Your search keyword '"Viral integration"' showing total 9 results

1. ViR: a tool to solve intrasample variability in the prediction of viral integration sites using whole genome sequencing data

Author

Elisa Pischedda, Cristina Crava, Martina Carlassara, Susanna Zucca, Leila Gasmi, and Mariangela Bonizzoni

Subjects

Viral integration, Repetitive DNA, Lateral gene transfer, Non-model organisms, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Several bioinformatics pipelines have been developed to detect sequences from viruses that integrate into the human genome because of the health relevance of these integrations, such as in the persistence of viral infection and/or in generating genotoxic effects, often progressing into cancer. Recent genomics and metagenomics analyses have shown that viruses also integrate into the genome of non-model organisms (i.e., arthropods, fish, plants, vertebrates). However, rarely studies of endogenous viral elements (EVEs) in non-model organisms have gone beyond their characterization from reference genome assemblies. In non-model organisms, we lack a thorough understanding of the widespread occurrence of EVEs and their biological relevance, apart from sporadic cases which nevertheless point to significant roles of EVEs in immunity and regulation of expression. The concomitance of repetitive DNA, duplications and/or assembly fragmentations in a genome sequence and intrasample variability in whole-genome sequencing (WGS) data could determine misalignments when mapping data to a genome assembly. This phenomenon hinders our ability to properly identify integration sites. Results To fill this gap, we developed ViR, a pipeline which solves the dispersion of reads due to intrasample variability in sequencing data from both single and pooled DNA samples thus ameliorating the detection of integration sites. We tested ViR to work with both in silico and real sequencing data from a non-model organism, the arboviral vector Aedes albopictus. Potential viral integrations predicted by ViR were molecularly validated supporting the accuracy of ViR results. Conclusion ViR will open new venues to explore the biology of EVEs, especially in non-model organisms. Importantly, while we generated ViR with the identification of EVEs in mind, its application can be extended to detect any lateral transfer event providing an ad-hoc sequence to interrogate.

Published

2021

2. ViR: a tool to solve intrasample variability in the prediction of viral integration sites using whole genome sequencing data.

Author

Pischedda, Elisa, Crava, Cristina, Carlassara, Martina, Zucca, Susanna, Gasmi, Leila, and Bonizzoni, Mariangela

Subjects

*VIRAL variation, *NUCLEOTIDE sequencing, *HORIZONTAL gene transfer, *AEDES albopictus, *IMMUNOREGULATION, *GENETIC toxicology

Abstract

Background: Several bioinformatics pipelines have been developed to detect sequences from viruses that integrate into the human genome because of the health relevance of these integrations, such as in the persistence of viral infection and/or in generating genotoxic effects, often progressing into cancer. Recent genomics and metagenomics analyses have shown that viruses also integrate into the genome of non-model organisms (i.e., arthropods, fish, plants, vertebrates). However, rarely studies of endogenous viral elements (EVEs) in non-model organisms have gone beyond their characterization from reference genome assemblies. In non-model organisms, we lack a thorough understanding of the widespread occurrence of EVEs and their biological relevance, apart from sporadic cases which nevertheless point to significant roles of EVEs in immunity and regulation of expression. The concomitance of repetitive DNA, duplications and/or assembly fragmentations in a genome sequence and intrasample variability in whole-genome sequencing (WGS) data could determine misalignments when mapping data to a genome assembly. This phenomenon hinders our ability to properly identify integration sites. Results: To fill this gap, we developed ViR, a pipeline which solves the dispersion of reads due to intrasample variability in sequencing data from both single and pooled DNA samples thus ameliorating the detection of integration sites. We tested ViR to work with both in silico and real sequencing data from a non-model organism, the arboviral vector Aedes albopictus. Potential viral integrations predicted by ViR were molecularly validated supporting the accuracy of ViR results. Conclusion: ViR will open new venues to explore the biology of EVEs, especially in non-model organisms. Importantly, while we generated ViR with the identification of EVEs in mind, its application can be extended to detect any lateral transfer event providing an ad-hoc sequence to interrogate. [ABSTRACT FROM AUTHOR]

Published

2021

3. HGT-ID: an efficient and sensitive workflow to detect human-viral insertion sites using next-generation sequencing data

Author

Saurabh Baheti, Xiaojia Tang, Daniel R. O’Brien, Nicholas Chia, Lewis R. Roberts, Heidi Nelson, Judy C. Boughey, Liewei Wang, Matthew P. Goetz, Jean-Pierre A. Kocher, and Krishna R. Kalari

