Your search keyword '"Rachel Huddart"' showing total 15 results

1. PGxMine: Text Mining for Curation of PharmGKB.

Author

Jake Lever, Julia M. Barbarino, Li Gong, Rachel Huddart, Katrin Sangkuhl, Ryan Whaley, Michelle Whirl Carrillo, Mark Woon, Teri E. Klein, and Russ B. Altman

Published

2020

2. PharmGKB summary: heparin-induced thrombocytopenia pathway, adverse drug reaction

Author

Elise Miller, Charles Norwood, Jason B. Giles, Rachel Huddart, Jason H. Karnes, Michelle Whirl-Carrillo, and Teri E. Klein

Subjects

Drug-Related Side Effects and Adverse Reactions, Heparin, Genetics, Anticoagulants, Humans, Molecular Medicine, General Pharmacology, Toxicology and Pharmaceutics, Thrombocytopenia, Molecular Biology, Article, Genetics (clinical)

Published

2022

3. An Evidence‐Based Framework for Evaluating Pharmacogenomics Knowledge for Personalized Medicine

Author

Michelle Whirl-Carrillo, Katrin Sangkuhl, Teri E. Klein, Caroline F. Thorn, Rachel Huddart, Ryan Whaley, and Li Gong

Subjects

Pharmacology, Prescription Drugs, Information retrieval, PharmGKB, Evidence-based practice, Standardization, Computer science, business.industry, Knowledge Bases, Reproducibility of Results, White Paper, Reviews, Evidence-based medicine, Drug Prescriptions, Annotation, Consistency (database systems), Pharmacogenetics, Pharmacogenomics, Databases, Genetic, Humans, Pharmacology (medical), Personalized medicine, Precision Medicine, business, Drug Labeling

Abstract

Clinical annotations are one of the most popular resources available on the Pharmacogenomics Knowledgebase (PharmGKB). Each clinical annotation summarizes the association between variant‐drug pairs, shows relevant findings from the curated literature, and is assigned a level of evidence (LOE) to indicate the strength of support for that association. Evidence from the pharmacogenomic literature is curated into PharmGKB as variant annotations, which can be used to create new clinical annotations or added to existing clinical annotations. This means that the same clinical annotation can be worked on by multiple curators over time. As more evidence is curated into PharmGKB, the task of maintaining consistency when assessing all the available evidence and assigning an LOE becomes increasingly difficult. To remedy this, a scoring system has been developed to automate LOE assignment to clinical annotations. Variant annotations are scored according to certain attributes, including study size, reported P value, and whether the variant annotation supports or fails to find an association. Clinical guidelines or US Food and Drug Administration (FDA)‐approved drug labels which give variant‐specific prescribing guidance are also scored. The scores of all annotations attached to a clinical annotation are summed together to give a total score for the clinical annotation, which is used to calculate an LOE. Overall, the system increases transparency, consistency, and reproducibility in LOE assignment to clinical annotations. In combination with increased standardization of how clinical annotations are written, use of this scoring system helps to ensure that PharmGKB clinical annotations continue to be a robust source of pharmacogenomic information.

Published

2021

4. Clinical Pharmacogenetics Implementation Consortium Guideline for CYP2D6 , OPRM1 , and COMT Genotypes and Select Opioid Therapy

Author

Caroline Flora Samer, Larisa H. Cavallari, Andrew A. Monte, Andrew A. Somogyi, Rachel Huddart, Evan D. Kharasch, Kelly E. Caudle, Gualberto Ruaño, J. Steven Leeder, Andrea Gaedigk, Sara L. Van Driest, Cynthia A. Prows, Kristine R. Crews, Teri E. Klein, Todd C. Skaar, Henry M. Dunnenberger, Cyrine E. Haidar, Daniel J. Müller, John T. Callaghan, Mohamed Nagy, and Katrin Sangkuhl

