Your search keyword '"Brasca, S"' showing total 9 results

1. New Graph-Based Algorithm for Comprehensive Identification and Tracking Retroviral Integration Sites

Author

CALABRIA, ANDREA, BERETTA, STEFANO, MERELLI, IVAN, SPINOZZI, GIULIO, Brasca, S, Benedicenti, F, Tenderini, E, Biffi, A, Montini, E., Calabria, A, Beretta, S, Merelli, I, Spinozzi, G, Brasca, S, Benedicenti, F, Tenderini, E, Biffi, A, and Montini, E

Subjects

Retroviral Integration Sites, Cell Therapy

Published

2016

2. VISPA2: a scalable pipeline for high-throughput identification and annotation of vector integration sites

Author

Spinozzi, G, Calabria, A, Brasca, S, Beretta, S, Merelli, I, Milanesi, L, Montini, E, SPINOZZI, GIULIO, CALABRIA, ANDREA, Montini, E., Spinozzi, G, Calabria, A, Brasca, S, Beretta, S, Merelli, I, Milanesi, L, Montini, E, SPINOZZI, GIULIO, CALABRIA, ANDREA, and Montini, E.

Abstract

Background: Bioinformatics tools designed to identify lentiviral or retroviral vector insertion sites in the genome of host cells are used to address the safety and long-term efficacy of hematopoietic stem cell gene therapy applications and to study the clonal dynamics of hematopoietic reconstitution. The increasing number of gene therapy clinical trials combined with the increasing amount of Next Generation Sequencing data, aimed at identifying integration sites, require both highly accurate and efficient computational software able to correctly process "big data" in a reasonable computational time. Results: Here we present VISPA2 (Vector Integration Site Parallel Analysis, version 2), the latest optimized computational pipeline for integration site identification and analysis with the following features: (1) the sequence analysis for the integration site processing is fully compliant with paired-end reads and includes a sequence quality filter before and after the alignment on the target genome; (2) an heuristic algorithm to reduce false positive integration sites at nucleotide level to reduce the impact of Polymerase Chain Reaction or trimming/alignment artifacts; (3) a classification and annotation module for integration sites; (4) a user friendly web interface as researcher front-end to perform integration site analyses without computational skills; (5) the time speedup of all steps through parallelization (Hadoop free). Conclusions: We tested VISPA2 performances using simulated and real datasets of lentiviral vector integration sites, previously obtained from patients enrolled in a hematopoietic stem cell gene therapy clinical trial and compared the results with other preexisting tools for integration site analysis. On the computational side, VISPA2 showed a>6-fold speedup and improved precision and recall metrics (1 and 0.97 respectively) compared to previously developed computational pipelines. These performances indicate that VISPA2 is a fast, reliable a

Published

2017

3. Lentiviral Vector-based Insertional Mutagenesis Identifies Genes Involved in the Resistance to Targeted Anticancer Therapies

Author

Ranzani M, Annunziato S, Calabria A, Brasca S, Benedicenti F, Gallina P, Montini E., NALDINI , LUIGI, Ranzani, M, Annunziato, S, Calabria, A, Brasca, S, Benedicenti, F, Gallina, P, Naldini, Luigi, and Montini, E.

Published

2014

4. New Graph-Based Algorithm for Comprehensive Identification and Tracking Retroviral Integration Sites

Author

Calabria, A, Beretta, S, Merelli, I, Spinozzi, G, Brasca, S, Benedicenti, F, Tenderini, E, Biffi, A, Montini, E, CALABRIA, ANDREA, BERETTA, STEFANO, MERELLI, IVAN, SPINOZZI, GIULIO, Montini, E., Calabria, A, Beretta, S, Merelli, I, Spinozzi, G, Brasca, S, Benedicenti, F, Tenderini, E, Biffi, A, Montini, E, CALABRIA, ANDREA, BERETTA, STEFANO, MERELLI, IVAN, SPINOZZI, GIULIO, and Montini, E.

Published

2016

5. ChemInform Abstract: Selective Lipase‐Catalyzed Acylation of 4,6‐O‐Benzylidene‐D‐ glucopyranosides to Synthetically Useful Esters.

Author

PANZA, L., primary, BRASCA, S., additional, RIVA, S., additional, and RUSSO, G., additional

Published

1993

6. VISPA2: a scalable pipeline for high-throughput identification and annotation of vector integration sites

Author

Ivan Merelli, Andrea Calabria, Giulio Spinozzi, Luciano Milanesi, Eugenio Montini, Stefano Brasca, Stefano Beretta, Spinozzi, G, Calabria, A, Brasca, S, Beretta, S, Merelli, I, Milanesi, L, and Montini, E

Subjects

0301 basic medicine, Speedup, Source code, Computer science, Genetic enhancement, computer.software_genre, Biochemistry, Genome, law.invention, Workflow, User-Computer Interface, Software, Structural Biology, law, Throughput (business), lcsh:QH301-705.5, Polymerase chain reaction, media_common, High-throughput sequencing, Applied Mathematics, Hematopoietic Stem Cell Transplantation, High-Throughput Nucleotide Sequencing, Open source software, Computer Science Applications, Scalability, lcsh:R858-859.7, Data mining, DNA microarray, Algorithms, Sequence analysis, media_common.quotation_subject, Genetic Vectors, Integration site analysi, Bioinformatics pipeline, lcsh:Computer applications to medicine. Medical informatics, DNA sequencing, Viral vector, 03 medical and health sciences, Gene therapy, Humans, Molecular Biology, business.industry, Lentivirus, Genetic Therapy, Virus Internalization, Hematopoietic Stem Cells, Pipeline (software), 030104 developmental biology, Integration site analysis, lcsh:Biology (General), Next-generation sequencing, business, computer, Sequence Alignment

Abstract

Background Bioinformatics tools designed to identify lentiviral or retroviral vector insertion sites in the genome of host cells are used to address the safety and long-term efficacy of hematopoietic stem cell gene therapy applications and to study the clonal dynamics of hematopoietic reconstitution. The increasing number of gene therapy clinical trials combined with the increasing amount of Next Generation Sequencing data, aimed at identifying integration sites, require both highly accurate and efficient computational software able to correctly process “big data” in a reasonable computational time. Results Here we present VISPA2 (Vector Integration Site Parallel Analysis, version 2), the latest optimized computational pipeline for integration site identification and analysis with the following features: (1) the sequence analysis for the integration site processing is fully compliant with paired-end reads and includes a sequence quality filter before and after the alignment on the target genome; (2) an heuristic algorithm to reduce false positive integration sites at nucleotide level to reduce the impact of Polymerase Chain Reaction or trimming/alignment artifacts; (3) a classification and annotation module for integration sites; (4) a user friendly web interface as researcher front-end to perform integration site analyses without computational skills; (5) the time speedup of all steps through parallelization (Hadoop free). Conclusions We tested VISPA2 performances using simulated and real datasets of lentiviral vector integration sites, previously obtained from patients enrolled in a hematopoietic stem cell gene therapy clinical trial and compared the results with other preexisting tools for integration site analysis. On the computational side, VISPA2 showed a > 6-fold speedup and improved precision and recall metrics (1 and 0.97 respectively) compared to previously developed computational pipelines. These performances indicate that VISPA2 is a fast, reliable and user-friendly tool for integration site analysis, which allows gene therapy integration data to be handled in a cost and time effective fashion. Moreover, the web access of VISPA2 (http://openserver.itb.cnr.it/vispa/) ensures accessibility and ease of usage to researches of a complex analytical tool. We released the source code of VISPA2 in a public repository (https://bitbucket.org/andreacalabria/vispa2). Electronic supplementary material The online version of this article (doi:10.1186/s12859-017-1937-9) contains supplementary material, which is available to authorized users.

Published

2017

7. γ-TRIS: a graph-algorithm for comprehensive identification of vector genomic insertion sites

Author

Luciano Milanesi, Andrea Calabria, Fabrizio Benedicenti, Stefano Brasca, Ivan Merelli, Giulio Spinozzi, Yuri Pirola, Erika Tenderini, Stefano Beretta, Paola Bonizzoni, Eugenio Montini, Calabria, A, Beretta, S, Merelli, I, Spinozzi, G, Brasca, S, Pirola, Y, Benedicenti, F, Tenderini, E, Bonizzoni, P, Milanesi, L, Montini, E, and Berger, B

Subjects

Statistics and Probability, Source code, media_common.quotation_subject, Computational biology, Biology, Biochemistry, Genome, Low complexity, genome-free, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Humans, Graph algorithms, Molecular Biology, 030304 developmental biology, media_common, 0303 health sciences, Base Sequence, INF/01 - INFORMATICA, Genomics, Repetitive Regions, graph, Genome Analysis, Computer Science Applications, Genetically modified organism, Applications Note, Computational Mathematics, Computational Theory and Mathematics, chemistry, 030220 oncology & carcinogenesis, Graph (abstract data type), insertion sites, Algorithms, Software, DNA