Subjects

Horizontal gene transfer, Viral integration, Next-generation sequencing, Whole-genome sequencing, RNA-Seq – Cancer, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Transfer of genetic material from microbes or viruses into the host genome is known as horizontal gene transfer (HGT). The integration of viruses into the human genome is associated with multiple cancers, and these can now be detected using next-generation sequencing methods such as whole genome sequencing and RNA-sequencing. Results We designed a novel computational workflow, HGT-ID, to identify the integration of viruses into the human genome using the sequencing data. The HGT-ID workflow primarily follows a four-step procedure: i) pre-processing of unaligned reads, ii) virus detection using subtraction approach, iii) identification of virus integration site using discordant and soft-clipped reads and iv) HGT candidates prioritization through a scoring function. Annotation and visualization of the events, as well as primer design for experimental validation, are also provided in the final report. We evaluated the tool performance with the well-understood cervical cancer samples. The HGT-ID workflow accurately detected known human papillomavirus (HPV) integration sites with high sensitivity and specificity compared to previous HGT methods. We applied HGT-ID to The Cancer Genome Atlas (TCGA) whole-genome sequencing data (WGS) from liver tumor-normal pairs. Multiple hepatitis B virus (HBV) integration sites were identified in TCGA liver samples and confirmed by HGT-ID using the RNA-Seq data from the matched liver pairs. This shows the applicability of the method in both the data types and cross-validation of the HGT events in liver samples. We also processed 220 breast tumor WGS data through the workflow; however, there were no HGT events detected in those samples. Conclusions HGT-ID is a novel computational workflow to detect the integration of viruses in the human genome using the sequencing data. It is fast and accurate with functions such as prioritization, annotation, visualization and primer design for future validation of HGTs. The HGT-ID workflow is released under the MIT License and available at http://kalarikrlab.org/Software/HGT-ID.html.

Published

2018

4. VISMapper: ultra-fast exhaustive cartography of viral insertion sites for gene therapy

Author

José M. Juanes, Asunción Gallego, Joaquín Tárraga, Felipe J. Chaves, Pablo Marín-Garcia, Ignacio Medina, Vicente Arnau, and Joaquín Dopazo

Subjects

Gene therapy, Viral insertion, Viral integration, Sequence mapping, Genome viewer, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background The possibility of integrating viral vectors to become a persistent part of the host genome makes them a crucial element of clinical gene therapy. However, viral integration has associated risks, such as the unintentional activation of oncogenes that can result in cancer. Therefore, the analysis of integration sites of retroviral vectors is a crucial step in developing safer vectors for therapeutic use. Results Here we present VISMapper, a vector integration site analysis web server, to analyze next-generation sequencing data for retroviral vector integration sites. VISMapper can be found at: http://vismapper.babelomics.org . Conclusions Because it uses novel mapping algorithms VISMapper is remarkably faster than previous available programs. It also provides a useful graphical interface to analyze the integration sites found in the genomic context.

Published

2017

5. HGT-ID: an efficient and sensitive workflow to detect human-viral insertion sites using next-generation sequencing data.

Author

Baheti, Saurabh, Tang, Xiaojia, O'Brien, Daniel R., Chia, Nicholas, Roberts, Lewis R., Nelson, Heidi, Boughey, Judy C., Wang, Liewei, Goetz, Matthew P., Kocher, Jean-Pierre A., and Kalari, Krishna R.

Subjects

*HORIZONTAL gene transfer, *NUCLEOTIDE sequencing, *RNA sequencing, *CERVICAL cancer, *HEPATITIS B virus