Subjects

medicine.medical_specialty, Genotype, Pharmacogenomic Variants, Receptors, Opioid, mu, Pain, Catechol O-Methyltransferase, digestive system, 030226 pharmacology & pharmacy, Article, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, medicine, Humans, Pharmacology (medical), skin and connective tissue diseases, Pharmacology, ddc:617, business.industry, Codeine, Guideline, Pharmacogenomic Testing, Analgesics, Opioid, Cytochrome P-450 CYP2D6, Hydrocodone, Opioid, 030220 oncology & carcinogenesis, Tramadol, business, Oxycodone, Pharmacogenetics, medicine.drug, Methadone

Abstract

Opioids are mainly used to treat both acute and chronic pain. Several opioids are metabolized to some extent by CYP2D6 (codeine, tramadol, hydrocodone, oxycodone, and methadone). Polymorphisms in CYP2D6 have been studied for an association with the clinical effect and safety of these drugs. Other genes that have been studied for their association with opioid clinical effect or adverse events include OPRM1 (mu receptor) and COMT (catechol-O-methyltransferase). This guideline updates and expands the 2014 Clinical Pharmacogenetics Implementation Consortium (CPIC) guideline for CYP2D6 genotype and codeine therapy and includes a summation of the evidence describing the impact of CYP2D6, OPRM1, and COMT on opioid analgesia and adverse events. We provide therapeutic recommendations for the use of CYP2D6 genotype results for prescribing codeine and tramadol and describe the limited and/or weak data for CYP2D6 and hydrocodone, oxycodone, and methadone, and for OPRM1 and COMT for clinical use.

Published

2021

5. Pharmacogenomics in dermatology: tools for understanding gene-drug associations

Author

Russ B. Altman, Teri E. Klein, Roxana Daneshjou, and Rachel Huddart

Subjects

Drug, medicine.medical_specialty, Databases, Factual, Drug-Related Side Effects and Adverse Reactions, business.industry, media_common.quotation_subject, Genetic data, Dermatology, Skin Diseases, Article, Clinical Practice, Drug treatment, Knowledge base, Pharmacogenetics, Pharmacogenomics, Health care, medicine, Humans, Surgery, Dermatologic Agents, Precision Medicine, business, media_common

Abstract

Pharmacogenomics aims to associate human genetic variability with differences in drug phenotypes in order to tailor drug treatment to individual patients. The massive amount of genetic data generated from large cohorts of patients with variable drug phenotypes have led to advances in this field. Understanding the application of pharmacogenomics in dermatology could inform clinical practice and provide insight for future research. The Pharmacogenomics Knowledge Base and the Clinical Pharmacogenetics Implementation Consortium are among the resources to help clinicians and researchers navigate the many gene-drug associations that have already been discovered. The implementation of clinical pharmacogenomics within health care systems remains an area of ongoing development. This review provides an introduction to the field of pharmacogenomics and to current pharmacogenomics resources using examples of gene-drug associations relevant to the field of dermatology.

Published

2019

6. Clinical Pharmacogenetics Implementation Consortium Guideline for the Use of Aminoglycosides Based on MT-RNR1 Genotype

Author

Cristina Rodríguez-Antona, Rachel Huddart, Keito Hoshitsuki, Teri E. Klein, Richard J.H. Smith, Joshua Wolf, Michelle Whirl-Carrillo, William G. Newman, Kelly E. Caudle, John H McDermott, Peter S. Steyger, and Neal Cody

Subjects

Genotype, Pharmacogenomic Variants, medicine.drug_class, Hearing loss, Hearing Loss, Sensorineural, Antibiotics, Clinical Decision-Making, MT-RNR1, Bioinformatics, 030226 pharmacology & pharmacy, Risk Assessment, Article, 03 medical and health sciences, 0302 clinical medicine, Predictive Value of Tests, Risk Factors, medicine, Humans, Pharmacology (medical), Gene, Pharmacology, business.industry, Guideline, medicine.disease, Anti-Bacterial Agents/adverse effects, Ototoxicity, Aminoglycosides/adverse effects, RNA, Ribosomal/genetics, Anti-Bacterial Agents, Pharmacogenomic Testing, Hearing Loss, Sensorineural/chemically induced, Aminoglycosides, Pharmacogenetics, RNA, Ribosomal, 030220 oncology & carcinogenesis, Sensorineural hearing loss, Patient Safety, medicine.symptom, business

