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Predicting Treatment Response and the Role of the ISG15/USP18 Ubiquitin-like Signaling Pathway in Hepatitis C Viral InfectionChen, Limin 14 February 2011 (has links)
Hepatitis C Virus (HCV) infects 170 million people worldwide. The current treatment regimen, which is combination therapy with pegylated interferon (PegIFN) and Ribavirin (Rib), cures only 50% of the patients infected with the most prevalent HCV genotype. Therefore, there is a pressing need to understand the molecular mechanism of interferon resistance and to develop a prognostic tool to predict who will respond to treatment before initiation of therapy. It has been firmly established that the virus-host interaction plays an important role in determining treatment outcomes. My thesis investigated the host factors that are involved in interferon resistance with an aim to provide insights into the molecular mechanism of IFN resistance.
cDNA microarray analysis identified 18 differentially expressed hepatic genes from pretreatment liver tissues of responders (Rs) and non-responders (NRs). Based on the differential expression levels of these 18 genes, a prognostic tool was developed to predict who will respond to therapy, with a positive predicting value (PPV) of 96%. Most of these 18 genes are interferon stimulated genes (ISGs) and they are more highly expressed in NR livers, indicating that preactivation of interferon signaling in the pre-treatment liver tissues contributes to NR. 3 out of the 18 genes are involved in an ubiquitin-like ISG15/USP18 signaling pathway that plays an important role in interferon response. Over-expression of USP18 and ISG15 in the pretreatment liver tissues of NR promotes HCV production and blunts interferon anti-HCV activity. There exists a distinct cell-type specific ISG activation in the pretreatment liver tissues of Rs and NRs. Up-regulation of the two ISGs that I tested (ISG15 and MxA) was found mainly in hepatocytes in NRs while ISG activation was preferentially observed in macrophages in Rs.
Taking all these data together, pre-activation of interferon signaling and cell-type specific gene activation in the pretreatment liver tissues of patients infected with HCV are associated with treatment non-response. HCV exploits the host interferon system to favour its persistence by enhanced replication /secretion stimulated by a few ISGs (ISG15, USP18) in response to IFN. The developed prognostic tool can be used to stratify patients for treatment and the novel insights of the molecular mechanism of IFN resistance in HCV patients offer potential drug targets for future development.
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The Effect of Preovulatory Concentration of Estradiol and Length of Proestrus on Fertility in Beef CattleCruppe, Leandro Henrique 16 December 2011 (has links)
No description available.
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Investigating the Substrate Specificity of the Equivalent Papain-like Protease 2 Domain of nsp3 across Alpha- and Beta-CoronavirusesJozlyn Clasman (6632228) 11 June 2019 (has links)
<div>The papain-like protease (PLP) domain of nonstructural protein 3 (nsp3) of the coronavirus (CoV) genome promotes viral replication by processing the CoV polyprotein (protease) and also antagonize innate immune responses by deubiquitinating (DUB) and deISGylating (deISG) host substrates. Selectively removing the DUB/deISG activities of PLP while keeping the protease activity intact is a potential strategy for designing a live attenuated virus. However, it is unclear in the literature the precise mechanism by which PLPs support CoV evasion of the innate immune system. Deciphering the substrate specificity of PLPs for host ubiquitin (Ub) and interferon stimulated gene 15 (ISG15) can therefore help in the design of PLP mutants that selectively lack one activity for evaluating the DUB and deISG mechanism in CoV pathogenesis and replication. </div><div> In this dissertation, we investigate the structure and function of the single PLP (PLpro) from beta-CoVs, severe acute respiratory syndrome coronavirus (SARS-CoV) and Middle East respiratory syndrome coronavirus (MERS-CoV), which are dangerous viral pathogens that emerged from a zoonotic source to cause infectious disease in the human population. Additionally, we translate the knowledge gained to the equivalent PLP2 from alpha-CoV porcine epidemic diarrhea virus (PEDV) and feline infectious peritonitis virus (FIPV), which cause fatal disease in suckling piglets on industrial pork farms and household cats, respectively. The primary objective of this work is to rationally design PLP mutants across beta- and alpha-CoVs to help attenuate CoV infection, as no antiviral or vaccine exist for human CoVs and the efficacy of PEDV vaccines are an ongoing research topic. </div><div><br></div><div>In Chapter 1, different human, animal, and the bat origin CoV strains are introduced. The CoV life-cycle and virion structure are outlined, along with the replicase complex for viral replication. The multidomain nsp3 from alpha- and beta-CoV genomes are also described with a focus on the PLP domain and its proposed cleavage sites of the viral polyprotein. The discovery of the first viral protease DUB and the multiple activities of PLPs are defined, which includes a proposed model of how DUB versus deISG activities may act in the innate immune response. This leads into the therapeutic potential of PLP for an antiviral or live attenuated vaccine, which is followed by the introduction of live attenuated vaccines and the reverse genetics system. Next, proof of concept studies on PLP2 mutants are described and the introduction is concluded by stating the ultimate goal for the design of PLP mutants.</div><div><br></div><div>In Chapter 2, we hypothesize that the flanking ubiquitin-like (Ubl2) domain of MERS-CoV PLpro is not required for its enzymatic function. We characterize the specific activity, kinetics, substrate specificity, and inhibition of the PLpro enzyme with and without the Ubl2 domain and reveal that the Ubl2 domain does not significantly alter PLpro function. We determine the structure of the core PLpro, smallest catalytic unit to 1.9 Å resolution and observed no structural changes compared to the wild-type. Additionally, we demonstrate that a purported MERS-CoV PLpro inhibitor is nonselective in non-reducing conditions and should not be pursed for therapeutic use. We show that the core PLpro enzyme i.e. without the Ubl2 domain is a stable and robust construct for crystallization and is also thermally stable based on thermal melting studies with utility for structure-based drug design. </div><div><br></div><div>In Chapter 3, we shed light on the specificity of SARS-CoV PLpro towards Ub versus ISG15 by characterizing the specific activity and kinetic parameters of SARS-CoV PLpro mutants. In addition, the structure of SARS-CoV PLpro in complex with the C-terminal domain of ISG15 is determined and compared with the Ub-bound structure. Based on the structure and kinetic results, the altered specificities of SARS-CoV PLpro mutants Arg167Glu, Met209Ala, and Gln233Glu are compared with the wild-type. Arg167Glu mutant exhibits DUB hyperactivity and is expected to adopt a more favorable interaction with the Arg42 of Ub. At the same time, ARG167GLU contains a shorter side-chain that hinders interaction with the unique Trp123 of ISG15 for deISG activity compared to the wild-type. These results aid in the development of SARS-CoV PLpro mutants that have directed shifts in substrate specificity for Ub versus ISG15. </div><div><br></div><div>In Chapter 4, the process and antiviral activity of ISGylation is reviewed and how viruses can modulate host-derived versus virus-derived machineries to counteract ISGylation for viral infection. MERS-CoV PLpro is cross-reactive for Ub, but less is known about its specificity towards ISG15. In this study, we determine the structure of MERS-CoV PLpro bound with ISG15 to 2.3 Å resolution and reveal a small hydrophobic pocket of ISG15 that consists of P130 and W123, which differs from Ub hydrophobic patch. We design and determine the kinetic parameters for 13 PLpro mutants and reveal that MERS-CoV PLpro only has a single ubiquitin recognition (SUb1) site. Kinetic studies show that removing the charge of the R1649 greatly enhances DUB/protease activity while mutating in an Arg near R42 of Ub or ISG15 hydrophobic region is detrimental to both DUB/deISG activities. Kinetic experiments and probe-reactivity assays showed that Val1691Arg, Val1691Lys, and His1652Arg mutants are drastically reduced DUB/deISG activities compared to the wild-type. Overall, MERS-CoV PLpro mutants with alter kinetic profiles will be useful for discovery tools and DUB/deISG deficient mutants are great candidates for removing host cell antagonism activity by PLpro for live attenuated vaccines.</div><div><br></div><div>In Chapter 5, the goal is to translate the knowledge gained in Chapters 2-4 on beta-CoVs PLpro and evaluate the substrate specificity of alpha-CoVs FIPV and PEDV PLP2 for mutagenesis experiments. First, we design and purify the core PLP2 enzymes for kinetics. PLP2s are efficient DUBs that prefer Ub to ISG15 in vitro, and this preference is conserved in beta-CoV MHV PLP2 as well as alpha-CoV NL63 PLP2. We determine the structure of alpha-CoV PEDV PLP2 to 1.95 Å resolution and reveal the unique Zn-finger coordinating Cys3-His arrangement of the alpha-CoV genus that differs from past beta-CoV PLP crystal structures. To determine residues of the SUb1 site, we generate a homology model of FIPV PLP2 and overlay our PLP2 structures with MERS-CoV PLpro bound with Ub. In addition, we create electrostatic surface maps across coronaviral PLP subfamilies to evaluate the charge distribution of the SUb1 for the rational design of several FIPV and PEDV PLP2 mutants. We evaluate the turnover of PLP mutants for FRET-based substrates and reveal that His101ArgFIPV and Asn101ArgPEDV are drastically reduced in Ub-AMC activity while their peptide activities are within 2-fold of the wild-type. These mutants show delayed reactivity for Ub probes and no longer cleave Ub-chains displaying isopeptide bonds compared to the wild-type. Results from this study reveal a hot spot in both alpha- and beta-CoVs that can be used to selectively remove DUB activity of PLPs for generating a DUB deficient PLP enzyme. </div><div><br></div><div>In this dissertation, we investigate the substrate specificity of PLPs across alpha- and beta-CoVs and develop a fingerprint for Ub and also shed light on ISG15 recognition. Specifically, hot spots were identified in the SUb1 site of different PLPs, which recognize R42 and hydrophobic Ile44 of Ub. Position 97-98 of PLPs can be used to remove DUB activity by substituting an Arg, but usually effect protease function. Substituting an Arg at position 101 and 136 of coronaviral PLPs serve as the best strategy to remove DUB function while not hindering active site functionality. The DUB/deISG deficient mutants described will be useful for inhibiting the ability of PLPs to function in the innate immune response. Ultimately, this work provides a guide for identifying attenuating mutants in existing CoVs for live attenuated vaccines and also a blueprint for engineering PLPs from new emerging CoVs. </div>
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Insights on type I IFN signaling and regulation : studies of disease-associated TYK2 variants and of the negative regulators USP18/ISG15 / Signalisation et régulation de l'interféron de type I : études de variants de TYK2 associés à des maladies et des régulateurs négatifs USP18 et ISG15Li, Zhi 12 October 2017 (has links)
L'action ubiquitaire de l'interféron de type I (IFN- alpha/beta , ici IFN) dans la physiologie et la pathologie est aujourd'hui certaine. Une réponse dérégulée à l'IFN peut entraîner des interféronopathies ou des maladies auto-immunes. Dans mon travail de thèse j'ai étudié trois éléments de la voie de signalisation de l'IFN afin de comprendre comment une dérégulation peut se produire. TYK2 est une tyrosine kinase de la famille Janus impliquée dans la signalisation de cytokines immunorégulatrices (IFN de type I, IL-10, IL-12, IL-23). Selon le récepteur, TYK2 est co-activé avec JAK1 ou JAK2. L'interaction moléculaire entre les deux kinases juxtaposées est peu connue. J'ai caractérisé deux variants de TYK2 associés à des maladies auto-immunes, TYK2 I684S et TYK2 P1104A. J'ai démontré que ces deux variants ont un défaut catalytique, mais soutiennent la réponse à l'IFN. Mes résultats suggèrent un modèle d'activation réciproque des deux kinases. Par des études de signalisation dans les cellules EBV-B j'ai montré que l'homozygotie TYK2 P1104A a un impact différent selon la cytokine étudiée. L'analyse de deux autres polymorphismes de TYK2 associés à des maladies auto-immunes (rs12720270, rs2304256) a montré un impact sur la rétention de l'Exon 8, ce qui augmente l'expression de TYK2. J'ai aussi contribué à la dissection du mécanisme moléculaire contrôlant la réponse à l'IFN dans les cellules de patients déficients pour USP18 ou ISG15 et souffrant d'interféronopathies. Ces travaux ont démontré le rôle essentiel d'USP18 pour restreindre la réponse à l'IFN et ont mis en évidence ISG15 comme un nouvel inhibiteur de l'IFN chez l'humain mais pas chez la souris. / Today, the pervasive action of type I IFN (IFN-alpha/beta, here IFN) in human physiology and pathology has become evident. Dysregulated IFN response can lead to interferonopathies and auto-immune diseases (AID). My thesis work has focused on the study of three elements of the IFN response pathway, aiming to understand how dysregulation occurs. TYK2 belongs to the Janus tyrosine kinase family and is involved in signaling of several immunoregulatory cytokines, such as type I IFN, IL-10, IL-12 and IL-23. Depending on the receptor complex, TYK2 is co-activated with either JAK1 or JAK2. A detailed molecular characterization of the interplay between the two juxtaposed enzymes is missing. In my study, I characterized two rare AID-associated human variants TYK2 I684S and TYK2 P1104A. I found that both variants are catalytically impaired but rescue signaling in response to IFN in fibroblasts. My results support a model of reciprocal activation of Janus kinases. Through signaling studies I showed that TYK2 P1104A homozygosity has a cytokine-specific impact in EBV-B cells. My studies of two other AID-associated TYK2 SNPs (rs12720270 and rs2304256) suggest that they promote Exon 8 retention and increase TYK2 expression. In the second part of my thesis work, I contributed to dissecting the molecular mechanism that tunes down IFN response in cells from rare USP18- and ISG15-deficient patients that suffered of interferonopathies. This work substantiated the essential role of USP18 in downregulating the IFN response and highlighted ISG15 as a novel IFN inhibitor in humans, but not in mice.
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