Abstract

Background: Transfer of genetic material from microbes or viruses into the host genome is known as horizontal gene transfer (HGT). The integration of viruses into the human genome is associated with multiple cancers, and these can now be detected using next-generation sequencing methods such as whole genome sequencing and RNA-sequencing. Results: We designed a novel computational workflow, HGT-ID, to identify the integration of viruses into the human genome using the sequencing data. The HGT-ID workflow primarily follows a four-step procedure: i) pre-processing of unaligned reads, ii) virus detection using subtraction approach, iii) identification of virus integration site using discordant and soft-clipped reads and iv) HGT candidates prioritization through a scoring function. Annotation and visualization of the events, as well as primer design for experimental validation, are also provided in the final report. We evaluated the tool performance with the well-understood cervical cancer samples. The HGT-ID workflow accurately detected known human papillomavirus (HPV) integration sites with high sensitivity and specificity compared to previous HGT methods. We applied HGT-ID to The Cancer Genome Atlas (TCGA) whole-genome sequencing data (WGS) from liver tumor-normal pairs. Multiple hepatitis B virus (HBV) integration sites were identified in TCGA liver samples and confirmed by HGT-ID using the RNA-Seq data from the matched liver pairs. This shows the applicability of the method in both the data types and cross-validation of the HGT events in liver samples. We also processed 220 breast tumor WGS data through the workflow; however, there were no HGT events detected in those samples. Conclusions: HGT-ID is a novel computational workflow to detect the integration of viruses in the human genome using the sequencing data. It is fast and accurate with functions such as prioritization, annotation, visualization and primer design for future validation of HGTs. The HGT-ID workflow is released under the MIT License and available at http://kalarikrlab.org/Software/HGT-ID.html. [ABSTRACT FROM AUTHOR]

Published

2018

6. VISMapper: ultra-fast exhaustive cartography of viral insertion sites for gene therapy.

Author

Juanes, José M., Gallego, Asunción, Tárraga, Joaquín, Chaves, Felipe J., Marín-Garcia, Pablo, Medina, Ignacio, Arnau, Vicente, and Dopazo, Joaquín

Subjects

*CARTOGRAPHY, *DNA insertion elements, *GENE therapy, *GENOMICS, *THERAPEUTICS

Abstract

Background: The possibility of integrating viral vectors to become a persistent part of the host genome makes them a crucial element of clinical gene therapy. However, viral integration has associated risks, such as the unintentional activation of oncogenes that can result in cancer. Therefore, the analysis of integration sites of retroviral vectors is a crucial step in developing safer vectors for therapeutic use. Results: Here we present VISMapper, a vector integration site analysis web server, to analyze next-generation sequencing data for retroviral vector integration sites. VISMapper can be found at: http://vismapper.babelomics.org. Conclusions: Because it uses novel mapping algorithms VISMapper is remarkably faster than previous available programs. It also provides a useful graphical interface to analyze the integration sites found in the genomic context. [ABSTRACT FROM AUTHOR]

Published

2017

7. BATVI: Fast, sensitive and accurate detection of virus integrations.

Author

Tennakoon, Chandana and Wing Kin Sung

Subjects

*SEQUENCE alignment, *VIRUS identification, *HUMAN genome, *ROUS sarcoma, *CHIMERIC proteins, *GENE expression

Abstract

Background: The study of virus integrations in human genome is important since virus integrations were shown to be associated with diseases. In the literature, few methods have been proposed that predict virus integrations using next generation sequencing datasets. Although they work, they are slow and are not very sensitive. Results and discussion: This paper introduces a new method BatVI to predict viral integrations. Our method uses a fast screening method to filter out chimeric reads containing possible viral integrations. Next, sensitive alignments of these candidate chimeric reads are called by BLAST. Chimeric reads that are co-localized in the human genome are clustered. Finally, by assembling the chimeric reads in each cluster, high confident virus integration sites are extracted. Conclusion: We compared the performance of BatVI with existing methods VirusFinder and VirusSeq using both simulated and real-life datasets of liver cancer patients. BatVI ran an order of magnitude faster and was able to predict almost twice the number of true positives compared to other methods while maintaining a false positive rate less than 1%. For the liver cancer datasets, BatVI uncovered novel integrations to two important genes TERT and MLL4, which were missed by previous studies. Through gene expression data, we verified the correctness of these additional integrations. BatVI can be downloaded from http://biogpu.ddns.comp.nus.edu.sg/∼ksung/batvi/index.html. [ABSTRACT FROM AUTHOR]

Published

2017

8. HGT-ID: an efficient and sensitive workflow to detect human-viral insertion sites using next-generation sequencing data

Author

Lewis R. Roberts, Liewei Wang, Jean Pierre A. Kocher, Krishna R. Kalari, Daniel R. O'Brien, Nicholas Chia, Judy C. Boughey, Xiaojia Tang, Saurabh Baheti, Heidi Nelson, and Matthew P. Goetz

