Browsing by Author "Sobrado, Pablo"

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    AMP-activated protein kinase and muscle metabolism
    Scheffler, Tracy L. (Virginia Tech, 2012-07-11)
    AMP-activated protein kinase (AMPK) is a major regulator of skeletal muscle metabolism with relevance to agriculture and human health. During the conversion of muscle to meat, the rate and extent of postmortem metabolism and pH decline largely determine pork quality development. Pigs with the AMPKγ3 R200Q mutation generate pork with low ultimate pH (pHu); this is attributed to high glycogen content, and greater "potential" to produce lactate and H+. We hypothesized that decreasing muscle phosphocreatine and creatine would decrease ATP buffering capacity, resulting in earlier termination of glycolysis and pH decline. Dietary supplementation with the creatine analogue, β-GPA, decreased muscle total creatine but negatively affected performance. Another experiment was conducted using control or β-GPA diet and wild type and AMPKγ3R200Q pigs in a 2Ã 2 factorial design. The loss of muscle total creatine was important in maintenance of ATP levels in AMPKγ3R200Q muscle early postmortem. Moreover, elevated glycogen did not affect pHu, supporting that energetic modifications induced by feed restriction and β-GPA supplementation influence extent of pH decline. Next, we utilized a line of pigs selected for differences in pHu. Another AMPKγ3 mutation (V199I), which is associated with higher pHu and lower glycolytic potential, was prevalent. The 199II genotype increased pHu in castrated males only. The wild type VV genotype increased glycolytic potential, but neither glycolytic potential nor lactate predicted pHu. In humans, AMPK activation is at least partly responsible for the beneficial effects of exercise on glucose transport and increased oxidative capacity in skeletal muscle. An inverse relationship exists between skeletal muscle fiber cross-sectional area and oxidative capacity, which suggests muscle fibers hypertrophy at the expense of oxidative capacity. Therefore, we utilized pigs possessing mutations associated with increased oxidative capacity (AMP-activated protein kinase, AMPKγ3R200Q) or fiber hypertrophy (ryanodine receptor 1, RyR1R615C) to determine if these events occur in parallel. RyR1R615C increased muscle fiber size; AMPKγ3R200Q increased oxidative capacity, evidenced by enhanced enzyme activity, mitochondrial function, and expression of mitochondrial proteins. Thus, pigs with both AMPKγ3R200Q and RyR1R615C possess increased fiber size and oxidative capacity, suggesting hypertrophy and oxidative capacity can occur simultaneously in skeletal muscle.
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    Biochemical Characterization of Arabidopsis Enzymes Involved in Inositol Pyrophosphate Biosynthesis
    Adepoju, Olusegun Adeboye (Virginia Tech, 2019-09-05)
    To compensate for the sessile nature of plants, thousands of years of evolution have led to the development of many sophisticated signaling pathways that help plants sense and respond appropriately to different environmental cues. One such signaling pathway is called inositol phosphate signaling. This research dissertation focuses on the inositol phosphate signaling pathway in plants, with emphasis on elucidating how a new class of signaling molecules collectively referred to inositol pyrophosphates are synthesized. Inositol pyrophosphates are an emerging class of "high-energy" intracellular signaling molecules containing one or two diphosphate groups attached to an inositol ring, with suggested roles in bioenergetic homeostasis and inorganic phosphate sensing. Information regarding the biosynthesis of this unique class of signaling molecules in plants is scarce, however the enzymes responsible for their biosynthesis in other eukaryotes have been well described. This work aims to characterize the biochemical activity of the kinase domain (KD) of the Arabidopsis plant diphosphoinositol pentakisphosphate kinase enzymes (AtVIP1 and AtVIP2), and elucidate the biosynthesis pathway of inositol pyrophosphates in plants. Our data indicate that AtVIP1-KD and AtVIP2-KD function primarily as diphosphoinositol pentakisphosphate 5 kinases that phosphorylate this substrate at the 1-position. We also discovered a previously unreported inositol hexakisphosphate kinase activity for the Arabidopsis inositol(1,3,4) triphosphate 5/6kinase enzymes, that can convert InsP6 to InsP7. Together, these enzymes can function in plants to produce inositol pyrophosphates, which have been implicated in signal transduction and phosphate sensing pathways. The significance and potential application of these findings in terms of reduced phytate content and phosphate pollution, improved plant fitness, and improved nutrient use efficiency are discussed. The future outlook of inositol phosphate signaling research is also discussed.
