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Protein Design and Engineering Using the Fluorescent Non-canonical Amino Acid L-(7-hydroxycoumarin-4-yl)ethylglycineJanuary 2020 (has links)
abstract: Proteins are, arguably, the most complicated molecular machines found in nature. From the receptor proteins that decorate the exterior of cell membranes to enzymes that catalyze the slowest of chemical reactions, proteins perform a wide variety of essential biological functions. A reductionist view of proteins as a macromolecular group, however, may hold that they simply interact with other chemical species. Notably, proteins interact with other proteins, other biological macromolecules, small molecules, and ions. This in turn makes proteins uniquely qualified for use technological use as sensors of said chemical species (biosensors). Several methods have been developed to convert proteins into biosensors. Many of these techniques take advantage of fluorescence spectroscopy because it is a fast, non-invasive, non-destructive and highly sensitive method that also allows for spatiotemporal control. This, however, requires that first a fluorophore be added to a target protein. Several methods for achieving this have been developed from large, genetically encoded autofluorescent protein tags, to labeling with small molecule fluorophores using bioorthogonal chemical handles, to genetically encoded fluorescent non-canonical amino acids (fNCAA). In recent years, the fNCAA, L-(7-hydroxycoumarin-4yl)ethylglycine (7-HCAA) has been used in to develop several types of biosensors.
The dissertation I present here specifically addresses the use of the fNCAA L-(7-hydroxycoumarin-4-yl)ethylglycine (7-HCAA) in protein-based biosensors. I demonstrate 7-HCAA’s ability to act as a Förster resonance energy transfer (FRET) acceptor with tryptophan as the FRET donor in a single protein containing multiple tryptophans. I the describe efforts to elucidate—through both spectroscopic and structural characterization—interactions within a 7-HCAA containing protein that governs 7-HCAA fluorescence. Finally, I present a top-down computational design strategy for incorporating 7-HCAA into proteins that takes advantage of previously described interactions. These reports show the applicability of 7-HCAA and the wider class of fNCAAs as a whole for their use of rationally designed biosensors. / Dissertation/Thesis / Doctoral Dissertation Biochemistry 2020
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Functionalizing Branched Peptides with Unnatural Amino Acids Toward Targeting HIV-1 RRE RNA and MicrobialsWynn, Jessica Elaine 29 August 2016 (has links)
The interaction of the protein Rev with Rev Response Element (RRE) RNA is critical to the HIV-1 life cycle as this complex is required for the export of singly-spliced and unspliced mRNAs from the nucleus to the cytoplasm. Disruption of this interaction is considered to be a powerful strategy towards the development of HIV-1 therapeutics. Therefore, we have developed several branched peptide libraries containing unnatural amino acids to target the high-affinity binding site of RRE RNA (RRE IIB), with the idea that branching in peptides can provide multivalent contacts with folded RNA structures and boost binding affinity and selectivity for the target. Unnatural amino acids were incorporated into the library design to encourage non-canonical interactions with the RNA and to improve proteolytic stability.
The on-bead high-throughput screening of our first branched peptide library (46,656 sequences) against HIV-1 RRE RNA generated hit peptides with binding affinities in the low micromolar range. We demonstrated that branching in the peptide is required for efficient binding and selectivity towards the RNA, and that the peptides bind a large surface area of RRE IIB. Introduction of boronic acids into branched peptides boosted selectivity of the peptides for RRE IIB, and proved to be a novel and tunable mode of binding towards RNA. Additionally, we revealed that these branched peptide boronic acids (BPBAs) were cell permeable and non-toxic. One BPBA (BPBA3) bound RRE IIB selectively and was able to inhibit HIV-1 replication in vitro, revealing enzymatic cleavage of the RNA upon binding.
A second generation BPBA library that introduced acridinyl lysine as an intercalator (4,096 sequences) was screened against RRE IIB. Several hit compounds bound in the low nanomolar regime, and a significant number of compounds inhibited HIV-1 replication in vitro. These BPBAs were also found to severely inhibit the microbial growth of bacteria and fungus, with MICs as low as 1 µg/mL against Staphylococcus aureus, Candida albicans, and Escherichia coli. These compounds were also found to significantly inhibit biofilm formation and growth, and were non-hemolytic.
