Your search keyword '"Jocelyne DiRuggiero"' showing total 4 results

1. Current progress and future opportunities in applications of bioinformatics for biodefense and pathogen detection: report from the Winter Mid-Atlantic Microbiome Meet-up, College Park, MD, January 10, 2018

Author

Jacquelyn S. Meisel, Daniel J. Nasko, Brian Brubach, Victoria Cepeda-Espinoza, Jessica Chopyk, Héctor Corrada-Bravo, Marcus Fedarko, Jay Ghurye, Kiran Javkar, Nathan D. Olson, Nidhi Shah, Sarah M. Allard, Adam L. Bazinet, Nicholas H. Bergman, Alexis Brown, J. Gregory Caporaso, Sean Conlan, Jocelyne DiRuggiero, Samuel P. Forry, Nur A. Hasan, Jason Kralj, Paul M. Luethy, Donald K. Milton, Brian D. Ondov, Sarah Preheim, Shashikala Ratnayake, Stephanie M. Rogers, M. J. Rosovitz, Eric G. Sakowski, Nils Oliver Schliebs, