Desenvolvimento de teste diagnóstico para a triagem sorológica de diversas infecções virais / Development of diagnostics for serological screening of various viral infections

Brand, Heike Erna

January 2014

Made available in DSpace on 2015-06-08T13:58:11Z (GMT). No. of bitstreams: 2 16.pdf: 27181026 bytes, checksum: 6dd85c661271ca63e8ec1eaa11f96d9b (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2014 / Fundação Oswaldo Cruz. Centro de Pesquisas Aggeu Magalhães. Recife, PE, Brasil / A leishmaniose visceral canina (LVC) e uma doença parasitária causada por protozoários do gênero Leishmania, principalmente por Leishmania infantum. A epidemiologia da doença varia de região para região e o entendimento dos fatores associados à infecção em cães pode ajudar na elaboração de medidas de controle mais específicas. O diagnóstico sorológico da infecção sofreu mudanças importantes nos últimos anos com a introdução do TR-DPP® e do estabelecimento de novos critérios de diagnóstico (TR-DPP® + EIE-LVC) pelo Ministério da Saúde. Dentro desse contexto, no presente estudo objetivou-se estudar a epidemiologia da LVC no município de Goiana, estado de Pernambuco, nordeste do Brasil. Para tal, realizaram-se testes sorológicos (TR-DPP® e EIE-LVC) e análise clínico-epidemiológica em 360 cães semi e domiciliados, de ambos os sexos, raças e idades variadas, nos distritos de Atapuz, Tejucupapo e Pontas de Pedra no referido município. No TR-DPP®47 (13,1 por cento) animais foram reagentes, onde se observou associação significativa dos resultados com os seguintes sinais clínicos: alopecia, lesões na pele paresia e linfonodomegalia. Já no EIE-LVC 21 (5,8 por cento) animais foram reagentes, havendo associação significativa entre a classificação clínica dos animais, condição corporal, alopecia, lesões na pele, secreção ocular, paresia e linfonodomegalia. Já de acordo com o critério do Ministério da Saúde do Brasil, apenas 15 (4,2 por cento) animais foram classificados como positivos. De fato, verificou-se uma fraca concordância (Kappa = 0,39) entre os dois testes sorológicos. Conclui-se que a LVC encontra-se estabelecida em Goiana e que o uso do TR-DPP® como teste de triagem e do EIE-LVC como teste confirmatório pode levar a perda de cães infectados, uma vez que cães positivos do TR-DPP® são negativos no EIE-LVC e vice-versa