High-throughput screening of a third generation BPBA library containing all unnatural amino acids (46,656 sequences) revealed several hits that bound RRE IIB RNA in the nanomolar range. Sequence motifs present in the hit peptides suggested that the location and composition of amino acids within the branched peptide structure were important for recognizing the RNA target. In particular, lead compounds 2C5 and 4B3 demonstrated selectivity towards RRE, and footprinting experiments combined with SHAPE experiments revealed different interactions of the peptides with the RNA Toxicity assays revealed no impact on cell viability for the majority of hit sequences tested up to 100 µM, and several compounds also demonstrated inhibition of HIV-1 replication. / Ph. D.
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Synthesis of unnatural amino acids for genetic encoding by the pyrrolysyl-tRNA/RNA synthetase systemKnight, William A 01 January 2015 (has links)
The complexity of all biomolecules in existence today can be attributed to the variation of the amino acid repertoire. In nature, 20 canonical amino acids are translated to form these biomolecules, however, many of these amino acids have revealed posttranslational modifications (i.e. acetylation, methylation) after incorporation. Amino acids that exhibit PTM are known for their involvement in cellular processes such as DNA repair and DNA replication; these PTMs are commonly found on histones within the chromatin complex. Utilization of in vivo site-specific incorporation has recently reported functionality of post-translationally modified amino acids.1 xii Here we report the synthesis and in vivo site-specific incorporation of the histone PTM, 2-hydroxyisobutyrl lysine (Khib), with the pyrrolysyl tRNA/ RNA synthetase system. This translational machine can better serve to probe Khib for functional benefits. Additionally, this thesis focuses much of its attention on the development of unnatural amino acids (UAA) with optogenetic characteristics. These UAAs, if site-specifically incorporated, can be used to control enzymes and proteins through rapid light perturbation (365nm UV light). Furthermore, discussed is the synthesis of photo-caged threonine and photo-caged serine as potential substrates for the pyrrolysyl translational machinery.
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Evolutionary synthetic biology: structure/function relationships within the protein translation systemCacan, Ercan 06 September 2011 (has links)
Production of mutant biological molecules for understanding biological principles or as therapeutic agents has gained considerable interest recently. Synthetic genes are today being widely used for production of such molecules due to the substantial decrease in the costs associated with gene synthesis technology. Along one such line, we have engineered tRNA genes in order to dissect the effects of G:U base-pairs on the accuracy of the protein translation machinery. Our results provide greater detail into the thermodynamic interactions between tRNA molecules and an Elongation Factor protein (termed EF-Tu in bacteria and eEF1A in eukaryotes) and how these interactions influence the delivery of aminoacylated tRNAs to the ribosome. We anticipate that our studies not only shed light on the basic mechanisms of molecular machines but may also help us to develop therapeutic or novel proteins that contain unnatural amino acids. Further, the manipulation of the translation machinery holds promise for the development of new methods to understand the origins of life.
Along another line, we have used the power of synthetic biology to experimentally validate an evolutionary model. We exploited the functional diversity contained within the EF-Tu/eEF1A gene family to experimentally validate the model of evolution termed ‘heterotachy’. Heterotachy refers to a switch in a site’s mutational rate class. For instance, a site in a protein sequence may be invariant across all bacterial homologs while that same site may be highly variable across eukaryotic homologs. Such patterns imply that the selective constraints acting on this site differs between bacteria and eukaryotes. Despite intense efforts and large interest in understanding these patterns, no studies have experimentally validated these concepts until now. In the present study, we analyzed EF-Tu/eEF1A gene family members between bacteria and eukaryotes to identify heterotachous patterns (also called Type-I functional divergence). We applied statistical tests to identify sites possibly responsible for biomolecular functional divergence between EF-Tu and eEF1A. We then synthesized protein variants in the laboratory to validate our computational predictions. The results demonstrate for the first time that the identification of heterotachous sites can be specifically implicated in functional divergence among homologous proteins.
In total, this work supports an evolutionary synthetic biology paradigm that in one direction uses synthetic molecules to better understand the mechanisms and constraints governing biomolecular behavior while in another direction uses principles of molecular sequence evolution to generate novel biomolecules that have utility for industry and/or biomedicine.
