Accurate Genetic Detection of Hepatitis C Virus Transmissions in Outbreak Settings.

David S Campo,Ha-Jung Roh,Amanda Sue,Zoya Dimitrova,Inna Rytsareva,Yury Khudyakov,Lilia Ganova-Raeva,Seth Sims,Sumathi Ramachandran,Joseph C Forbi,Yulin Lin,Michael A Purdy,Guo-Liang Xia,Hong Thai,Lili Punkova,Gilberto Vaughan,Pavel Skums

doi:10.1093/infdis/jiv542

David S Campo, Ha-Jung Roh + Show 15 more

Open Access

https://doi.org/10.1093/infdis/jiv542

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Abstract

Hepatitis C is a major public health problem in the United States and worldwide. Outbreaks of hepatitis C virus (HCV) infections are associated with unsafe injection practices, drug diversion, and other exposures to blood and are difficult to detect and investigate. Here, we developed and validated a simple approach for molecular detection of HCV transmissions in outbreak settings. We obtained sequences from the HCV hypervariable region 1 (HVR1), using end-point limiting-dilution (EPLD) technique, from 127 cases involved in 32 epidemiologically defined HCV outbreaks and 193 individuals with unrelated HCV strains. We compared several types of genetic distances and calculated a threshold, using minimal Hamming distances, that identifies transmission clusters in all tested outbreaks with 100% accuracy. The approach was also validated on sequences obtained using next-generation sequencing from HCV strains recovered from 239 individuals, and findings showed the same accuracy as that for EPLD. On average, the nucleotide diversity of the intrahost population was 6.2 times greater in the source case than in any incident case, allowing the correct detection of transmission direction in 8 outbreaks for which source cases were known. A simple and accurate distance-based approach developed here for detecting HCV transmissions streamlines molecular investigation of outbreaks, thus improving the public health capacity for rapid and effective control of hepatitis C.

Highlights

Hepatitis C is a major public health problem in the United States and worldwide
A total of 12 987 Hepatitis C virus (HCV) clones obtained using end-point limiting-dilution (EPLD) PCR were analyzed in this study
There were 374 pairwise comparisons among samples belonging to the same transmission cluster from 32 epidemiologically confirmed outbreaks, of which 78 (20.86%) were between identical HCV variants and 73 (19.52%) were between HCV variants that differ at a single nucleotide position

Summary

Introduction

Hepatitis C is a major public health problem in the United States and worldwide. Outbreaks of hepatitis C virus (HCV) infections are associated with unsafe injection practices, drug diversion, and other exposures to blood and are difficult to detect and investigate. A simple and accurate distance-based approach developed here for detecting HCV transmissions streamlines molecular investigation of outbreaks, improving the public health capacity for rapid and effective control of hepatitis C. A phylogenetic cluster of sequences can be interpreted as representing a single viral strain shared by cases involved in an outbreak if (1) genetic or patristic distances among sequences from the cluster are below a certain threshold and (2) the ancestral node for the suspected transmission cluster in the tree has a high statistical significance calculated using Bayesian statistics or bootstrap analysis. Such as a close geographical location and high-risk behavior among members of the cluster can be used to evaluate the phylogenetic inferences [14]. Such approaches are commonly used in HIV forensics [23]

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