Subjects

0301 basic medicine, Gene Transfer, Horizontal, Virus Integration, Breast Neoplasms, Computational biology, Biology, lcsh:Computer applications to medicine. Medical informatics, Biochemistry, DNA sequencing, Workflow, Viral integration, 03 medical and health sciences, Annotation, Structural Biology, Cell Line, Tumor, Humans, Computer Simulation, RNA-Seq – Cancer, Molecular Biology, lcsh:QH301-705.5, Whole genome sequencing, Whole-genome sequencing, Base Sequence, Whole Genome Sequencing, Genome, Human, Applied Mathematics, High-Throughput Nucleotide Sequencing, Horizontal gene transfer, Computer Science Applications, 030104 developmental biology, ROC Curve, lcsh:Biology (General), Next-generation sequencing, lcsh:R858-859.7, Female, Human genome, DNA microarray, Algorithms, Software

Abstract

Transfer of genetic material from microbes or viruses into the host genome is known as horizontal gene transfer (HGT). The integration of viruses into the human genome is associated with multiple cancers, and these can now be detected using next-generation sequencing methods such as whole genome sequencing and RNA-sequencing. We designed a novel computational workflow, HGT-ID, to identify the integration of viruses into the human genome using the sequencing data. The HGT-ID workflow primarily follows a four-step procedure: i) pre-processing of unaligned reads, ii) virus detection using subtraction approach, iii) identification of virus integration site using discordant and soft-clipped reads and iv) HGT candidates prioritization through a scoring function. Annotation and visualization of the events, as well as primer design for experimental validation, are also provided in the final report. We evaluated the tool performance with the well-understood cervical cancer samples. The HGT-ID workflow accurately detected known human papillomavirus (HPV) integration sites with high sensitivity and specificity compared to previous HGT methods. We applied HGT-ID to The Cancer Genome Atlas (TCGA) whole-genome sequencing data (WGS) from liver tumor-normal pairs. Multiple hepatitis B virus (HBV) integration sites were identified in TCGA liver samples and confirmed by HGT-ID using the RNA-Seq data from the matched liver pairs. This shows the applicability of the method in both the data types and cross-validation of the HGT events in liver samples. We also processed 220 breast tumor WGS data through the workflow; however, there were no HGT events detected in those samples. HGT-ID is a novel computational workflow to detect the integration of viruses in the human genome using the sequencing data. It is fast and accurate with functions such as prioritization, annotation, visualization and primer design for future validation of HGTs. The HGT-ID workflow is released under the MIT License and available at http://kalarikrlab.org/Software/HGT-ID.html .

Published

2018

9. BATVI: Fast, sensitive and accurate detection of virus integrations

Author

Wing-Kin Sung and Chandana Tennakoon

Subjects

0301 basic medicine, Virus Integration, Computational biology, Biology, Biochemistry, DNA sequencing, Viral integration, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Screening method, Cluster Analysis, Humans, Dna viral, Telomerase, Molecular Biology, Alignment, Genetics, Genome, Human, Research, Applied Mathematics, Liver Neoplasms, High-Throughput Nucleotide Sequencing, Histone-Lysine N-Methyltransferase, Sequence Analysis, DNA, Models, Theoretical, Computer Science Applications, DNA-Binding Proteins, 030104 developmental biology, NGS, 030220 oncology & carcinogenesis, DNA, Viral, Host-Pathogen Interactions, Human genome, False positive rate, DNA microarray, True positive rate, Algorithms, Software

Abstract

The study of virus integrations in human genome is important since virus integrations were shown to be associated with diseases. In the literature, few methods have been proposed that predict virus integrations using next generation sequencing datasets. Although they work, they are slow and are not very sensitive. This paper introduces a new method BatVI to predict viral integrations. Our method uses a fast screening method to filter out chimeric reads containing possible viral integrations. Next, sensitive alignments of these candidate chimeric reads are called by BLAST. Chimeric reads that are co-localized in the human genome are clustered. Finally, by assembling the chimeric reads in each cluster, high confident virus integration sites are extracted. We compared the performance of BatVI with existing methods VirusFinder and VirusSeq using both simulated and real-life datasets of liver cancer patients. BatVI ran an order of magnitude faster and was able to predict almost twice the number of true positives compared to other methods while maintaining a false positive rate less than 1%. For the liver cancer datasets, BatVI uncovered novel integrations to two important genes TERT and MLL4, which were missed by previous studies. Through gene expression data, we verified the correctness of these additional integrations. BatVI can be downloaded from http://biogpu.ddns.comp.nus.edu.sg/~ksung/batvi/index.html .

Published

2017