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Structural investigation of the histone chaperone complex FACT using genetically encoded crosslinkers in Saccharomyces cerevisiaeHoffmann, Christian 01 December 2014 (has links)
No description available.
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A method for the genetically encoded incorporation of FRET pairs into proteinsLammers, Christoph 15 July 2014 (has links)
No description available.
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Development and Applications of Universal Genetic Code Expansion Platforms:Italia, James Sebastian January 2019 (has links)
Thesis advisor: Abhishek Chatterjee / The emergence of genetic code expansion (GCE) technology, which enables sitespecific incorporation of unnatural amino acids (UAAs) into proteins, has facilitated powerful new ways to probe and engineer protein structure and function. Using engineered orthogonal tRNA/aminoacyl-tRNA synthetase (aaRS) pairs that suppress repurposed nonsense codons, a variety of structurally diverse UAAs have been incorporated into proteins in living cells. This technology offers tremendous potential for deciphering the complex biology of eukaryotes, but its scope in eukaryotic systems remains restricted due to several technical limitations. For example, development of the engineered tRNA/aaRS pairs for eukaryotic GCE traditionally relied on a eukaryotic cell-based directed evolution system, which are significantly less efficient relative to bacteria-based engineering platforms. The work described in this thesis establishes a new paradigm in GCE through the development of a novel class of universal tRNA/aaRS pairs, which can be used for ncAA incorporation in both E. coli and eukaryotes. We achieve this by developing engineered strains of E. coli, where one of its endogenous tRNA/aaRS pair is functionally replaced with an evolutionarily distant counterpart. The liberated pair can then be used for GCE in the resulting altered translational machinery (ATM) strain, as well as any eukaryote. Using this strategy, we have been able to genetically encode new bioconjugation chemistries, post-translational modifications, and facilitate the incorporation of multiple, distinct ncAAs into a single protein. The ATM technology holds enormous promise for significantly expanding the scope of the GCE technology in both bacteria and eukaryotes. / Thesis (PhD) — Boston College, 2019. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
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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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RumpleMasterThesis_Final.pdfJoshua Keith Rumple (14286443) 21 December 2022 (has links)
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<p>The access of ring junction functionalized 5,6-hydrindanone systems has been elusive in the realm of synthetic methodology, and the functionalization of a pre-built ring system rarely explored. These 5,6-hydridanone systems are prevalent in a variety of terpenoid ring systems, especially that of steroidal molecules. Previous synthetic methods to reach these systems using a Diels-Alder cycloaddition proved to be difficult and lacked labile functional groups that would be useful for substitution after the cycloaddition. The design of the α-nitrile cyclopentenone dienophile allows for both post-cyclization adduct functionalization, as well as lowering the energy barrier of the cycloaddition itself. In this work, it is shown that the Lewis acid promoted Diels-Alder reaction with α-nitrile β-methyl cyclopentenone dienophile can be performed under standard temperatures and pressures unlike previously established methods.1 This reaction can generate four chiral centers in a single synthetic step when the starting materials are prochiral. After the generation of 5,6-hydrindanone systems, radical cleavage of the nitrile functionality also allowed for electrophile trapping at the ring junction. This radical cleavage and electrophile trapping pathway allows for functionalization of a quaternary carbon at the ring junction, a method that should be fruitful in the generation of difficult to synthesize steroidal and other terpenoid molecules.</p>
<p>In the work on synthetic cell penetrating peptides, camptothecin whilst a notably effective topoisomerase I inhibitor, has never quite reached it’s potential as a therapeutic due to its poor solubility in living systems. Previously, cationic amphiphilic polyproline helices (CAPH) molecules from the Chmielewski lab have been hydrophobically functionalized through O-alkylation of hydroxyprolines at specific regions within the peptide to generate a hydrophobic face. The combination of the cationic faces and the hydrophobic face have made the CAPH molecules notably cell penetrant and tunable. With camptothecin’s notable insolubility in water, it may serve as valuable surrogate to the hydrophobic groups on CAPH molecules and allowing it to be delivered intracellularly. Using an endogenously cleavable linker, we have worked towards a CPP that acts as a drug delivery vehicle. Acting as a replacement of the hydrophobic residue of a CAPH molecule, camptothecin will be chaperoned into the cell and should be released through the action of intracellular esterases.</p>
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Branched Peptides Targeting HIV-1 RRE RNA and Structure-Activity Relationship Studies of Spinster Homolog 2 InhibitorsPeralta, Ashley N. 08 June 2020 (has links)
Binding of the Rev protein with Rev Response Element (RRE) RNA present in singly- and unspliced mRNA transcripts is necessary for the replication of HIV-1. This interaction transports the mRNA transcripts from the nucleus to the cytoplasm for translation of the necessary structural and enzymatic proteins for the newly budding virus as well as for providing its genetic material. Given the high rate of mutation in HIV-1, the highly conserved and pertinent RRE RNA is of high interest for pharmaceutical intervention. Consequently, a branched peptide library containing unnatural amino acids was developed to target RRE RNA with the goal of increasing stability, potency, selectivity, and in vivo activity for RRE RNA.
