Your search keyword '"Julia Ponomarenko"' showing total 7 results

1. Scalable Design of Paired CRISPR Guide RNAs for Genomic Deletion.

Author

Carlos Pulido-Quetglas, Estel Aparicio-Prat, Carme Arnan, Taisia Polidori, Toni Hermoso, Emilio Palumbo, Julia Ponomarenko, Roderic Guigo, and Rory Johnson

Subjects

Biology (General), QH301-705.5

Abstract

CRISPR-Cas9 technology can be used to engineer precise genomic deletions with pairs of single guide RNAs (sgRNAs). This approach has been widely adopted for diverse applications, from disease modelling of individual loci, to parallelized loss-of-function screens of thousands of regulatory elements. However, no solution has been presented for the unique bioinformatic design requirements of CRISPR deletion. We here present CRISPETa, a pipeline for flexible and scalable paired sgRNA design based on an empirical scoring model. Multiple sgRNA pairs are returned for each target, and any number of targets can be analyzed in parallel, making CRISPETa equally useful for focussed or high-throughput studies. Fast run-times are achieved using a pre-computed off-target database. sgRNA pair designs are output in a convenient format for visualisation and oligonucleotide ordering. We present pre-designed, high-coverage library designs for entire classes of protein-coding and non-coding elements in human, mouse, zebrafish, Drosophila melanogaster and Caenorhabditis elegans. In human cells, we reproducibly observe deletion efficiencies of ≥50% for CRISPETa designs targeting an enhancer and exonic fragment of the MALAT1 oncogene. In the latter case, deletion results in production of desired, truncated RNA. CRISPETa will be useful for researchers seeking to harness CRISPR for targeted genomic deletion, in a variety of model organisms, from single-target to high-throughput scales.

Published

2017

2. Ten Simple Rules on How to Organize a Scientific Retreat.

Author

Julia Ponomarenko, Romina Garrido, and Roderic Guigó

Subjects

Biology (General), QH301-705.5

Published

2017

3. Analysis of Human RSV Immunity at the Molecular Level: Learning from the Past and Present.

Author

Kerrie Vaughan, Julia Ponomarenko, Bjoern Peters, and Alessandro Sette

Subjects

Medicine, Science

Abstract

Human RSV is one of the most prevalent viral pathogens of early childhood for which no vaccine is available. Herein we provide an analysis of RSV epitope data to examine its application to vaccine design and development. Our objective was to provide an overview of antigenic coverage, identify critical antibody and T cell determinants, and then analyze the cumulative RSV epitope data from the standpoint of functional responses using a combinational approach to characterize antigenic structure and epitope location. A review of the cumulative data revealed, not surprisingly, that the vast majority of epitopes have been defined for the two major surface antigens, F and G. Antibody and T cell determinants have been reported from multiple hosts, including those from human subjects following natural infection, however human data represent a minority of the data. A structural analysis of the major surface antigen, F, showed that the majority of epitopes defined for functional antibodies (neutralizing and/or protective) were either shown to bind pre-F or to be accessible in both pre- and post-F forms. This finding may have has implications for on-going vaccine design and development. These interpretations are in agreement with previous work and can be applied in the larger context of functional epitopes on the F protein. It is our hope that this work will provide the basis for further RSV-specific epitope discovery and investigation into the nature of antigen conformation in immunogenicity.

