Long-Read Sequencing – A Powerful Tool in Viral Transcriptome Research

Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in determining full-length RNA molecules. Two important LRS technologies have been developed during the past few years, including single-molecule, real-...

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Published in	Trends in microbiology (Regular ed.) Vol. 27; no. 7; pp. 578 - 592
Main Authors	Boldogkői, Zsolt, Moldován, Norbert, Balázs, Zsolt, Snyder, Michael, Tombácz, Dóra
Format	Journal Article
Language	English
Published	England Elsevier Ltd 01.07.2019 Elsevier Science Ltd
Subjects	Deoxyribonucleic acid DNA DNA replication Gene expression genome Genomes Identification methods Isoforms messenger RNA nanopore sequencing nanopores noncoding RNA Pacific Biosciences Porosity Production methods replication origin Ribonucleic acid RNA RNA viruses RNA-Seq splicing Transcription transcription (genetics) transcriptome transcriptomics Viruses nanopore sequencing DNA replication noncoding RNA RNA-Seq splicing replication origin Pacific Biosciences
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Abstract	Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in determining full-length RNA molecules. Two important LRS technologies have been developed during the past few years, including single-molecule, real-time sequencing by Pacific Biosciences, and nanopore sequencing by Oxford Nanopore Technologies. Although current LRS methods produce lower coverage, and are more error prone than short-read sequencing, these methods continue to be superior in identifying transcript isoforms including multispliced RNAs and transcript-length variants as well as overlapping transcripts and alternative polycistronic RNA molecules. Viruses have small, compact genomes and therefore these organisms are ideal subjects for transcriptome analysis with the relatively low-throughput LRS techniques. Recent LRS studies have multiplied the number of previously known transcripts and have revealed complex networks of transcriptional overlaps in the examined viruses. Long-read sequencing (LRS) has revolutionized genomics and transcriptomics. These third-generation approaches have a relatively low throughput compared to short-read sequencing, but they can solve problems that used to be a challenge for earlier techniques.The PacBio and ONT sequencing are able to read full-length transcripts and allow the direct study of base modifications on both DNA and RNA molecules. Nanopore technology is able to sequence RNA directly.LRS has revealed a much more complex viral transcriptome. Among other capabilities, these techniques allow the discrimination between multispliced transcript variants, RNA length isoforms, embedded RNAs, and polycistronic RNA molecules.The viral genomes express a highly complex pattern of transcriptional overlaps, the function of which continues to remain unknown.
AbstractList	Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in determining full-length RNA molecules. Two important LRS technologies have been developed during the past few years, including single-molecule, real-time sequencing by Pacific Biosciences, and nanopore sequencing by Oxford Nanopore Technologies. Although current LRS methods produce lower coverage, and are more error prone than short-read sequencing, these methods continue to be superior in identifying transcript isoforms including multispliced RNAs and transcript-length variants as well as overlapping transcripts and alternative polycistronic RNA molecules. Viruses have small, compact genomes and therefore these organisms are ideal subjects for transcriptome analysis with the relatively low-throughput LRS techniques. Recent LRS studies have multiplied the number of previously known transcripts and have revealed complex networks of transcriptional overlaps in the examined viruses. Long-read sequencing (LRS) has revolutionized genomics and transcriptomics. These third-generation approaches have a relatively low throughput compared to short-read sequencing, but they can solve problems that used to be a challenge for earlier techniques.The PacBio and ONT sequencing are able to read full-length transcripts and allow the direct study of base modifications on both DNA and RNA molecules. Nanopore technology is able to sequence RNA directly.LRS has revealed a much more complex viral transcriptome. Among other capabilities, these techniques allow the discrimination between multispliced transcript variants, RNA length isoforms, embedded RNAs, and polycistronic RNA molecules.The viral genomes express a highly complex pattern of transcriptional overlaps, the function of which continues to remain unknown. Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in determining full-length RNA molecules. Two important LRS technologies have been developed during the past few years, including single-molecule, real-time sequencing by Pacific Biosciences, and nanopore sequencing by Oxford Nanopore Technologies. Although current LRS methods produce lower coverage, and are more error prone than short-read sequencing, these methods continue to be superior in identifying transcript isoforms including multispliced RNAs and transcript-length variants as well as overlapping transcripts and alternative polycistronic RNA molecules. Viruses have small, compact genomes and therefore these organisms are ideal subjects for transcriptome analysis with the relatively low-throughput LRS techniques. Recent LRS studies have multiplied the number of previously known transcripts and have revealed complex networks of transcriptional overlaps in the examined viruses. Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in determining full-length RNA molecules. Two important LRS technologies have been developed during the past few years, including single-molecule, real-time sequencing by Pacific Biosciences, and nanopore sequencing by Oxford Nanopore Technologies. Although current LRS methods produce lower coverage, and are more error prone than short-read sequencing, these methods continue to be superior in identifying transcript isoforms including multispliced RNAs and transcript-length variants as well as overlapping transcripts and alternative polycistronic RNA molecules. Viruses have small, compact genomes and therefore these organisms are ideal subjects for transcriptome analysis with the relatively low-throughput LRS techniques. Recent LRS studies have multiplied the number of previously known transcripts and have revealed complex networks of transcriptional overlaps in the examined viruses.Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in determining full-length RNA molecules. Two important LRS technologies have been developed during the past few years, including single-molecule, real-time sequencing by Pacific Biosciences, and nanopore sequencing by Oxford Nanopore Technologies. Although current LRS methods produce lower coverage, and are more error prone than short-read sequencing, these methods continue to be superior in identifying transcript isoforms including multispliced RNAs and transcript-length variants as well as overlapping transcripts and alternative polycistronic RNA molecules. Viruses have small, compact genomes and therefore these organisms are ideal subjects for transcriptome analysis with the relatively low-throughput LRS techniques. Recent LRS studies have multiplied the number of previously known transcripts and have revealed complex networks of transcriptional overlaps in the examined viruses.
Author	Snyder, Michael Tombácz, Dóra Moldován, Norbert Boldogkői, Zsolt Balázs, Zsolt
Author_xml	– sequence: 1 givenname: Zsolt surname: Boldogkői fullname: Boldogkői, Zsolt email: boldogkoi.zsolt@med.u-szeged.hu organization: Department of Medical Biology, Faculty of Medicine, University of Szeged, Szeged, Hungary – sequence: 2 givenname: Norbert surname: Moldován fullname: Moldován, Norbert organization: Department of Medical Biology, Faculty of Medicine, University of Szeged, Szeged, Hungary – sequence: 3 givenname: Zsolt surname: Balázs fullname: Balázs, Zsolt organization: Department of Medical Biology, Faculty of Medicine, University of Szeged, Szeged, Hungary – sequence: 4 givenname: Michael surname: Snyder fullname: Snyder, Michael organization: Department of Genetics, School of Medicine, Stanford University, 300 Pasteur Drive, Stanford, CA 94305-5120, USA – sequence: 5 givenname: Dóra surname: Tombácz fullname: Tombácz, Dóra organization: Department of Medical Biology, Faculty of Medicine, University of Szeged, Szeged, Hungary
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Snippet	Long-read sequencing (LRS) has become increasingly popular due to its strengths in de novo assembly and in resolving complex DNA regions as well as in...
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SubjectTerms	Deoxyribonucleic acid DNA DNA replication Gene expression genome Genomes Identification methods Isoforms messenger RNA nanopore sequencing nanopores noncoding RNA Pacific Biosciences Porosity Production methods replication origin Ribonucleic acid RNA RNA viruses RNA-Seq splicing Transcription transcription (genetics) transcriptome transcriptomics Viruses
Title	Long-Read Sequencing – A Powerful Tool in Viral Transcriptome Research
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