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    Biochemical characterization of Aspergillus fumigatus SidA: a flavin-dependent N-hydroxylating enzyme
    Chocklett, Samuel Wyatt (Virginia Tech, 2009-12-09)
    Ferrichrome is a hydroxamate-containing siderophore produced by the pathogenic fungus Aspergillus fumigatus during infection. This siderophore includes N5-hydroxylated L-ornithine in the peptide backbone that serve as iron chelators. Af SidA is the L-ornithine N5-hydroxylase, which performs the first enzymatic step in the biosynthesis of ferrichrome. In this study, Af SidA was recombinantly expressed and purified as a soluble tetramer with a bound FAD cofactor. The enzyme demonstrated typical Michaelis-Menten kinetics in a product formation assay with respect to L-ornithine, but similar experiments as a function NADH and NADPH indicated inhibition at high coenzyme concentrations. Af SidA is highly specific for its substrate; however, it is promiscuous with respect to its coenzyme requirement. A multi-functional role of NADPH is observed since NADP+ is a competitive inhibitor with respect to NADPH and steady-state kinetic experiments indicate that Af SidA forms a ternary complex with NADP+ and L-ornithine for catalysis. Furthermore, in the absence of substrate, Af SidA forms a stable C4a-(hydro)peroxyflavin intermediate that is stable on the second time scale. Af SidA is also inhibited by several halides and the arginine-reactive reagent, phenylglyoxal. Biochemical comparison of Af SidA to other flavin-containing monooxygenases reveal that Af SidA likely proceeds by a sequential-ordered mechanism.
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    Biochemical Characterization of Thermocrispum agreste TheA: A Flavin-Dependent N-hydroxylating Enzyme
    Mena Aguilar, Didier Philippe (Virginia Tech, 2018-06-26)
    N-hydroxylating monooxygenases (NMOs) are Class B flavin-dependent monooxygenases found only in fungi and bacteria. These enzymes catalyze the hydroxylation of nucleophilic primary amines, such as those found in histamine, L-ornithine, L-lysine, and small aliphatic diamines. The hydroxamate moiety produced by this reaction is key for the production of siderophores, small chelating compounds that allow survival in iron limiting conditions. NMOs involved in siderophore biosynthesis have been shown to be essential for pathogenesis in organisms such as Aspergillus fumigatus, Pseudomonas aeruginosa, and Mycobacterium tuberculosis. Therefore, NMOs are considered novel drug targets for the treatment associated with these diseases. Herein we present the characterization of TheA, an NMO from Thermocrispum agreste. The enzyme mechanism was studied using steady state kinetic measurements, thermostability, and stopped flow spectrophotometry assays. Using these techniques, the catalytic rates, substrate binding affinities, thermal stability, and coenzyme specificities were determined. Additionally, NADPH analogues were produced to use as tools to study FAD reduction in NMOs. An unspecific reduction reaction of NADP+ using NaB2H4 yielded [6-2H]-NADPH, [2-2H]-NADPH, and [4-2H]-NADPH. Compound identity was confirmed by mass spectrometry and unidimensional proton nuclear magnetic resonance (NMR). Results presented in this thesis lay the foundation for future studies of NMOs using NADPH analogues. In conjunction, these results will improve the general knowledge and understanding of flavoenzymes, ornithine monooxygenases, and their associated mechanisms.
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    Biosynthesis of Galactofuranose in Kinetoplastids: Novel Therapeutic Targets for Treating Leishmaniasis and Chagas' Disease
    Oppenheimer, Michelle; Valenciano Murillo, Ana L.; Sobrado, Pablo (Hindawi, 2011-05-25)
    Cell surface proteins of parasites play a role in pathogenesis by modulating mammalian cell recognition and cell adhesion during infection. β-Galactofuranose (Galf) is an important component of glycoproteins and glycolipids found on the cell surface of Leishmania spp. and Trypanosoma cruzi. β-Galf-containing glycans have been shown to be important in parasite-cell interaction and protection against oxidative stress. Here, we discuss the role of β-Galf in pathogenesis and recent studies on the Galf-biosynthetic enzymes: UDP-galactose 4′ epimerase (GalE), UDP-galactopyranose mutase (UGM), and UDP-galactofuranosyl transferase (GalfT). The central role in Galf formation, its unique chemical mechanism, and the absence of a homologous enzyme in humans identify UGM as the most attractive drug target in the β-Galf-biosynthetic pathway in protozoan parasites.
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    Characterization of a Nitro-Forming Enzyme Involved in Fosfazinomycin Biosynthesis
    Valentino, Hannah; Sobrado, Pablo (American Chemical Society, 2021-09-28)
    N-hydroxylating monooxygenases (NMOs) are a subclass of flavin-dependent enzymes that hydroxylate nitrogen atoms. Recently, unique NMOs that perform multiple reactions on one substrate molecule have been identified. Fosfazinomycin M (FzmM) is one such NMO, forming nitrosuccinate from aspartate (Asp) in the fosfazinomycin biosynthetic pathway in someStreptomycessp. This work details the biochemical and kinetic analysis of FzmM. Steady-state kinetic investigation shows that FzmM performs a coupled reaction with Asp (kcat, 3.0 ± 0.01 s-1) forming nitrosuccinate, which can be converted to fumarate and nitrite by the action of FzmL. FzmM displays a 70-fold higherkcat/KMvalue for NADPH compared to NADH and has a narrow optimal pH range (7.5-8.0). Contrary to other NMOs where thekredis rate-limiting, FzmM exhibits a very fastkred(50 ± 0.01 s-1at 4 °C) with NADPH. NADPH binds at aKDvalue of ∼400 μM, and hydride transfer occurs withpro-Rstereochemistry. Oxidation of FzmM in the absence of Asp exhibits a spectrum with a shoulder at ∼370 nm, consistent with the formation of a C(4a)-hydroperoxyflavin intermediate, which decays into oxidized flavin and hydrogen peroxide at a rate 100-fold slower than thekcat. This reaction is enhanced in the presence of Asp with a slightly fasterkoxthan thekcat, suggesting that flavin dehydration or Asp oxidation is partially rate limiting. Multiple sequence analyses of FzmM to NMOs identified conserved residues involved in flavin binding but not for NADPH. Additional sequence analysis to related monooxygenases suggests that FzmM shares sequence motifs absent in other NMOs.