An unnatural amino acid branched peptide library (46,656 sequences) was synthesized and screened against RRE IIB and several hits in the sub-micromolar regime were found. A number of hits demonstrated selectivity in the presence of other RNAs in addition to two hits, 4A5 and 4B3, significantly inhibiting HIV-1 growth in vitro. These peptides inhibited HIV-1 replication in a concentration dependent manner and were demonstrated to be non-toxic. Further analysis of 4A5 and 4B3 via footprinting and SHAPE-MaP experiments determined that these peptides blocked binding of Rev through binding at the primary and secondary binding sites of RRE RNA.
Sphingosine 1-phosphate (S1P) is a signaling molecule that plays a role in various biological processes including immunity, neurogenesis, and angiogenesis. The role S1P plays is largely determined by its location, in which Spinster homolog 2 (spns2) and mfsd2b are the two known transporters. The two transporters exist in different cell types and cellular localizations, with spns2-produced S1P being responsible for trafficking of lymphocytes. As such, spns2 has become of interest for therapeutic targeting in autoimmune and inflammatory diseases. To validate spns2 as a target in pharmaceutical intervention, a series of spns2 inhibitors were developed.
A screening of a library of inhibitors found that compound SLP7120922 demonstrated inhibition of spns2 transport activity. The design, synthesis, and biological evaluation of inhibitors based on SLP7120922 is described. Modifications to the lipophilic tail region were performed with one compound 4.40f discovered to be potent, minimally toxic, and active in vivo. A series of modifications to the head region were then conducted that evaluated linear head derivatives with alkyl-, amide-, and amino acid-based groups. A number of compounds are reported that demonstrate good in vitro activity and minimal toxicity with two compounds, 4.48b and 4.52c, showing favorable in vivo activity in mice. / Doctor of Philosophy / Human immunodeficiency virus (HIV-1) has a high rate of mutation, which commonly leads to the need for many types of medications throughout the lifetime of a patient. In order to design a therapeutic that the virus has a low chance of growing resistance to, a target needs to be chosen with a low mutation rate. One such target is the Rev Response Element (RRE) RNA and it is necessary for the virus to replicate. A protein named Rev binds to RRE RNA in order for RRE to carry out its pertinent function. To block this function we have chosen branched peptides to target the RNA. Peptides are made of the same building blocks of proteins, but are much shorter than proteins. The peptides described here are made up of modified building blocks, called unnatural amino acids. This work describes the generation of an unnatural amino acid branched peptide library and how it was screened in order to find branched peptides that bind RRE RNA. Many peptides were found to bind RRE RNA but two in particular, 4A5 and 4B3, were the best binders that inhibited HIV-1 growth. The remainder of the work describes how these peptides bind to RRE RNA, while demonstrating that they are non-toxic and bind HIV-1 in a concentration dependent manner.
A transporter protein termed Spinster homolog 2 (spns2) transports a signaling molecule known as sphingosine 1-phosphate (S1P). For our immune system to function properly, spns2 has to transport S1P to the appropriate places to signal to immune cells. Unfortunately, this is a problem in autoimmune and inflammatory diseases, such as multiple sclerosis, due to these diseases having an overactive immune system. A potential way to treat these diseases would be by inhibiting spns2. This work describes the design, synthesis, and biological evaluation of spns2 inhibitors. Many compounds were found to inhibit spns2 to a degree, but three compounds, in particular, show potent and effective inhibition in mice.
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