Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications

Monitoring viruses circulating in the human population and the environment is critical for protecting public and ecosystem health. The goal of this dissertation was to incorporate a viral metagenomic approach into virus surveillance efforts (both clinical and water quality control programs) to enhan...

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Main Author: Rosario-Cora, Karyna
Format: Others
Published: Scholar Commons 2010
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Online Access:http://scholarcommons.usf.edu/etd/3600
http://scholarcommons.usf.edu/cgi/viewcontent.cgi?article=4849&context=etd
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spelling ndltd-USF-oai-scholarcommons.usf.edu-etd-48492015-09-30T04:41:18Z Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications Rosario-Cora, Karyna Monitoring viruses circulating in the human population and the environment is critical for protecting public and ecosystem health. The goal of this dissertation was to incorporate a viral metagenomic approach into virus surveillance efforts (both clinical and water quality control programs) to enhance traditional virus detection methods. Clinical surveillance programs are designed to identify and monitor etiological agents that cause disease. However, the ability to identify viruses may be compromised when novel or unsuspected viruses are causing infection since traditional virus detection methods target specific known pathogens. Here we describe the successful application of viral metagenomics in a clinical setting using samples from symptomatic patients collected through the Enterovirus Surveillance (EVS) program in the Netherlands (Appendix A). Despite extensive PCR-based testing, the viruses in a small percentage of these samples (n = 7) remained unidentified for more than 10 years after collection. Viral metagenomics allowed the identification of viruses in all seven samples within a week using minimal sequencing, thus rapidly filling the diagnostic gap. The unexplained samples contained BK polyomavirus, Herpes simplex virus, Newcastle disease virus and the recently discovered Saffold viruses (SAFV) which dominated the unexplained samples (n = 4). This study demonstrated that metagenomic analyses can be added as a routine tool to investigate unidentified viruses in clinical samples in a public-health setting. In addition, metagenomic data gathered for SAFV was used to complete four genotype 3 SAFV (SAFV-3) genomes through primer walking, doubling the number of SAFV-3 full genomic sequences in public databases. In addition to monitoring viruses in symptomatic patients, it is also important to monitor viruses in wastewater (raw and treated) to protect the environment from biological contamination and prevent further spread of pathogens. To gain a comprehensive understanding of viruses that endure wastewater treatment, viral metagenomics was used to survey the total DNA and RNA viral community in reclaimed water (the reusable end-product of wastewater treatment) (Appendix B). Phages (viruses that infect bacteria) dominated the DNA viral community while eukaryotic viruses similar to known plant and insect viruses dominated RNA metagenomic libraries suggesting that highly stable viruses may be disseminated through this alternative water supply. A plant virus, the Pepper mild mottle virus (PMMoV), was identified as a potential indicator of wastewater contamination based on metagenomic data and quantitative PCR assays (Appendix C). The metagenomic analysis also revealed a wealth of novel single-stranded DNA (ssDNA) viruses in reclaimed water. Further investigation of sequences with low-level similarities to known ssDNA viruses led to the completion of ten novel ssDNA genomes from reclaimed water and marine environments (Appendix D). Unique genome architectures and phylogenetic analysis suggest that these ssDNA viruses belong to new viral genera and/or families. To further explore the ecology of the novel ssDNA viruses, a strategy was developed to take metagenomic analysis to the next level by combining expression analysis and immunotechnology (Appendix E). This dissertation made a significant contribution to current microbiological data regarding wastewater by uncovering viruses that endure the wastewater treatment and identifying a new viral bioindicator. 2010-10-28T07:00:00Z text application/pdf http://scholarcommons.usf.edu/etd/3600 http://scholarcommons.usf.edu/cgi/viewcontent.cgi?article=4849&context=etd default Graduate Theses and Dissertations Scholar Commons Enteric Viruses Bioindicators Wastewater Reclaimed Water Fecal Pollution Single-stranded DNA Viruses American Studies Arts and Humanities
collection NDLTD
format Others
sources NDLTD
topic Enteric Viruses