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    Characterization of Peptidoglycan, and the Enzymes that Synthesize it, in Borrelia burgdorferi and Insights into the Peptidoglycan of Other Pathogenic Borrelia
    DeHart, Tanner Gage (Virginia Tech, 2021-06-03)
    Peptidoglycan (PG) is an essential cell-wall biopolymer in virtually all bacteria. It is composed of glycan strands of N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) crosslinked by peptide chains of alternating D- and L- amino acids and diamines. PG plays an important role in 1) cell elongation and division, 2) cell strength and morphology, 3) antibiotic susceptibility, and 4) host immune detection and modulation. While differences in peptide chains are common, deviations in glycan strand composition were not previously known to occur. Here, we provide characterization of the first known deviation to bacterial glycan strand composition — GlcNAc-GlcNAc-anhMurNAc (G-G- anhM) in Borrelia burgdorferi, the causative agent of Lyme disease. B. burgdorferi with less G-G-anhM were found to be significantly less motile, flexible, and stress-tolerant while possessing gross morphological defects and less overall PG. Our studies also characterized the muropeptide profile of Borrelia afzelii, Borrelia garinii, and Borrelia hermsii — species of Borrelia associated with causing different disease manifestations of Lyme disease, and relapsing fever, respectively. These species were found to incorporate appreciable amounts of G-G-anhM into their PG, suggesting an evolutionary adaptation to life inside a tick that predates the differentiation of Lyme disease and relapsing fever Borrelia. Finally, we provide partial characterization of a putative penicillin-binding protein in B. burgdorferi — a class of highly conserved PG synthesis enzymes present in the vast majority of bacteria. Collectively, the work in this thesis furthers our understanding of the structure, function, and synthesis of PG in Borrelia.
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    Characterization of the amino acid transporter AAP1 in Arabidopsis thaliana
    Boyd, Shelton Roosevelt (Virginia Tech, 2018-01-22)
    Amino acids are essential molecules in plant metabolism. Amino acids carry reduced nitrogen while serving as precursors for protein synthesis and secondary metabolites. Translocation of amino acids in the cell is mediated by amino acid transporters. While about 100 transporters have been identified, only a dozen have been fully characterized. The regulation of amino acid transporters is not fully understood and stands as the basis of this study. Previous toxicity-based screenings of Arabidopsis thaliana mutants led to the isolation of a loss-of-function line and the phenylalanine insensitive growth (pig1) mutant capable of growth on toxic concentrations of phenylalanine (1). The pig1-1 mutants also displayed a deregulated metabolism (1). We followed this work with a similar forward genetic screening of Arabidopsis thaliana that led to the identification of 18 mutants capable of growth in the presence of amino acids at toxic concentrations. From this screen, seven mutations were confirmed to affect the amino acid transporter AAP1. Here I demonstrate that, when expressed in yeast deficient for endogenous amino acid transporters, three variant aap1 proteins restored growth similar to yeast complemented by wild type AAP1. Transport of radiolabeled Pro was abolished by variant aap1 proteins while deletion of an intracellular loop spanning the 8th and 9th transmembrane domains reduced Pro transport in yeast. Site directed mutagenesis of this loop conferred a variant aap1 protein which augmented Pro transport in yeast. Amino acid transport in loss-of-function aap1 plants display decreased uptake and increased efflux. In addition, aap1 mutant plants accumulated between 2 and 8 times more free amino acids in the leaves than the wild type. These observations are not fully compatible with the accepted role of AAP1 in transport by the root. The present work describes how the amino acid transporter AAP1 could play a role in regulating amino acid metabolism. We hypothesize that the amino acid transporter AAP1 functions as a senor that is involved in amino acid homeostasis in addition to its established role as a transporter. Is true, this would make AAP1 the first identified amino acid sensor in plants. Knowledge of the mechanism of amino acid sensing would enable us to engineer crops for improved nutrition in a more efficient way than affecting metabolic enzymes.