Abstract

Aminoglycosides are widely used antibiotics with notable side effects such as nephrotoxicity, vestibulotoxicity and sensorineural hearing loss (cochleotoxicity). MT-RNR1 is a gene that encodes the 12s rRNA subunit and is the mitochondrial homologue of the prokaryotic 16s rRNA. Some MT-RNR1 variants (i.e., m.1095T>C; m.1494C>T; m.1555A>G) more closely resemble the bacterial 16s rRNA subunit and result in increased risk of aminoglycoside-induced hearing loss. Use of aminoglycosides should be avoided in individuals with an MT-RNR1 variant associated with an increased risk of aminoglycoside-induced hearing loss unless the high risk of permanent hearing loss is outweighed by the severity of infection and safe or effective alternative therapies are not available. We summarize evidence from the literature supporting this association and provide therapeutic recommendations for the use of aminoglycosides based on MT-RNR1 genotype (updates at https://cpicpgx.org/guidelines/ and www.pharmgkb.org).

Published

2021

7. PharmGKB Tutorial for Pharmacogenomics of Drugs Potentially Used in the Context of COVID-19

Author

Teri E. Klein, Russ B. Altman, Rachel Huddart, and Michelle Whirl-Carrillo

Subjects

2019-20 coronavirus outbreak, PharmGKB, Coronavirus disease 2019 (COVID-19), Computer science, Medication Therapy Management, Knowledge Bases, coronavirus, Context (language use), Scientific literature, 030226 pharmacology & pharmacy, Antiviral Agents, SARS‐CoV‐2, World Wide Web, 03 medical and health sciences, 0302 clinical medicine, COVID‐19, Tutorial, Humans, Pharmacology (medical), Precision Medicine, Pharmacology, pharmacogenomics, COVID-19, Precision medicine, Pharmacogenomic Testing, COVID-19 Drug Treatment, Gene Ontology, Pharmacogenetics, 030220 oncology & carcinogenesis, Pharmacogenomics, Healthcare system

Abstract

Pharmacogenomics (PGx) is a key area of precision medicine, which is already being implemented in some health systems and may help guide clinicians toward effective therapies for individual patients. Over the last 2 decades, the Pharmacogenomics Knowledgebase (PharmGKB) has built a unique repository of PGx knowledge, including annotations of clinical guideline and regulator-approved drug labels in addition to evidence-based drug pathways and annotations of the scientific literature. All of this knowledge is freely accessible on the PharmGKB website. In the first of a series of PharmGKB tutorials, we introduce the PharmGKB coronavirus disease 2019 (COVID-19) portal and, using examples of drugs found in the portal, demonstrate some of the main features of PharmGKB. This paper is intended as a resource to help users become quickly acquainted with the wealth of information stored in PharmGKB.

Published

2020

8. PharmGKB summary

Author

Rachel Huddart, Melissa Clarke, Russ B. Altman, and Teri E. Klein

Subjects

PharmGKB, MEDLINE, Bioinformatics, 030226 pharmacology & pharmacy, Article, 03 medical and health sciences, 0302 clinical medicine, Pharmacokinetics, Genetics, medicine, Humans, General Pharmacology, Toxicology and Pharmaceutics, Molecular Biology, Genetics (clinical), Extramural, business.industry, Analgesics, Opioid, Pharmacogenetics, Molecular Medicine, business, Oxycodone, Metabolic Networks and Pathways, 030217 neurology & neurosurgery, medicine.drug

