amino acid allows for site-specific immobilization, thus stabilizing the protein against elevated temperatures and chemical denaturants. Current unnatural amino acid incorporation technologies are limited to one or few simultaneous incorporations and suffer from low efficiency. This work proposes a system that could potentially allow for upwards of 40 unnatural amino acids to be simultaneously incorporated, effectively tripling the protein code. These projects demonstrate the power and versatility of CFPS technologies while laying the foundation for promising technologies in the field of biotechnology.
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