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    Characterization of the Ornithine Hydroxylation Step in Albachelin Biosynthesis
    Bufkin, Kendra; Sobrado, Pablo (MDPI, 2017-10-01)
    N-Hydroxylating monooxygenases (NMOs) are involved in siderophore biosynthesis. Siderophores are high affinity iron chelators composed of catechol and hydroxamate functional groups that are synthesized and secreted by microorganisms and plants. Recently, a new siderophore named albachelin was isolated from a culture of Amycolatopsis alba growing under iron-limiting conditions. This work focuses on the expression, purification, and characterization of the NMO, abachelin monooxygenase (AMO) from A. alba. This enzyme was purified and characterized in its holo (FAD-bound) and apo (FAD-free) forms. The apo-AMO could be reconstituted by addition of free FAD. The two forms of AMO hydroxylate ornithine, while lysine increases oxidase activity but is not hydroxylated and display low affinity for NADPH.
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    Characterization of Transcriptional and Post-transcriptional Regulation of lin-42/Period During Post-embryonic Development of C. elegans
    James, Tracy (Virginia Tech, 2012-09-11)
    Period, which is broadly conserved in metazoans, regulates circadian timing of neurophysiology as well as cell fate specification. Studies in mouse and humans indicate that period functions as a tumor suppressor and controls adult stem cell differentiation. However, regulation of period function in developmental pathways has not been characterized and appears to be different from its regulation and function in circadian pathways. lin-42 is the Caenorhabditis elegans ortholog of period and has both circadian and developmental timing functions. During post-embryonic larval development, cyclic expression and function of lin-42 controls stage-specific and reiterative cell fate choices of a subset of epidermal stem cells called seam cells. We are studying lin-42 regulation of seam cell fate during C. elegans larval development as a model for understanding the mechanisms of period regulation of adult stem cell fate in mammals. This dissertation describes the research undertaken to characterize the cis-regulatory elements and the trans-regulatory factors that control lin-42 expression. We used direct molecular interaction assays (Electrophoretic Mobility Shift Assay, EMSA) (Chapter 2) followed by an RNA interference (RNAi)-based genetic screen (Chapter 3) to identify lin-42 transcriptional regulators. Using the EMSA, we identified three 50 to 100 base pair regions (binding regions, BR1-3) in the lin-42 5â noncoding sequences that were bound with specificity by C. elegans nuclear proteins. These binding regions represent putative cis-regulatory elements that may serve as transcription factor binding sites (TFBSs). We attempted to identify by mass spectrometry the proteins that bind to the BR sequences. We also used Phylogenetic Footprinting and bioinformatics screens to identify candidate C. elegans transcription factors (TFs) that may bind to putative TFBSs within the BR sequences. Using an RNAi-based screen, we tested the candidate TF genes for potential genetic interactions with lin-42. We identified ZTF-16, a member of the Hunchback/Ikaros zinc-finger transcription factor family, as a potential lin-42 activator and, using quantitative real-time PCR, confirmed that ztf-16 mutation results in down-regulation and loss of cycling expression of lin-42. We further determined that loss of ztf-16 results in seam cell development defects that phenocopy lin-42 loss-of-function, thus validating ZTF-16 as a transcriptional activator of lin-42.
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    Chemical Mechanism of UDP-Galactopyranose Mutase from Trypanosoma cruzi: A Potential Drug Target against Chagas' Disease
    Oppenheimer, Michelle; Lisa Valenciano, Ana; Kizjakina, Karina; Qi, Jun; Sobrado, Pablo (PLOS, 2012-03-20)
    UDP-galactopyranose mutase (UGM) is a flavoenzyme that catalyzes the conversion of UDP-galactopyranose to UDP-galactofuranose, the precursor of galactofuranose (Galf). Galf is found in several pathogenic organisms, including the parasite Trypanosoma cruzi, the causative agent of Chagas' disease. Galf) is important for virulence and is not present in humans, making its biosynthetic pathway an attractive target for the development of new drugs against T. cruzi. Although UGMs catalyze a non-redox reaction, the flavin must be in the reduced state for activity and the exact role of the flavin in this reaction is controversial. The kinetic and chemical mechanism of TcUGM was probed using steady state kinetics, trapping of reaction intermediates, rapid reaction kinetics, and fluorescence anisotropy. It was shown for the first time that NADPH is an effective redox partner of TcUGM. The substrate, UDP-galactopyranose, protects the enzyme from reacting with molecular oxygen allowing TcUGM to turnover ∼1000 times for every NADPH oxidized. Spectral changes consistent with a flavin iminium ion, without the formation of a flavin semiquinone, were observed under rapid reaction conditions. These data support the proposal of the flavin acting as a nucleophile. In support of this role, a flavin-galactose adduct was isolated and characterized. A detailed kinetic and chemical mechanism for the unique non-redox reaction of UGM is presented.