Bioindicators
Wastewater
Reclaimed Water
Fecal Pollution
Single-stranded DNA Viruses
American Studies
Arts and Humanities
spellingShingle Enteric Viruses
Bioindicators
Wastewater
Reclaimed Water
Fecal Pollution
Single-stranded DNA Viruses
American Studies
Arts and Humanities
Rosario-Cora, Karyna
Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications
description Monitoring viruses circulating in the human population and the environment is critical for protecting public and ecosystem health. The goal of this dissertation was to incorporate a viral metagenomic approach into virus surveillance efforts (both clinical and water quality control programs) to enhance traditional virus detection methods. Clinical surveillance programs are designed to identify and monitor etiological agents that cause disease. However, the ability to identify viruses may be compromised when novel or unsuspected viruses are causing infection since traditional virus detection methods target specific known pathogens. Here we describe the successful application of viral metagenomics in a clinical setting using samples from symptomatic patients collected through the Enterovirus Surveillance (EVS) program in the Netherlands (Appendix A). Despite extensive PCR-based testing, the viruses in a small percentage of these samples (n = 7) remained unidentified for more than 10 years after collection. Viral metagenomics allowed the identification of viruses in all seven samples within a week using minimal sequencing, thus rapidly filling the diagnostic gap. The unexplained samples contained BK polyomavirus, Herpes simplex virus, Newcastle disease virus and the recently discovered Saffold viruses (SAFV) which dominated the unexplained samples (n = 4). This study demonstrated that metagenomic analyses can be added as a routine tool to investigate unidentified viruses in clinical samples in a public-health setting. In addition, metagenomic data gathered for SAFV was used to complete four genotype 3 SAFV (SAFV-3) genomes through primer walking, doubling the number of SAFV-3 full genomic sequences in public databases. In addition to monitoring viruses in symptomatic patients, it is also important to monitor viruses in wastewater (raw and treated) to protect the environment from biological contamination and prevent further spread of pathogens. To gain a comprehensive understanding of viruses that endure wastewater treatment, viral metagenomics was used to survey the total DNA and RNA viral community in reclaimed water (the reusable end-product of wastewater treatment) (Appendix B). Phages (viruses that infect bacteria) dominated the DNA viral community while eukaryotic viruses similar to known plant and insect viruses dominated RNA metagenomic libraries suggesting that highly stable viruses may be disseminated through this alternative water supply. A plant virus, the Pepper mild mottle virus (PMMoV), was identified as a potential indicator of wastewater contamination based on metagenomic data and quantitative PCR assays (Appendix C). The metagenomic analysis also revealed a wealth of novel single-stranded DNA (ssDNA) viruses in reclaimed water. Further investigation of sequences with low-level similarities to known ssDNA viruses led to the completion of ten novel ssDNA genomes from reclaimed water and marine environments (Appendix D). Unique genome architectures and phylogenetic analysis suggest that these ssDNA viruses belong to new viral genera and/or families. To further explore the ecology of the novel ssDNA viruses, a strategy was developed to take metagenomic analysis to the next level by combining expression analysis and immunotechnology (Appendix E). This dissertation made a significant contribution to current microbiological data regarding wastewater by uncovering viruses that endure the wastewater treatment and identifying a new viral bioindicator.
author Rosario-Cora, Karyna
author_facet Rosario-Cora, Karyna
author_sort Rosario-Cora, Karyna
title Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications
title_short Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications
title_full Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications
title_fullStr Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications
title_full_unstemmed Enhancing Virus Surveillance through Metagenomics: Water Quality and Public Health Applications
title_sort enhancing virus surveillance through metagenomics: water quality and public health applications
publisher Scholar Commons
publishDate 2010
url http://scholarcommons.usf.edu/etd/3600
http://scholarcommons.usf.edu/cgi/viewcontent.cgi?article=4849&context=etd
work_keys_str_mv AT rosariocorakaryna enhancingvirussurveillancethroughmetagenomicswaterqualityandpublichealthapplications
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