Published

2018

9. Are Randomized Controlled Trials Necessary to Establish the Value of Implementing Pharmacogenomics in the Clinic?

Author

Rachel Huddart, Michelle Whirl-Carrillo, Katrin Sangkuhl, and Teri E. Klein

Subjects

Pharmacology, medicine.medical_specialty, Drug-Related Side Effects and Adverse Reactions, Pharmacogenomic Variants, business.industry, Drug Resistance, Article, law.invention, Randomized controlled trial, Pharmacogenetics, law, Pharmacogenomics, Humans, Medicine, Pharmacology (medical), Medical physics, Precision Medicine, business, Value (mathematics), Randomized Controlled Trials as Topic

Published

2019

10. PharmGKB summary: sertraline pathway, pharmacokinetics

Author

Rachel Huddart, J. Kevin Hicks, Russ B. Altman, D. Max Smith, Margarita Bobonis Babilonia, Jeffrey R. Strawn, Teri E. Klein, and Laura B. Ramsey

Subjects

Pharmacogenomic Variants, Serotonin reuptake inhibitor, Pharmacology, Article, Sertraline, Genetics, medicine, Humans, Drug Interactions, General Pharmacology, Toxicology and Pharmaceutics, Molecular Biology, Genetics (clinical), chemistry.chemical_classification, business.industry, Mental Disorders, Social anxiety, Panic, medicine.disease, Toxic epidermal necrolysis, chemistry, Molecular Medicine, Antidepressant, Major depressive disorder, medicine.symptom, business, Selective Serotonin Reuptake Inhibitors, medicine.drug, Tricyclic, Signal Transduction

Abstract

Sertraline, a selective serotonin reuptake inhibitor (SSRI), is commonly prescribed to treat several psychiatric disorders including major depressive disorder, panic, generalized and social anxiety disorders as well as obsessive-compulsive disorder (OCD) [1]. It has similar efficacy to other SSRIs and is considered to cause fewer side effects than some antidepressants, such as tricyclic antidepressants [2, 3]. However, sertraline-induced adverse events such as reversible hepatic injury and Stevens Johnson Syndrome/toxic epidermal necrolysis (SJS/TEN) have been reported [4, 5]. Sertraline is a secondary amine with two chiral centers [6–9]. The potent cis-(1S,4S) enantiomer is used as an antidepressant in either a tablet or an oral solution [1, 7, 10], although the (1R,4R) enantiomer also inhibits serotonin reuptake [10].

Published

2019

11. PharmGKB summary: ondansetron and tropisetron pathways, pharmacokinetics and pharmacodynamics

Author

Rachel Huddart, Russ B. Altman, and Teri E. Klein

Subjects

Serotonin, PharmGKB, Tropisetron, Pharmacology, Article, Ondansetron, Pharmacokinetics, Cytochrome P-450 CYP1A2, Genetics, medicine, Humans, General Pharmacology, Toxicology and Pharmaceutics, Molecular Biology, Genetics (clinical), Extramural, business.industry, Serotonin metabolism, Cytochrome P-450 CYP2D6, Inactivation, Metabolic, Molecular Medicine, Serotonin Antagonists, Receptors, Serotonin, 5-HT3, business, Metabolic Networks and Pathways, medicine.drug