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    Circadian modulation of the estrogen receptor alpha transcription
    Villa, Linda Monique (Virginia Tech, 2012-07-12)
    The circadian clock is a molecular mechanism that synchronizes physiological changes with environmental variations. Disruption of the circadian clock has been linked to increased risk in diseases and a number of disorders (e.g. jet lag, insomnia, and cancer). Period 2 (Per2), a circadian protein, is at the center of the clock's function. The loss or deregulation of per2 has been shown to be common in several types of cancer including breast and ovarian [1, 2]. Epidemiological studies established a correlation between circadian disruption and the development of estrogen dependent tumors. The expression of estrogen receptor alpha (ERα) mRNA oscillates in a 24-hour period and, unlike Per2, ERα peaks during the light phase of the day. Because up regulation of ERα relates to tumor development, defining the mechanisms of ERα expression will contribute to our comprehension of cellular proliferation and regulation of normal developmental processes. The overall goal of this project is to investigate the molecular basis for circadian control of ERα transcription. Transcriptional activation of ERα was measured using a reporter system in Chinese hamster ovary (CHO) cell lines. Data show that Per2 influences ERα transcription through a non-canonical mechanism independent of its circadian counterparts. Breast cancer susceptibility protein 1 (BRCA1) was confirmed to be an interactor of Per2 via bacterial two-hybrid assays, in accordance with previous studies [2]. BRCA1 is a transcriptional activator of ERα promoter in the presence of octamer transcription factor-1 (OCT-1) [3]. Our results indicate that the DNA binding domain of OCT-1, POU, to directly interact with Per2 and BRCA1, in vitro. Pull-down assays were used to map direct interaction of various Per2 and BRCA1 recombinant proteins and POU. Chromatin immunoprecipitation assays confirmed the recruitment of PER2 and BRCA1 to the estrogen promoter by OCT-1 and the recruitment of Per2 to the ERα promoter decreases ERα mRNA expression levels in MCF-7 cells. Our work supports a circadian regulation of ERα through the repression of esr1 by Per2 in MCF-7 cells.
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    CT610: A Mn-Dependent Self-Sacrificing Oxygenase in p-Aminobenzoate Biosynthesis in Chlamydia trachomatis
    Wooldridge, Rowan Scott (Virginia Tech, 2022-06-09)
    Folate is an essential cofactor required for several processes including DNA and amino acid biosynthesis. Folate molecules are made up of three parts: a pteridine ring, p-aminobenzoate (pABA), and a variable number of glutamate residues. Chlamydia trachomatis synthesizes folate de novo; however, several genes encoding enzymes required for the canonical folate biosynthesis pathway are missing, including pabA/B and pabC, which are normally required for pABA biosynthesis from chorismate. Previous studies have found that a single gene in C. trachomatis, CT610, functionally replaces the canonical pABA biosynthesis genes. Interestingly, CT610 does not use chorismate as a substrate. Instead, the CT610-route for pABA biosynthesis incorporates isotopically labeled tyrosine into the synthesized pABA molecule. However, in vitro experiments revealed that CT610 produces pABA without any added substrates (including tyrosine) in the presence of a reducing agent and molecular oxygen. CT610 shares low sequence similarity to non-heme diiron oxygenases and the previously solved crystal structure revealed a diiron active site. Taken together, CT610 is proposed to be a novel self-sacrificing enzyme that uses one of its active site tyrosine residues as a precursor to pABA in a reaction that requires O2 and a reduced metallocofactor. Here, we discuss our progress towards understanding CT610-catalyzed pABA synthesis. Upon investigation of the pABA production and oxygenase activities of several active site tyrosine to phenylalanine variants, we found that Y27 and/or Y43 are the most likely precursors to the resulting pABA molecule. Further, activity was nearly completely abolished with a K152R variant, suggesting that this conserved lysine may be the required amino group donor. We also developed an in vitro Fe(II) reconstitution procedure, where the reconstituted enzyme exhibited a drastic increase in oxygenase activity but, surprisingly, a significant decrease in pABA synthase activity. Interestingly, a significant increase in pABA synthase activity was observed when the enzyme was reconstituted with manganese as opposed to iron, suggesting that the diiron active site of this enzyme might not be directly involved in CT610-dependent production of pABA and instead Mn may be the actual cofactor. Finally, we show that two 18O atoms from molecular oxygen are incorporated into the pABA molecule when synthesized by Mn-reconstituted CT610, providing further evidence for the oxygenase activity of CT610 and supporting our proposed mechanism that involves two monooxygenase reactions.
