Genotipagem do vírus da hepatite C por PCR em tempo real com base na análise da região NS5B / Genotyping of hepatitis C vírus by real time PCR based in analysis of NS5B region

Nakatani, Sueli Massumi

05 December 2008

A genotipagem do vírus da hepatite C (VHC) é a principal ferramenta para prognóstico e tempo de tratamento. Dependendo do genótipo infectado existem diferentes esquemas e tempo de tratamento. O objetivo deste trabalho foi desenvolver padronizar e validar um método de genotipagem por PCR em tempo real com base na análise da região NS5B. Esta região apresenta um grau de polimorfismo que permite identificar de modo mais acurado tanto os tipos como os subtipos do VHC. Para isto foram desenhados dois conjuntos de primers e sondas. Neste trabalho desenvolvemos um método one-step modificado em uma reação triplex em que ocorre a identificação dos genótipos (1a, 1b, 3a) e em outro set a identificação dos genótipos (2a, 2b, 2c). Os resultados obtidos pelo método de genotipagem em tempo real concordaram em 100% com os resultados de seqüênciamento da região NS5B quando excluímos amostras que foram identificados como mistura de genótipos no método desenvolvido e classificados somente como um único genótipo no seqüênciamento. Houve uma boa concordância entre o método desenvolvido e o seqüênciamento da região NS5B pelo coeficiente de Kappa (k= 0,6222; p=0,0020). O método de desenvolvido conseguiu detectar 97,93% (190/194) do genótipo 1, 86,11% (31/36) do genótipo 2 e 100% (80/80) do genótipo 3. A média da sensibilidade foi de 97%. Quando comparamos a genotipagem por PCR em tempo real e LiPA nas 310 amostras analisadas não houve resultados discordantes em relação ao genótipo. Entretanto, 26,24% (79/301) das amostras analisadas apresentaram resultados discordantes em relação ao subtipo quando comparados os dois métodos. Foi determinada a sensibilidade analítica do método através de um ponto do painel da OptiQuant que foi diluído de modo seriado e a sensibilidade relativa foi realizada através de amostras de plasma de pacientes com carga viral determinada pelo Cobas Amplicor. O limite mínimo de detecção determinado foi de 125UI/ml para o genótipo 3a, 250 UI/ml para o genótipo 1b e 2b e 500 UI/ml para o genótipo 1a. Somados a isso, o método desenvolvido tem um custo de R$ 58,00, um valor nove vezes menor que o método comercial utilizado em nosso laboratório. Além disso, no método desenvolvido, o tempo trabalhado cai para menos de 2 horas sem a necessidade de manipulação constante em comparação com LiPA que necessita em torno de 16 horas, devido ao vários passos de hibridizações e lavagens. No presente trabalho o método de genotipagem por PCR em tempo real para o VHC mostrou-se eficiente e capaz de identificar de um modo acurado os diferentes genótipos e seus subtipos e contribuir para um entendimento melhor do verdadeiro papel dos genótipos e seus subtipos e da variabilidade genética na história natural da infecção do VHC. / Hepatitis C virus (HCV) genotyping is the most significant predictor of response to antiviral therapy. Depending on the infecting HCV genotyping different antiviral regimens have been proposed as well as the length of different treatment. The aim of this study was to develop and evaluate a new real time PCR of HCV genotyping based in NS5B region. This region has sequencing heterogeneity and can accurately identify both type and subtype of HCV. Furthermore, we compared the real time PCR with LiPA and sequencing of NS5B region. We developed a new one-step modified method in triplex reaction where we identified in two sets genotypes (1a, 1b, 3a) and (2a, 2b, 2c). Results obtained by real time PCR agreed 100% with those obtained by NS5B sequencing when excluded samples with mixed of HCV genotypes identified by real time PCR genotyping and in NS5B sequencing all samples were classified only as only one genotype. We found a good concordance for the analysis of genotype concordance between genotyping by real time and sequencing of NS5B region through the coefficient kappa (k= 0,6222; p=0,0020). The method developed detected 97,93% (190/194) of genotype 1, 86,11% (31/36) of genotype 2 and 100% (80/80) of genotype 3, with the overall sensitivity of this new method being 97%. Among 310 samples only two samples had discordant results at type level when comparing real time PCR and LiPA. However, 26,24% (79/301) had discordant results at subtype level when comparing LiPA and real time PCR genotyping of HCV. In order to measure the analytical sensitivity of the real time assay, one member of the panel OptiQuant HCV RNA was diluted. The relative sensitivity was determined by analysis the clinical specimens based upon the initial HCV RNA concentration determined by Cobas Amplicor. The lower limit of detection was estimated to be 125 IU/ml for genotype 3a, 250 IU/ml for genotype 1b and 2b, and 500 IU/ml for genotype 1a. Finally, the cost of each reaction are about R$ 58,00 nine fold lower than the commercial method available in Brazil. Manipulation time of real time PCR genotyping is about 2 hours, in comparison to LiPA that requires about 16 hours due to various hybridization steps and washing. This study was demonstrated an efficient method of identification in a accurate way. HCV genotyping which is important to understand the role of genotypes and subtypes, as well as of genomic variability in the natural history of HCV infection.