Published

2019

12. STrengthening the Reporting Of Pharmacogenetic Studies: Development of the STROPS guideline

Author

Marty Chaplin, Jamie J. Kirkham, Kerry Dwan, Derek J. Sloan, Geraint Davies, Andrea L. Jorgensen, Irma Aguilar-Delfín, José A G Agúndez, Sophie M Argon, M J Arranz, Derrick A Bennett, Stefan Böhringer, Lawrence Brody, Ingolf Cascorbi, Erika Cecchin, Mandy Crommentuijn-van Rhenen, Ann K Daly, Nur Aizati Athirah Daud, Jorge Duconge, Chiara Fabbri, Alison Fitches, Andrea Gaedigk, Donato Gemmati, Claudia Maria Dan Hawcutt, Rachel Huddart, Evelyne Jacqz-Aigrain, Slobodan M Janković, Theodora Katsila, Gideon Koren, Beata S Lipska-Ziętkiewicz, Thomas Liehr, A H Maitland-van der Zee, Lisanne E N Manson, Martin H Maurer, Juan Eduardo Megías-Vericat, Taichi Ochi, Daniel J O'Connor, Laura B Ramsey, Gad Rennert, Francesco Rucci, Gaetano Santulli, Aris Saoulidis, Rashmi R Shah, Alessandro Serretti, Andrew Somogyi, Gere Sunder-Plassmann, Virginia Boso-Ribelles, Caroline F Thorn, Evangelia Eirini Tsermpini, Satyanarayana Chakradhara Rao Uppugunduri, Michael A van Es, Magdalena Zarowiecki, University of St Andrews. School of Medicine, University of St Andrews. Infection and Global Health Division, Chaplin, Marty, Kirkham, Jamie J., Dwan, Kerry, Sloan, Derek J., Davies, Geraint, Jorgensen, Andrea L., Aguilar-Delfín, Irma, G Agúndez, José A, M Argon, Sophie, J Arranz, M, A Bennett, Derrick, Böhringer, Stefan, Brody, Lawrence, Cascorbi, Ingolf, Cecchin, Erika, Crommentuijn-van Rhenen, Mandy, K Daly, Ann, Aizati Athirah Daud, Nur, Duconge, Jorge, Fabbri, Chiara, Fitches, Alison, Gaedigk, Andrea, Gemmati, Donato, Maria Dan Hawcutt, Claudia, Huddart, Rachel, Jacqz-Aigrain, Evelyne, M Janković, Slobodan, Katsila, Theodora, Koren, Gideon, S Lipska-Ziętkiewicz, Beata, Liehr, Thoma, H Maitland-van der Zee, A, N Manson, Lisanne E, H Maurer, Martin, Eduardo Megías-Vericat, Juan, Ochi, Taichi, J O'Connor, Daniel, B Ramsey, Laura, Rennert, Gad, Rucci, Francesco, Santulli, Gaetano, Saoulidis, Ari, R Shah, Rashmi, Serretti, Alessandro, Somogyi, Andrew, Sunder-Plassmann, Gere, Boso-Ribelles, Virginia, F Thorn, Caroline, Eirini Tsermpini, Evangelia, Chakradhara Rao Uppugunduri, Satyanarayana, A van Es, Michael, and Zarowiecki, Magdalena

Subjects

Male, Delphi Technique, Delphi method, Surveys, 030204 cardiovascular system & hematology, Guidelines and Guidance, Mathematical and Statistical Techniques, 0302 clinical medicine, Surveys and Questionnaires, Medicine and Health Sciences, 030212 general & internal medicine, Statistics, Politics, Stakeholder, Genomics, General Medicine, Research Assessment, Metaanalysis, Middle Aged, Checklist, Systematic review, Research Design, Physical Sciences, Research Reporting Guidelines, Medicine, Engineering and Technology, Female, Goals, Biotechnology, Adult, RM, medicine.medical_specialty, Drug Research and Development, Consensus, Systematic Reviews, MEDLINE, Bioengineering, Research and Analysis Methods, 03 medical and health sciences, Genomic Medicine, Stakeholder Participation, Genetics, medicine, Humans, Statistical Methods, Genetic Association Studies, Pharmacology, Publishing, Survey Research, business.industry, Biology and Life Sciences, DAS, Guideline, United Kingdom, RM Therapeutics. Pharmacology, Pharmacogenomic Testing, Pharmacogenetics, Sample size determination, Family medicine, Pharmacogenomics, business, Mathematics