Antígenos Virais/uso diagnóstico

Vacinas Sintéticas

Microesferas

ELISA

Western Blotting

Hepacivirus

HIV

Vírus 2 Linfotrópico T Humano

Toll-Like Receptors: Target of Hepatitis C Virus: A Dissertation

Chang, Serena Soyoung Yunmee

08 August 2008

Hepatitis C Virus (HCV) is the primary cause of liver transplantation due to its chronic nature in up to eighty percent of infected cases. Around 3 percent of the world’s population is infected with HCV. Treatment for HCV is a combined Ribavirin and interferon-α (IFN-α) therapy effective in only fifty to eighty percent of patients depending on HCV genotype. The growing health concern with this disease is the lack of a cure despite liver transplantation. HCV targets hepatocytes, liver cells, but is not cytolytic. HCV has been shown to induce end stage liver disease through sustained inflammation from the host’s immune system in the liver. One of the key dilemmas in HCV research and the search for fully effective treatments or vaccines is the lack of animal models. HCV infectivity and disease is limited to primates, most specifically to humans, which cannot be fully replicated in any other living being. The mechanisms for HCV evasion or activation of the immune system are complex, many and discoveries within this field are crucial to overcoming this destructive hepatic infection. Toll-like receptors (TLR) are cellular activators of the innate immune system that have been a target of HCV. Activated TLRs trigger both the inflammatory and anti-viral pathways to produce inflammatory cytokines and interferons. HCV proteins have been reported to activate a number of TLRs in a variety of cell types. In order to identify possible targets of HCV within the TLR family, we first characterized TLR presence and function in both human hepatic carcinoma cell lines and purified primary human hepatocytes. RNA from TLRs 1-10 was observed to varying degrees in both the hepatoma cell lines and the primary hepatocytes. We show the extracellular and/or intracellular presence of TLR2, TLR1, TLR3 and TLR7 proteins in hepatoma cell lines. TLR3 and TLR7 are located within the endosome and recognize viral RNA products. We recently reported that TLR2-mediated innate immune signaling pathways are activated by HCV core and NS3 proteins. TLR2 activation requires homo- or heterodimerization with either TLR1 or TLR6. We show NF-κB activation in hepatoma cells by TLR2/1, TLR2/6 ligand and HCV protein stimulation. In primary hepatocytes, HCV proteins induced both IL-8 and IL-6 production. We also show that primary hepatocytes initiate a Type 1 IFN response in addition to IL-8 and IL-6 production upon stimulation with a TLR7/8 ligand. Human hepatoma and primary hepatocytes are responsive to TLR2, TLR1, TLR6, TLR7/8 ligands and HCV proteins. Activation of these TLRs may contribute to the inflammatory mediated destruction caused by HCV or could be targets of HCV contributing to its immune evasion. We found previously that hepatoma cells and primary hepatocytes are responsive to TLR2 ligands and HCV proteins. We also reported that TLR2 is activated by HCV proteins. Here we aimed to determine whether TLR2 coreceptors participated in cellular activation by HCV core or NS3 proteins. By designing siRNAs targeted to TLR2, TLR1 and TLR6, we showed that knockdown of each of these receptors impairs pro- and anti-inflammatory cytokine activation by TLR-specific ligands as well as by HCV core and NS3 proteins in Human Embryonic Kidney cells (HEK/TLR2) and in primary human macrophages. We found that HCV core and NS3 proteins induced TNF-α and IL-10 production in human monocyte-derived macrophages, which was impaired by TLR2, TLR1 and TLR6 knockdown. Contrary to human data, results from TLR2, TLR1 or TLR6 knockout mice indicated that the absence of TLR2 and its coreceptor TLR6, but not TLR1, prevented the HCV core and NS3 protein-induced peritoneal macrophage activation. TLR2 may utilize both TLR1 and TLR6 coreceptors for HCV core- and NS3-mediated activation of macrophages and innate immunity in humans. These results imply that multiple pattern recognition receptors could participate in cellular activation by HCV proteins contributing to inflammatory disease. Two critical factors in chronic HCV infection are inflammatory disease and immune evasion. We have demonstrated that TLR2 and its co-receptors play a role in inflammatory-mediated induction via HCV NS3 and core administration. It has recently been shown that HCV targets the TLR3 pathway to aid in immune evasion. TLR3 is only one of four viral recognition receptors located within the endosome and it is plausible that HCV may target others. We hypothesized that HCV infection may interfere with the expression and function of TLR7, a sensor of single stranded RNA. Investigating any effect on TLR7 by HCV may reveal a new mechanism for HCV immune evasion. Low levels of both TLR7 mRNA and protein were measured in HCV replicating cells compared to control cells while reducing HCV infection with either IFNα or restrictive culture conditions restored the decreased TLR7 expression. Downstream of the TLR7 pathway, an increased baseline IRF7 nuclear translocation was observed in HCV replicating cells compared to controls. Stimulation with a TLR7 ligand, R837, resulted in significant IRF7 nuclear translocation in control cells. In contrast, HCV replicating cells showed impaired IRF7 activation. Use of RNA polymerase inhibitors on hepatoma cells, control and HCV replicating, revealed a shorter TLR7 half life in HCV replicating cells compared to control cells which was not seen in TLR5 mRNA. These data suggest that reduced TLR7 expression, due to RNA instability, directly correlates with HCV replication and results in impaired TLR7-induced IRF7-mediated cell activation. In conclusion, Hepatitis C Virus manipulates specific Toll-like receptors’ expression and their signaling pathways to induce cytokine production. HCV utilizes surface receptors TLR2 and its co-receptors which once activated could contribute to inflammatory disease by production of inflammatory cytokines and possibly immune evasion. HCV down-regulates TLR7, a viral recognition receptor, by decreasing mRNA stability which could facilitate evasion of host immune surveillance.

Hepacivirus

Toll-Like Receptor 1

Toll-Like Receptor 2

Toll-Like Receptor 6

Toll-Like Receptor 7

Hepatitis C

Digestive System

Digestive System Diseases

Hemic and Immune Systems

Surgical Procedures, Operative

Therapeutics

Virus Diseases

Viruses

Understanding Drug Resistance and Antibody Neutralization Escape in Antivirals: A Dissertation

Prachanronarong, Kristina L.

06 April 2016

Antiviral drug resistance is a major problem in the treatment of viral infections, including influenza and hepatitis C virus (HCV). Influenza neuraminidase (NA) is a viral sialidase on the surface of the influenza virion and a primary antiviral target in influenza. Two subtypes of NA predominate in humans, N1 and N2, but different patterns of drug resistance have emerged in each subtype. To provide a framework for understanding the structural basis of subtype specific drug resistance mutations in NA, we used molecular dynamics simulations to define dynamic substrate envelopes for NA to determine how different patterns of drug resistance have emerged in N1 and N2 NA. Furthermore, we used the substrate envelope to analyze HCV NS3/4A protease inhibitors in clinical development. In addition, influenza hemagglutinin (HA) is a primary target of neutralizing antibodies against influenza. Novel broadly neutralizing antibodies (BnAbs) against the stem region of HA have been described and inhibit several influenza viral subtypes, but antibody neutralization escape mutations have emerged. We identified potential escape mutations in broadly neutralizing antibody F10 that may impact protein dynamics in HA that are critical for function. We also solved crystal structures of antibody fragments that are important for understanding the structural basis of antibody binding for influenza BnAbs. These studies can inform the design of improved therapeutic strategies against viruses by incorporating an understanding of structural elements that are critical for function, such as substrate processing and protein dynamics, into the development of novel therapeutics that are robust against resistance.