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    Decoding novel virulence strategies in Fusobacterium invasion and survival
    Nguyen, Tam (Virginia Tech, 2022-06-08)
    Fusobacterium nucleatum is an anaerobic, Gram-negative, oral bacterium that disseminates from the mouth, and contributes to preterm birth, tissue infections, and acceleration of multiple cancers including colorectal and pancreatic. It is well-established that most Fusobacterium species exhibit genetic recalcitrance, which has led to hindrance in the understanding of their biology and molecular pathogenesis. Though the association of Fusobacterium in diseases is well-established, the majority of our experimental work stems from the strain F. nucleatum ATCC 23726 because it is genetically tractable. Here, in this dissertation, we show that we are able to enhance our existing molecular tools for genome editing to introduce the first mutants in a clinically relevant strain, F. nucleatum ATCC 25586, a feat that was never accomplished in decades of trying. Furthermore, we created a deletion library of genes predicted to be involved in host cellular invasion and survival. In this work, we identified a novel small adhesin, FadA2, that played a significant role in the invasive ability of F. nucleatum ATCC 25586 to colorectal cancer cells. This dissertation also sheds the first insight into the roles of the type 5a autotransporters. Using a deletion library of genes encoding for the type 5a autotransporter proteins in F. nucleatum ATCC 23726, we systemically characterized altogether 12 type 5a proteins with a focus on the invasion of colorectal cancer cells. Most notably, we found that a wide assortment of type 5a proteins contributing to binding and invasion of F. nucleatum to HCT116 cancer cells. Furthermore, we identified that RadD was not directly involved in inducing secretions of the cytokines IL-8 and CXCL1 while confirmed the specific association of Fap2 in bacterial-induced cytokine secretion. Thus, our findings provided the first comparative and functional analysis of Fusobacterium type 5a autotransporter proteins in colorectal cancer cells which will be crucial to the understanding of Fusobacterium involvement in cancer progression. Finally, this dissertation reported on the first ever observation on the survival strategy of Fusobacterium inside the host cells. We uncovered a novel protein that contributed to enhanced survival of Fusobacterium residing in colorectal cancer cells. This work undoubtedly helps expand the current Fusobacterium genetic toolkit to study proteins and mechanisms relevant to Fusobacterium-accelerated diseases. By identifying and characterizing novel virulence strategies that Fusobacterium can take advantage of, we can increase our comprehension on this opportunistic microbe while devising innovative therapeutic treatments.
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    Defining the role of mitochondria in fresh meat quality development
    Matarneh, Sulaiman K. (Virginia Tech, 2017-07-12)
    During postmortem metabolism, hydrogen ions accumulate in the muscle and gradually lower the pH from 7.2 to an ultimate pH near 5.6. The ultimate pH of meat is widely valued as an indicator of fresh meat quality as it directly affects the quality characteristics of color, texture, and water holding capacity. Therefore, our research was conducted to identify the processes responsible for determining ultimate pH. Pigs harboring the AMPK�•3R200Q mutation produce meat with extremely low ultimate pH (pH ~ 5.3) that is detrimental to quality. This phenomenon is often attributed to a greater glycogen content in muscle from the mutant pigs compared to wild-type pigs. However, our research indicated that greater glycolytic flux in muscle from these pigs causes a lower ultimate pH rather than greater tissue glycogen deposition. On the other hand, however, AMPK�•3R200Q pigs contain more mitochondria and retain greater oxidative capacity. Hence, we hypothesized that mitochondria may contribute to the lower ultimate pH in muscle of these pigs. To test our hypothesis, isolated mitochondria were incorporated into an in vitro system the mimics postmortem glycolysis. Mitochondria enhanced glycolytic flux and pH decline in the in vitro system similar to that of AMPK�•3R200Q pigs. After a series of experiments, we found that the causative agent for enhanced glycolytic flux is a soluble mitochondrial protein. In other experiments, mitochondrial F1-ATPase was found to be responsible for the majority of this effect, principally through promoting greater ATP hydrolysis at lower pH values, thereby allowing for greater flux through glycolysis. These data suggest that variations in ultimate pH may be more thoroughly explained and predicted by the abundance of mitochondria. Broiler pectoralis major muscle, which is a highly glycolytic muscle, possesses high ultimate pH (pH ~ 5.9) compared to pork and beef. We postulated that rapid carcass chilling reduces the flux through glycolysis, thereby causing premature termination of postmortem metabolism. Yet, chilling was only partially responsible for the high ultimate pH of pectoralis major muscle. However, we showed that pectoralis major of broiler chicken exhibits lower phosphofructokinase-1 activity compared to porcine longissimus lumborum muscle, which limits the flux through glycolysis.
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    Determinants of Core Shell Dependent Rotavirus Polymerase Activity
    Steger, Courtney Long (Virginia Tech, 2019-02-22)
    Rotaviruses (RVs) are medically significant gastrointestinal pathogens and are a leading cause of childhood mortality in many countries. The RV RNA-dependent RNA polymerase, VP1, synthesizes RNA during viral replication only in the presence of another RV protein, VP2, which comprises the innermost core shell layer of the virion. Though these VP1-VP2 interactions are essential for RV replication, the mechanism by which the core shell regulates polymerase activity remains incompletely understood. Here, we sought to identify and characterize specific regions of both VP1 and VP2 that are required for core shell dependent polymerase activity. First, we used bioinformatics approaches to analyze VP1 and VP2 sequence diversity across many RV strains and identify positional locations of critical amino acid changes within the context of known structural domains and motifs. We next tested how the identified sequence differences influenced VP2-dependent VP1 activity in vitro. These data revealed that VP1 and VP2 protein diversity correlates with functional differences between avian and mammalian RV strains. Then, we used these sequential and functional incompatibilities to map key regions of VP1 important for mediating RNA synthesis. To pinpoint critical interacting regions of VP1 and VP2, we used site directed mutagenesis to engineer several modified VP1 and VP2 proteins. Then, we employed an in vitro RNA synthesis assay to test how the introduced mutations influenced VP2-dependent VP1 activity. Altogether, our results revealed several functionally important VP1 residues critical for in vitro VP2-dependent VP1 activity, either individually or in combination with neighboring residues, including E265/L267, R614, and D971/S978/I980. Structural analyses show VP2 interactions at these surface-exposed VP1 sites, which altogether supports a direct contact model of core shell dependent RV polymerase activity. Moreover, recombinant VP1 proteins containing multiple mutations at buried residues were incapable of facilitating RNA synthesis in vitro under the assay conditions, indicating that an extensive intramolecular signaling network exists to mediate VP1 activity. Taken together, these results suggest that VP2 binding at the VP1 surface may induce intramolecular interactions critical for VP1 activity. Overall, results from these studies provide important insight into VP1-VP2 binding interface(s) that are necessary for RV replication.