Abstract

Summary Retroviruses and their vector derivatives integrate semi-randomly in the genome of host cells and are inherited by their progeny as stable genetic marks. The retrieval and mapping of the sequences flanking the virus-host DNA junctions allows the identification of insertion sites in gene therapy or virally infected patients, essential for monitoring the evolution of genetically modified cells in vivo. However, since ∼30% of insertions land in low complexity or repetitive regions of the host cell genome, they cannot be correctly assigned and are currently discarded, limiting the accuracy and predictive power of clonal tracking studies. Here, we present γ-TRIS, a new graph-based genome-free alignment tool for identifying insertion sites even if embedded in low complexity regions. By using γ-TRIS to reanalyze clinical studies, we observed improvements in clonal quantification and tracking. Availability and implementation Source code at https://bitbucket.org/bereste/g-tris. Contact montini.eugenio@hsr.it Supplementary information Supplementary data are available at Bioinformatics online.

Published

2019

8. γ-TRIS: a graph-algorithm for comprehensive identification of vector genomic insertion sites.

Author

Calabria A, Beretta S, Merelli I, Spinozzi G, Brasca S, Pirola Y, Benedicenti F, Tenderini E, Bonizzoni P, Milanesi L, and Montini E

Subjects

Algorithms, Base Sequence, Humans, Software, Genome, Genomics

Abstract

Summary: Retroviruses and their vector derivatives integrate semi-randomly in the genome of host cells and are inherited by their progeny as stable genetic marks. The retrieval and mapping of the sequences flanking the virus-host DNA junctions allows the identification of insertion sites in gene therapy or virally infected patients, essential for monitoring the evolution of genetically modified cells in vivo. However, since ∼30% of insertions land in low complexity or repetitive regions of the host cell genome, they cannot be correctly assigned and are currently discarded, limiting the accuracy and predictive power of clonal tracking studies. Here, we present γ-TRIS, a new graph-based genome-free alignment tool for identifying insertion sites even if embedded in low complexity regions. By using γ-TRIS to reanalyze clinical studies, we observed improvements in clonal quantification and tracking., Availability and Implementation: Source code at https://bitbucket.org/bereste/g-tris., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2019. Published by Oxford University Press.)

Published

2020

9. VISPA2: a scalable pipeline for high-throughput identification and annotation of vector integration sites.

Author

Spinozzi G, Calabria A, Brasca S, Beretta S, Merelli I, Milanesi L, and Montini E

Subjects

Algorithms, Genetic Therapy, Genetic Vectors genetics, Genetic Vectors metabolism, Hematopoietic Stem Cell Transplantation, Hematopoietic Stem Cells cytology, Hematopoietic Stem Cells metabolism, High-Throughput Nucleotide Sequencing, Humans, Lentivirus genetics, Lentivirus physiology, Sequence Alignment, Virus Internalization, User-Computer Interface

Abstract

Background: Bioinformatics tools designed to identify lentiviral or retroviral vector insertion sites in the genome of host cells are used to address the safety and long-term efficacy of hematopoietic stem cell gene therapy applications and to study the clonal dynamics of hematopoietic reconstitution. The increasing number of gene therapy clinical trials combined with the increasing amount of Next Generation Sequencing data, aimed at identifying integration sites, require both highly accurate and efficient computational software able to correctly process "big data" in a reasonable computational time., Results: Here we present VISPA2 (Vector Integration Site Parallel Analysis, version 2), the latest optimized computational pipeline for integration site identification and analysis with the following features: (1) the sequence analysis for the integration site processing is fully compliant with paired-end reads and includes a sequence quality filter before and after the alignment on the target genome; (2) an heuristic algorithm to reduce false positive integration sites at nucleotide level to reduce the impact of Polymerase Chain Reaction or trimming/alignment artifacts; (3) a classification and annotation module for integration sites; (4) a user friendly web interface as researcher front-end to perform integration site analyses without computational skills; (5) the time speedup of all steps through parallelization (Hadoop free)., Conclusions: We tested VISPA2 performances using simulated and real datasets of lentiviral vector integration sites, previously obtained from patients enrolled in a hematopoietic stem cell gene therapy clinical trial and compared the results with other preexisting tools for integration site analysis. On the computational side, VISPA2 showed a > 6-fold speedup and improved precision and recall metrics (1 and 0.97 respectively) compared to previously developed computational pipelines. These performances indicate that VISPA2 is a fast, reliable and user-friendly tool for integration site analysis, which allows gene therapy integration data to be handled in a cost and time effective fashion. Moreover, the web access of VISPA2 ( http://openserver.itb.cnr.it/vispa/ ) ensures accessibility and ease of usage to researches of a complex analytical tool. We released the source code of VISPA2 in a public repository ( https://bitbucket.org/andreacalabria/vispa2 ).

Published

2017