Hepacivirus

Hepacivirus

Prognostic

Prognóstico

Study of Genes Relating To Degradation of Aromatic Compounds and Carbon Metabolism in Mycobacterium Sp. Strain KMS

Zhang, Chun

01 May 2013

Polycyclic aromatic hydrocarbons, produced by anthropological and natural activities, are hazardous through formation of oxidative radicals and DNA adducts. Growth of Mycobacterium sp. strain KMS, isolated from a contaminated soil, on the model hydrocarbon pyrene induced specific proteins. My work extends the study of isolate KMS to the gene level to understand the pathways and regulation of pyrene utilization. Genes encoding pyrene-induced proteins were clustered on a 72 kb section on the KMS chromosome but some also were duplicated on plasmids. Skewed GC content and presence of integrase and transposase genes suggested horizontal transfer of pyrene-degrading gene islands that also were found with high conservation in five other pyrene-degrading Mycobacterium isolates. Transcript analysis found both plasmid and chromosomal genes were induced by pyrene. These processes may enhance the survival of KMS in hydrocarbon-contaminated soils when other carbon sources are limited. KMS also grew on benzoate, confirming the functionality of an operon containing genes distinct from those in other benzoate-degrading bacteria. Growth on benzoate but not on pyrene induced a gene, benA, encoding a benzoate dioxygenase α-subunit, but not the pyrene-induced nidA encoding a pyrene dioxygenase α-subunit; the differential induction correlated with differences in promoter sequences. Diauxic growth occurred when pyrene cultures were amended with benzoate or acetate, succinate, or fructose, and paralleled delayed expression of nidA. Single phase growth and normal expression of benA was observed for benzoate single and mixed cultures. The nidA promoters had potential cAMP-CRP binding sites, suggesting that cAMP could be involved in carbon repression of pyrene metabolism. Growth on benzoate and pyrene requires gluconeogenesis. Intermediary metabolism in isolate KMS involves expression from genes encoding a novel malate:quinone oxidoreductase and glyoxylate shunt enzymes. Generation of C3 structures involves transcription of genes encoding malic enzyme, phosphoenolpyruvate carboxykinase, and phosphoenolpyruvate synthase. Carbon source modified the transcription patterns for these genes. My findings are the first to show duplication of pyrene-degrading genes on the chromosome and plasmids in Mycobacterium isolates and expression from a unique benzoate-degrading operon. I clarified the routes for intermediary metabolism leading to gluconeogenesis and established a potential role for cAMP-mediated catabolite repression of pyrene utilization.

Catabolite Repression

Gluconeogenesis

Mycobacterium sp. KMS

Polycyclic Aromatic Hydrocarbons

Reverse Transcriptase PCR

Ring-Hydroxylating Dioxygenase

Biology

Environmental Sciences

Microbiology

Structural determinants of murine leukemia virus reverse transcriptase that are important for template switching, fidelity, and drug-resistance

Svarovskaia, Evguenia S.

January 2000

Thesis (Ph. D.)--West Virginia University, 2000. / Title from document title page. Document formatted into pages; contains xi, 185 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references.

Detection of human coronavirus infections by reverse transcription PCRin children hospitalized with respiratory disease in Hong Kong

Kwan, See-wai, Grace., 關詩慧.

January 2005

published_or_final_version / Medical Sciences / Master / Master of Medical Sciences

Reverse transcriptase.

Evaluation of reverse transcriptase assay for viral load monitoring /

Corrigan, Gary E.,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 5 uppsatser.

Vascular endothelial growth factor in renal cell carcinoma /

Jacobsen, Jan,

January 2006

Diss. (sammanfattning) Umeå : Univ., 2006. / Härtill 5 uppsatser.

Diagnosing antiretroviral treatment failure in resource-limited settings

Cantrell, Ronald Alexander.