Published

2015

4. An integrative approach to inferring gene regulatory module networks.

Author

Michael Baitaluk, Sergey Kozhenkov, and Julia Ponomarenko

Subjects

Medicine, Science

Abstract

Gene regulatory networks (GRNs) provide insight into the mechanisms of differential gene expression at a system level. However, the methods for inference, functional analysis and visualization of gene regulatory modules and GRNs require the user to collect heterogeneous data from many sources using numerous bioinformatics tools. This makes the analysis expensive and time-consuming.In this work, the BiologicalNetworks application-the data integration and network based research environment-was extended with tools for inference and analysis of gene regulatory modules and networks. The backend database of the application integrates public data on gene expression, pathways, transcription factor binding sites, gene and protein sequences, and functional annotations. Thus, all data essential for the gene regulation analysis can be mined publicly. In addition, the user's data can either be integrated in the database and become public, or kept private within the application. The capabilities to analyze multiple gene expression experiments are also provided.The generated modular networks, regulatory modules and binding sites can be visualized and further analyzed within this same application. The developed tools were applied to the mouse model of asthma and the OCT4 regulatory network in embryonic stem cells. Developed methods and data are available through the Java application from BiologicalNetworks program at http://www.biologicalnetworks.org.

Published

2012

5. Limitations of Ab initio predictions of peptide binding to MHC class II molecules.

Author

Hao Zhang, Peng Wang, Nikitas Papangelopoulos, Ying Xu, Alessandro Sette, Philip E Bourne, Ole Lund, Julia Ponomarenko, Morten Nielsen, and Bjoern Peters

Subjects

Medicine, Science

Abstract

Successful predictions of peptide MHC binding typically require a large set of binding data for the specific MHC molecule that is examined. Structure based prediction methods promise to circumvent this requirement by evaluating the physical contacts a peptide can make with an MHC molecule based on the highly conserved 3D structure of peptide:MHC complexes. While several such methods have been described before, most are not publicly available and have not been independently tested for their performance. We here implemented and evaluated three prediction methods for MHC class II molecules: statistical potentials derived from the analysis of known protein structures; energetic evaluation of different peptide snapshots in a molecular dynamics simulation; and direct analysis of contacts made in known 3D structures of peptide:MHC complexes. These methods are ab initio in that they require structural data of the MHC molecule examined, but no specific peptide:MHC binding data. Moreover, these methods retain the ability to make predictions in a sufficiently short time scale to be useful in a real world application, such as screening a whole proteome for candidate binding peptides. A rigorous evaluation of each methods prediction performance showed that these are significantly better than random, but still substantially lower than the best performing sequence based class II prediction methods available. While the approaches presented here were developed independently, we have chosen to present our results together in order to support the notion that generating structure based predictions of peptide:MHC binding without using binding data is unlikely to give satisfactory results.

Published

2010

6. An Integrative Approach to Inferring Gene Regulatory Module Networks

Author

Julia Ponomarenko, Sergey Kozhenkov, and Michael Baitaluk

Subjects

Microarrays, Gene regulatory network, lcsh:Medicine, Inference, Biological Data Management, Computational biology, Biology, computer.software_genre, Computer Applications, Mice, 03 medical and health sciences, 0302 clinical medicine, Databases, Genetic, Animals, Gene Regulatory Networks, lcsh:Science, Gene, 030304 developmental biology, Regulatory Networks, Genetics, Regulation of gene expression, Internet, 0303 health sciences, Multidisciplinary, Software Tools, business.industry, Systems Biology, lcsh:R, Computational Biology, Software Engineering, Genomics, Modular design, Asthma, DNA binding site, Gene Expression Regulation, Computer Science, lcsh:Q, DNA microarray, Genome Expression Analysis, business, Octamer Transcription Factor-3, computer, Software, 030217 neurology & neurosurgery, Research Article, Data integration

Abstract

Background: Gene regulatory networks (GRNs) provide insight into the mechanisms of differential gene expression at a system level. However, the methods for inference, functional analysis and visualization of gene regulatory modules and GRNs require the user to collect heterogeneous data from many sources using numerous bioinformatics tools. This makes the analysis expensive and time-consuming. Results: In this work, the BiologicalNetworks application–the data integration and network based research environment– was extended with tools for inference and analysis of gene regulatory modules and networks. The backend database of the application integrates public data on gene expression, pathways, transcription factor binding sites, gene and protein sequences, and functional annotations. Thus, all data essential for the gene regulation analysis can be mined publicly. In addition, the user’s data can either be integrated in the database and become public, or kept private within the application. The capabilities to analyze multiple gene expression experiments are also provided. Conclusion: The generated modular networks, regulatory modules and binding sites can be visualized and further analyzed within this same application. The developed tools were applied to the mouse model of asthma and the OCT4 regulatory network in embryonic stem cells. Developed methods and data are available through the Java application from BiologicalNetworks program at http://www.biologicalnetworks.org.