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    Developing a Novel Cell Surface RNA Detecting and Profiling Method via RNA Metabolic Labeling
    Brooks, Maxwell David (Virginia Tech, 2024-06-03)
    Cell surface RNA (csRNA) is a recent discovery in the field of RNA biology and has been implicated in playing important roles in many biological processes due to its extracellular properties. To understand the biogenesis, regulation, and function of csRNA, it is critical to develop methods to detect, isolate, and confidently characterize membrane-bound csRNA. Previously, csRNA has been profiled using methods based on cell membrane isolation that are expensive, laborious, and with unsatisfactory specificity and sensitivity . In this study, we use metabolic labeling and chemical cross-linking techniques to specifically label csRNA with biotin handles. We intended to use this technique for separating biotin-labeled csRNA from total RNA samples for characterization purposes. The primary materials that were used to label such csRNAs are 4-Thiouridine (4sU), an unnatural nucleotide analogue, and S-(2-aminoethyl)-ester-methanesulfonothioic-acid-biotin (MTSEA-biotin), a crosslinker designed specifically to label 4sU. By deploying these tools to cell lines such as HEK293T and HeLa, csRNA is detectable by Enhanced Chemiluminescent detection via Dot Blot. Furthermore, to separate biotin-labeled csRNA from total RNA, streptavidin-coated magnetic bead separation procedures could be used as a promising method for purifying csRNA from total RNA, for RNAseq characterization. This study highlights the processes of establishing the csRNA detection protocol and describes the current status and issues with developing the streptavidin-coated magnetic beads separation method.
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    Developing novel drug combinations for treatment of invasive fungal infections
    Salama, Ehab Ali (Virginia Tech, 2023-12-20)
    Several Fungal species have the potential to cause a broad spectrum of diseases in humans, ranging from mild superficial to disseminated invasive infections that involve the bloodstream and vital organs. Invasive fungal infections are severe, life-threatening diseases that result in the deaths of 1.5 million patients each year. The most common fungal species responsible for the majority of invasive fungal infections include Candida, Cryptococcus, and Aspergillus. The current treatment options for invasive fungal infections are restricted to three classes of antifungals: Azoles, polyenes, and echinocandins. The emergence of new fungal species, especially C. auris, marked by high resistance profiles and increased mortality rates (30-60%), has further exacerbated the limitations in its therapeutic options. This emphasizes the urgent need for effective alternatives to combat these deadly pathogens. C. auris isolates exhibited high resistance capability especially against azole (fluconazole) and polyene (amphotericin B) antifungals. Here, we utilized the combinatorial strategy to screen ~3400 FDA-approved drugs and clinical compounds to identify hits that can enhance/restore the antifungal activity of azoles and amphotericin B against resistant C. auris. The HIV protease inhibitors (lopinavir and ritonavir) were identified as potent enhancers to the antifungal activity of azole drugs (fluconazole, voriconazole and itraconazole). We confirmed that lopinavir and ritonavir have the capability to interfere with fungal efflux pump machinery. The in vivo efficacy of the combination of azole antifungals and HIV protease inhibitors was also evaluated to discover the best combination of itraconazole, lopinavir and ritonavir. Three drugs (lansoprazole, rolapitant and idebenone) were identified to effectively enhance the antifungal effects of amphotericin B and overcome its resistance in C. auris. Furthermore, the synergistic interactions of these combinations were applied on other medically important Candida, Cryptococcus, and Aspergillus species. In a comprehensive mechanistic study, we discovered that lansoprazole interferes with an essential target in the fungal mitochondrial cytochrome system, cytochrome bc1. This interference induces oxidative stress in fungal cells and subsequently enhances the antifungal activity of amphotericin B. For rolapitant, a transcriptomic analysis along with ATP luminescence assays confirmed that rolapitant at sub-inhibitory concentrations significantly interferes with ATP production in C. auris. For idebenone, checkerboard assays confirmed the synergistic interactions between amphotericin B and idebenone against a diversity of medically important fungal species. This combination exhibited a rapid fungicidal activity within 4 hours. Additionally, the cytotoxicity of this combination was assessed in a cell line model of kidney cells. Based on the potent in vitro and in vivo synergistic relationships observed for the identified combinations, it can be concluded that our approach offers a new hope to restore the antifungal activity of the existing antifungal drugs, even against resistant fungal infections. Additionally, it provides valuable insights into identifying novel targets to overcome resistance in multidrug-resistant fungal pathogens.