January 2008

Thesis (Ph. D.)--University of Alabama at Birmingham, 2008. / Title from first page of PDF file (viewed Sept. 16, 2008). Includes bibliographical references.

La particule ribonucléoprotéique de l'élément L1 humain : spécificité de l'activité transcriptase inverse et partenaires cellulaires / The ribonucleoprotein complex of the human L1 element : specificity of the reverse transcriptase activity and cellular partners

Monot, Clément

27 September 2013

Les éléments LINE-1 (L1) sont les seuls éléments transposables autonomes et actifs, constituant 20% de notre ADN. Ils prolifèrent via un intermédiaire ARN dans un processus appelé rétrotransposition. Les L1s encodent deux protéines, ORF1p et ORF2p, qui s’associent avec l’ARN du L1 pour former une particule ribonucléoprotéique (RNP), constituant l’intermédiaire fonctionnel de la rétrotransposition. Les L1s « sautent » activement dans les cellules germinales, les cellules souches embryonnaires et dans l’embryon précoce, conduisant occasionnellement à des maladies génétiques. Ils sont également exprimés et mobiles dans un certain nombre de cancers. Les sites d’intégration des L1s sont généralement considérés comme aléatoires, les déterminants moléculaires de leur insertion demeurant mal connus. Afin d’éclaircir ce processus, nous avons d’abord exploré les propriétés biochimiques des RNPs du L1, en mesurant leur activité transcriptase inverse in vitro sur une collection variée de substrats d’ADN. Nous avons observé que des substrats, qui diffèrent par leur séquence ou leur structure, ne sont pas tous utilisés efficacement par les RNPs du L1 pour amorcer la transcription inverse. Notre travail suggère que la spécificité et la flexibilité de l’initiation de la transcription inverse du L1 participe aux choix du site d’insertion. Dans un second temps, nous avons recherché des partenaires cellulaires de la RNP du L1 qui pourraient contribuer à la rétrotransposition et/ou la réguler, par des cribles double-hybride chez la levure. Nous avons découvert que la protéine ORF2p interagit avec un groupe de récepteurs nucléaires. Ces derniers possèdent un domaine de liaison à l’ADN qui reconnaît des séquences d’ADN spécifiques réparties dans le génome, et un domaine de liaison du ligand, qui permet d’activer la transcription des gènes cibles. Nos données suggèrent que ces facteurs participent à la rétrotransposition des L1s, possiblement en ciblant leurs RNPs dans certaines régions du génome. Dans leur ensemble, nos travaux ont contribué à améliorer notre compréhension de la relation entre éléments transposables et génome hôte, et de leur impact sur la plasticité du génome humain. / LINE-1 (L1) elements are mobile genetic elements, comprising up to 20% of the contemporary human genome, in which they are the only autonomously active element. They replicate through an RNA intermediate in a process named retrotransposition. Replication-competent L1 copies code for two proteins, ORF1p and ORF2p, that associate in cis with their own RNA to form a ribonucleoprotein complex (RNP), the functional intermediate of retrotransposition. L1s « jump » actively in germ cells, embryonic stem cells and in the early embryo, leading occasionally to genetic diseases. These elements are also expressed and mobile in a number of cancers. L1 insertion sites are generally considered as random. The molecular determinants of L1 insertion, as well as many steps of the retrotransposition cycle, remain uncertain. To get further insight in the molecular mechanisms of L1 retrotransposition, we first explored the biochemical properties of the L1 RNP, by measuring their reverse transcriptase activity in vitro on various DNA substrates. Using this approach, we observed that L1 RNPs do not equally extend DNA substrates, which differ in sequence or structure, to initiate cDNA synthesis. Our work suggests that the specificity and flexibility of L1 reverse transcription priming contribute to the choice of target sites. In a second approach, we performed yeast two-hybrid screens in order to discover cellular partners of the L1 RNP, which could contribute and/or regulate retrotransposition, We found that ORF2p interacts with a group of nuclear receptors. These proteins contain a DNA binding domain, which recognizes specific DNA sequences spread in the genome, and a ligand binding domain, driving transcriptional regulation of target genes. Our data suggest that these factors participate to L1 retrotransposition, potentially by tethering L1 RNPs to specific genomic regions. Altogether, this work has contributed to a better understanding of the relationship between mobile genetic elements and their host genome, and their impact on human genome plasticity.