Published

2012

7. The Immune Epitope Database and Analysis Resource: From Vision to Blueprint

Author

Mitch Kronenberg, Ole Lund, Huynh-Hoa Bui, Julia Ponomarenko, Phil Bourne, Steve Wilson, Grace Doh, Scott Way, Alessandro Sette, David Nemazee, Scott Stewart, John Sidney, Bjoern Peters, Muthu Sathiamurthy, Stephen P. Schoenberger, Buus Soeren, Ralph T. Kubo, Pamela Surko, and Ward Fleri

Subjects

QH301-705.5, animal diseases, Receptors, Antigen, T-Cell, chemical and pharmacologic phenomena, Biology, Bioinformatics, General Biochemistry, Genetics and Molecular Biology, Epitope, Allergy/Immunology, World Wide Web, Epitopes, Immune Epitope Database and Analysis Resource, Blueprint, Community Page, Biology (General), Databases, Protein, Mammals, Biodefense, General Immunology and Microbiology, Scope (project management), business.industry, General Neuroscience, biochemical phenomena, metabolism, and nutrition, Direct feedback, Bioterrorism, United States, Identification (information), National Institutes of Health (U.S.), bacteria, The Internet, General Agricultural and Biological Sciences, business

Abstract

Recent concerns about bioterrorism and emerging diseases have led to a new focus on the development of vaccines and drugs targeting infectious pathogens. An important component of vaccine development is the characterization of immune responses (to vaccination, for example, or following infection in experimental settings) by evaluating the epitopes recognized by antigen-specific receptors of the immune system (antibodies and/or T cell receptors (TCRs)) [1]. In recent years, different groups have followed different approaches to the discovery of immune epitopes, and various assay types have been used to generate data for the purpose of epitope definition or validation. We believe that research in this area could be greatly facilitated by a comprehensive knowledge center: a repository of immune epitope data with associated analysis tools. Our goal is the creation of the Immune Epitope Database and Analysis Resource (IEDB). The IEDB is sponsored by the National Institute for Allergy and Infectious Diseases (NIAID). It will host data relating to both B cell and T cell epitopes from infectious pathogens, as well as experimental and self-antigens (RTP-NIH-NIAID-DAIT-03/31; www.niaid.nih.gov/contract/archive). Priority will be placed on those epitopes considered to be potential bioterrorism threats, and emerging diseases as defined by NIAID (so-called category A–C pathogens; see: http://www2.niaid.nih.gov/Biodefense/bandc_priority.htm). As a corollary to the IEDB effort, NIAID has also launched a large-scale antibody and T cell epitope discovery program aimed at generating epitope data and analysis resources to be included in the IEDB. Other data sources to be integrated into the IEDB are publications in peer-reviewed journals, published patents or patent applications, and direct submissions from institutions or companies. Everyone who contributes data or analysis resources to the database will be cited, either by authorship or by other acknowledgment of their contributions. The involvement of the scientific community in the design of the scope and capability of the IEDB will be crucial to the success of the project. The IEDB will be produced in a manner that encourages the incorporation of data and analytical tools derived by research labs at-large. With this paper, we hope to inform the scientific community of our effort and to solicit feedback while the project is still in a design stage. We envision that this resource center will be freely available on the Internet, with a prototype operational in the fourth quarter of 2005. Once the project is online, forms for direct feedback and online submission of data and tools will be provided. Yearly conferences to present data relating to epitope identification and the IEDB itself will be organized, and a newsletter will be published quarterly.

Published

2005