Abstract

Background Large sample sizes are often required to detect statistically significant associations between pharmacogenetic markers and treatment response. Meta-analysis may be performed to synthesize data from several studies, increasing sample size and, consequently, power to detect significant genetic effects. However, performing robust synthesis of data from pharmacogenetic studies is often challenging because of poor reporting of key data in study reports. There is currently no guideline for the reporting of pharmacogenetic studies that has been developed using a widely accepted robust methodology. The objective of this project was to develop the STrengthening the Reporting Of Pharmacogenetic Studies (STROPS) guideline. Methods and findings We established a preliminary checklist of reporting items to be considered for inclusion in the guideline. We invited representatives of key stakeholder groups to participate in a 2-round Delphi survey. A total of 52 individuals participated in both rounds of the survey, scoring items with regards to their importance for inclusion in the STROPS guideline. We then held a consensus meeting, at which 8 individuals considered the results of the Delphi survey and voted on whether each item ought to be included in the final guideline. The STROPS guideline consists of 54 items and is accompanied by an explanation and elaboration document. The guideline contains items that are particularly important in the field of pharmacogenetics, such as the drug regimen of interest and whether adherence to treatment was accounted for in the conducted analyses. The guideline also requires that outcomes be clearly defined and justified, because in pharmacogenetic studies, there may be a greater number of possible outcomes than in other types of study (for example, disease–gene association studies). A limitation of this project is that our consensus meeting involved a small number of individuals, the majority of whom are based in the United Kingdom. Conclusions Our aim is for the STROPS guideline to improve the transparency of reporting of pharmacogenetic studies and also to facilitate the conduct of high-quality systematic reviews and meta-analyses. We encourage authors to adhere to the STROPS guideline when publishing pharmacogenetic studies., Marty Chaplin and co-authors recount the development of a guideline for reporting pharmacogenetic studies.

Published

2020

13. Response to: Unveiling the guidance heterogeneity for genome-informed drug treatment interventions among regulatory bodies and research consortia

Author

Katrin Sangkuhl, Rachel Huddart, Kelly E. Caudle, Michelle Whirl-Carrillo, Caroline F. Thorn, Mary V. Relling, Teri E. Klein, and Li Gong

Subjects

Pharmacology, medicine.medical_specialty, Drug treatment, business.industry, medicine, Psychological intervention, Intensive care medicine, business, Genome

Published

2020

14. Standardized biogeographic grouping system for annotating populations in pharmacogenetic research

Author

Carlos Bustamante, Michelle Whirl-Carrillo, Alison E. Fohner, Rachel Huddart, Christopher R. Gignoux, Genevieve L. Wojcik, Alice B. Popejoy, Russ B. Altman, and Teri E. Klein

Subjects

PharmGKB, media_common.quotation_subject, Population, Geographic Mapping, Context (language use), 030226 pharmacology & pharmacy, Article, 03 medical and health sciences, 0302 clinical medicine, Gene Frequency, Population Groups, Genetic variation, Humans, Pharmacology (medical), Genetic variability, 1000 Genomes Project, Allele, 10. No inequality, education, Allele frequency, 030304 developmental biology, media_common, Pharmacology, 0303 health sciences, education.field_of_study, Genetic Variation, Classification, Pharmacogenomic Testing, Geography, Genetics, Population, Evolutionary biology, Pharmacogenetics, 030220 oncology & carcinogenesis, Pharmacogenomics, Genetic structure, Topography, Medical, Diversity (politics)

Abstract

The frequencies of pharmacogenetic alleles vary considerably between populations which has important implications for the impact of these alleles in different populations. However, current population grouping methods to communicate these patterns are insufficient as they are inconsistent and fail to reflect the distribution of genetic variability around the world. To facilitate and standardize the reporting of global variability in pharmacogenetic allele frequencies, we present nine broad biogeographical groups, defined by global autosomal genetic structure. These groups are based on data from large-scale initiatives, including the 1000 Genomes Project and the Human Genome Diversity Project, and reflect population genetic history, genetic distances between populations, and geographical proximity, with borders falling predominantly along national boundaries to simplify application of the grouping system. The geographically-defined groups are American, Central/South Asian, East Asian, European, Near Eastern, Oceanian, and Sub-Saharan African. Because of their distinct genetic patterns and frequent inclusion in published data, we also present two admixed groups: African American/Afro-Caribbean and Latino. Here, we characterize this population grouping system in the context of broad genomic data and present its utility for annotating pharmacogenetic studies and alleles. We recognize that broadly grouping global populations is an oversimplification of human diversity, does not capture complex social and cultural identity, and uses arbitrary geographic borders. However, this grouping method is consistent with robust population genetic patterns and meets a need of the pharmacogenetics field by enabling consistent communication of the scale of variability in global allele frequencies.