drug resistance

antibody neutralization

antivirals

influenza

Dissertations, UMMS

Antibodies, Neutralizing

Antiviral Agents

Drug Resistance, Viral

Hemagglutinins

Hepacivirus

Influenza, Human

Neuraminidase

Molecular Dynamics Simulation

Protease Inhibitors

Biochemistry

Biophysics

Cellular and Molecular Physiology

Immunoprophylaxis and Therapy

Pharmacology

Structural Biology

Virology

Virus Diseases

Viral Proteases as Drug Targets and the Mechanisms of Drug Resistance: A Dissertation

Lin, Kuan-Hung

01 September 2016

Viral proteases have been shown to be effective targets of anti-viral therapies for human immunodeficiency virus (HIV) and hepatitis C virus (HCV). However, under the pressure of therapy including protease inhibitors, the virus evolves to select drug resistance mutations both in the protease and substrates. In my thesis study, I aimed to understand the mechanisms of how this protease−substrate co-evolution contributes to drug resistance. Currently, there are no approved drugs against dengue virus (DENV); I investigated substrate recognition by DENV protease and designed cyclic peptides as inhibitors targeting the prime site of dengue protease. First, I used X-ray crystallography and subsequent structural analysis to investigate the molecular basis of HIV-1 protease and p1-p6 substrate coevolution. I found that co-evolved p1-p6 substrates rescue the HIV-1 I50V protease’s binding activity by forming more van der Waals contacts and hydrogen bonds, and that co-evolution restores the dynamics at the active site for all three mutant substrates. Next, I used aprotinin as a platform to investigate DENV protease–substrate recognizing pattern, which revealed that the prime side residues significantly modulate substrate affinity to protease and the optimal interactions at each residue position. Based on these results, I designed cyclic peptide inhibitors that target the prime site pocket of DENV protease. Through optimizing the length and sequence, the best inhibitor achieved a 2.9 micromolar Ki value against DENV3 protease. Since dengue protease does not share substrate sequence with human serine proteases, these cyclic peptides can be used as scaffolds for inhibitor design with higher specificity.

Dengue Virus

Viral Drug Resistance

Hepacivirus

HIV Infections

HIV Protease

Dissertations, UMMS

Drug Resistance, Viral

Biochemistry

Cellular and Molecular Physiology

Enzymes and Coenzymes

Immunoprophylaxis and Therapy

Pharmacology

Structural Biology

Virology

Virus Diseases

Mechanisms of Substrate Recognition by HCV NS3/4A Protease Provide Insights Into Drug Resistance: A Dissertation

Romano, Keith P.

31 May 2011

HCV afflicts many millions of people globally, and antiviral therapies are often ineffective and intolerable. The Food and Drug Administration approved the HCV protease inhibitors telaprevir and boceprevir in May 2011, marking an important milestone in anti-HCV research over the past two decades. Nevertheless, severe drug side effects of combination therapy – flu-like symptoms, depression and anemia – limit patient adherence to treatment regimens. The acquisition of resistance challenges the long-term efficacy of antiviral therapies, including protease inhibitors, as suboptimal dosing allows for the selection of drug resistant viral variants. A better understanding of the molecular basis of drug resistance is therefore central to developing future generation protease inhibitors that retain potency against a broader spectrum of HCV strains. To this end, my research characterizes the molecular basis of drug resistance against HCV protease inhibitors. Chapter II defines the mode of substrate recognition by the common volume shared by NS3/4A substrate products – the substrate envelope. Chapter III then correlates patterns of drug resistance to regions where drugs protrude from the substrate envelope. Lastly, Chapter IV elucidates the molecular underpinnings of resistance against four leading protease inhibitors – telaprevir, danoprevir, vaniprevir and MK-5172 – and provides practical approaches to designing novel drugs that are less susceptible to resistance. I ultimately hope my work appeals to the broader biomedical community of virologists, medicinal chemists and clinicians, who struggle to understand HCV and other human pathogens in the face of rapid disease evolution.

Drug Resistance

Viral

Hepacivirus

Viral Nonstructural Proteins

Protease Inhibitors

Amino Acids, Peptides, and Proteins

Chemical Actions and Uses

Digestive System Diseases

Pharmaceutical Preparations

Therapeutics

Virology

Virus Diseases

Viruses