Rétrotransposition

Transcriptase inverse

Intégration

Récepteurs nucléaires

Ciblage chromatinien

Retrotransposition

Reverse transcriptase

Integration

Nuclear receptor

Targetting to chromatin

Mécanismes moléculaires de la rétrotransposition de l'élément L1 humain / Molecular mechanisms of human L1 retrotransposition

Viollet, Sébastien

19 December 2014

L’élément L1 (Long Interspersed Nuclear Element 1 ou L1) est le seul rétrotransposon autonome et actif connu dans notre génome, représentant 17% de celui-ci. Capable de se répliquer grâce à un intermédiaire à ARN et un mécanisme de transcription inverse initiée au site d’intégration, il encode deux protéines ORF1p et ORF2p, qui s’associent à l’ARN L1 pour former une particule ribonucléoprotéique (RNP). L’élément L1 rétrotranspose préférentiellement en cis : un L1 défectif est complémenté en trans par un élément fonctionnel de façon inefficace. Ce travail s'intéresse à deux étapes clefs du cycle réplicatif du L1 : l'assemblage de la RNP L1 en cis ou en trans afin d’explorer le mécanisme de la cis-préférence et la spécificité de l’initiation de la reverse transcription initiée. Nous avons d’abord comparé deux méthodes d’analyse de l’activité RT. Puis, nous avons montré l’importance de la complémentarité entre queue poly(A) de l’ARN L1 et site d’intégration durant l’initiation de la RT, ainsi que l’impact de mésappariements terminaux éventuels. Enfin, nous avons étudié les bases biochimiques de la cis-préférence, à travers la coexpression et la purification de deux éléments distincts étiquetés, ce qui nous a permis de suivre l'assemblage et l'activité de leurs RNPs respectives. Nos données suggèrent que ORF1p et ORF2p peuvent lier en trans l’ARN L1 de façon efficace et que la cis-préférence pourrait nécessiter des quantités limitantes de L1. / The Long Interspersed Nuclear Element 1 (LINE-1 ou L1) is the only known active and autonomous retrotransposon in the human genome and constitutes around 17% of our genomic DNA. The L1 element is able to replicate through an RNA intermediate by a mechanism called target-primed reverse transcription and encodes two proteins ORF1p and ORF2p, which associate with the L1 RNA to form a ribonucleoprotein particle (RNP). L1 preferentially retrotranspose in cis: a defective L1 can only be rescued in trans at low levels by a replication-competent copy. During this work, we focused on two essential steps of the L1 replication cycle: the assembly of the L1 RNP in cis or in trans to explore the mechanism of the cis-preference and the specificity of L1 reverse transcription priming. First, we compared two different methods to detect L1 RT activity. Then, we showed the importance of base-pairing between the poly(A) tail of the L1 RNA and the integration site to prime reverse transcription and the impact of potential mismatches. Finally, we investigated the biochemical basis of the cis-preference through the coexpression and purification of two different tagged L1 elements, which allowed us to follow the assembly and activity of their RNP. Our data suggest that binding of ORF1p and ORF2p in trans is efficient and that the cis-preference might requires limiting L1 levels.

Rétrotransposon LINE-1

Particule ribonucléoprotéique

Rétrotransposition

Cis-préférence

Transcriptase inverse

LINE-1 Retrotransposon

Ribonucleoprotein particle

Retrotransposition

Cis-preference

Reverse transcriptase

Exploring the Telomeric Repeat Addition Processivity of Vertebrate Telomerase

January 2010

abstract: Telomerase is a special reverse transcriptase that extends the linear chromosome termini in eukaryotes. Telomerase is also a unique ribonucleoprotein complex which is composed of the protein component called Telomerase Reverse Transcriptase (TERT) and a telomerase RNA component (TR). The enzyme from most vertebrate species is able to utilize a short template sequence within TR to synthesize a long stretch of telomeric DNA, an ability termed "repeat addition processivity". By using human telomerase reconstituted both in vitro (Rabbit Reticulocyte Lysate) and in vivo (293FT cells), I have demonstrated that a conserved motif in the reverse transcriptase domain of the telomerase protein is crucial for telomerase repeat addition processivity and rate. Furthermore, I have designed a "template-free" telomerase to show that RNA/DNA duplex binding is a critical step for telomere repeat synthesis. In an attempt to expand the understanding of vertebrate telomerase, I have studied RNA-protein interactions of telomerase from teleost fish. The teleost fish telomerase RNA (TR) is by far the smallest vertebrate TR identified, providing a valuable model for structural research. / Dissertation/Thesis / Ph.D. Biochemistry 2010

Chemistry, Biochemistry

Biology, Molecular

biochemistry

molecular biology

motif 3

repeat addition processivity

reverse transcriptase

RNA/DNA duplex