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    Discovery and Mechanisms of Small Molecule Amyloid Formation Inhibitors
    Velander, Paul William (Virginia Tech, 2018-01-17)
    Current dogma suggests modulating or preventing amyloid assembly will prove critical to the armamentarium of therapeutic interventions that will likely be required to overcome the multifaceted pathology associated with amyloid diseases. The work described in this dissertation reveals substantial gains in understanding key aspects relating to the anti-amylin amyloid activities associated with both individual and broad groups of small molecule amyloid inhibitors. A main observation was the important role that the catechol functional group plays in modulating and preventing amyloid formation. In this context, each chapter provides unique yet complementary mechanistic insight that delineates a wide range of anti-amyloid activities associated with preventing amylin amyloid formation by mainly catechol-containing structural scaffolds. Structure activity studies show that the catechol moiety present within baicalein, oleuropein and rosmarinic acid are critical for their anti-amyloid functions, including exerting cell rescue effects against amylin induced cytotoxicity. We also demonstrate that in general, autoxidation enhances the anti-amyloid potency associated with many catechol containing amyloid inhibitors that may be mechanistically linked to a covalent mode of action. For example, we demonstrate that the O-quinone form of baicalein conjugates with amylin via a Schiff base mechanism. In contrast, we also show that catechol mediated formation of protein denaturant resistant aggregates, which requires autoxidation and that also stems from a predicted covalent mode of action, does not necessarily correlate with the enhanced anti-amyloid activities that occur upon catechol autoxidation. Regardless of the chemical mechanism(s) that drive catechol mediated anti-amyloid activity in vitro, the observed cell rescue effects exhibited by catechol containing molecules against amylin amyloid induced cytotoxicity is congruent with several recent in vivo studies that indicate polyphenols prevent toxic amyloid deposition as well as decades of population based studies that show regular consumption of diets rich in polyphenols are linked to a reduce incidence of age-related neurodegenerative amyloid disease. Indeed, advances in structure based drug discovery against amyloid formation may provide new avenues to optimize various catechol containing scaffolds that could be readily leveraged into improving diagnostic tools or perhaps accelerate the effort of discovering anti-amyloid therapeutics.
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    Discovery of Two Inhibitors of the Type IV Pilus Assembly ATPase PilB as Potential Antivirulence Compounds
    Dye, Keane J.; Vogelaar, Nancy J.; O'Hara, Megan; Sobrado, Pablo; Santos, Webster; Carlier, Paul R.; Yang, Zhaomin (American Society for Microbiology, 2022-12)
    Many bacterial pathogens use their type IV pilus (T4P) to facilitate and maintain an infection in a human host. Small-molecule inhibitors of the production or assembly of the T4P are promising for the treatment and prevention of infections by these bacteria, especially in our fight against antibiotic-resistant pathogens. With the pressing antibiotic resistance pandemic, antivirulence has been increasingly explored as an alternative strategy against bacterial infections. The bacterial type IV pilus (T4P) is a well-documented virulence factor and an attractive target for small molecules for antivirulence purposes. The PilB ATPase is essential for T4P biogenesis because it catalyzes the assembly of monomeric pilins into the polymeric pilus filament. Here, we describe the identification of two PilB inhibitors by a high-throughput screen (HTS) in vitro and their validation as effective inhibitors of T4P assembly in vivo. We used Chloracidobacterium thermophilum PilB as a model enzyme to optimize an ATPase assay for the HTS. From a library of 2,320 compounds, benserazide and levodopa, two approved drugs for Parkinson's disease, were identified and confirmed biochemically to be PilB inhibitors. We demonstrate that both compounds inhibited the T4P-dependent motility of the bacteria Myxoccocus xanthus and Acinetobacter nosocomialis. Additionally, benserazide and levodopa were shown to inhibit A. nosocomialis biofilm formation, a T4P-dependent process. Using M. xanthus as a model, we showed that both compounds inhibited T4P assembly in a dose-dependent manner. These results suggest that these two compounds are effective against the PilB protein in vivo. The potency of benserazide and levodopa as PilB inhibitors both in vitro and in vivo demonstrate potentials of the HTS and its two hits here for the development of anti-T4P chemotherapeutics.IMPORTANCE Many bacterial pathogens use their type IV pilus (T4P) to facilitate and maintain an infection in a human host. Small-molecule inhibitors of the production or assembly of the T4P are promising for the treatment and prevention of infections by these bacteria, especially in our fight against antibiotic-resistant pathogens. Here, we report the development and implementation of a method to identify anti-T4P chemicals from compound libraries by high-throughput screen. This led to the identification and validation of two T4P inhibitors both in the test tubes and in bacteria. The discovery and validation pipeline reported here as well as the confirmation of two anti-T4P inhibitors provide new venues and leads for the development of chemotherapeutics against antibiotic-resistant infections.