Published

2019

15. Novel Adenovirus-based vaccines induce broad and sustained T cell responses to HCV in man

Author

Leo Swadling, Richard D Antrobus, Ayako Kurioka, Eleanor Barnes, C Willberg, M. Naddeo, Stefano Colloca, Maria Luisa Esposito, Virginia Ammendola, Antonella Folgori, Kira Smith, Stephen Aston, Joel Meyer, Geraldine O'Hara, Loredana Siani, Fabiana Grazioli, Adrian V. S. Hill, Cinzia Traboni, Paul Klenerman, Stefania Capone, Anthony Brown, Alfredo Nicosia, Riccardo Cortese, Ye Oo, Abby Harrison, Rachel Townsend, Rachel Huddart, David H. Adams, E., Barne, A., Folgori, S., Capone, L., Swadling, S., Aston, A., Kurioka, J., Meyer, R., Huddart, K., Smith, R., Townsend, A., Brown, R., Antrobu, V., Ammendola, M., Naddeo, G., O’Hara, C., Willberg, A., Harrison, F., Grazioli, M. L., Esposito, L., Siani, C., Traboni, Y., Oo, D., Adam, A., Hill, S., Colloca, Nicosia, Alfredo, R., Cortese, and P., Klenerman

Subjects

Interleukin 2, CD4-Positive T-Lymphocytes, Viral Hepatitis Vaccines, EXPRESSION, Time Factors, Genotype, adenoviru, T cell, T-Lymphocytes, design, Heterologous, Hepacivirus, Biology, CD8-Positive T-Lymphocytes, Major histocompatibility complex, medicine.disease_cause, HEPATITIS-C VIRUS, Article, Viral vector, Adenoviridae, Interferon-gamma, vaccine, INFECTION, medicine, Humans, PROTECTION, SPONTANEOUS CLEARANCE, Cell Proliferation, Tumor Necrosis Factor-alpha, HEK 293 cells, MEMORY, PERSISTENCE, General Medicine, Virology, Hepatitis C, gene therapy, medicine.anatomical_structure, HEK293 Cells, Immunology, HCV, biology.protein, Leukocytes, Mononuclear, immune-response, Interleukin-2, CD8(+), CD8, medicine.drug

Abstract

Currently, no vaccine exists for hepatitis C virus (HCV), a major pathogen thought to infect 170 million people globally. Many studies suggest that host T cell responses are critical for spontaneous resolution of disease, and preclinical studies have indicated a requirement for T cells in protection against challenge. We aimed to elicit HCV-specific T cells with the potential for protection using a recombinant adenoviral vector strategy in a phase 1 study of healthy human volunteers. Two adenoviral vectors expressing NS proteins from HCV genotype 1B were constructed based on rare serotypes [human adenovirus 6 (Ad6) and chimpanzee adenovirus 3 (ChAd3)]. Both vectors primed T cell responses against HCV proteins; these T cell responses targeted multiple proteins and were capable of recognizing heterologous strains (genotypes 1A and 3A). HCV-specific T cells consisted of both CD4(+) and CD8(+) T cell subsets; secreted interleukin-2, interferon-gamma, and tumor necrosis factor-alpha; and could be sustained for at least a year after boosting with the heterologous adenoviral vector. Studies using major histocompatibility complex peptide tetramers revealed long-lived central and effector memory pools that retained polyfunctionality and proliferative capacity. These data indicate that an adenoviral vector strategy can induce sustained T cell responses of a magnitude and quality associated with protective immunity and open the way for studies of prophylactic and therapeutic vaccines for HCV.

Published

2012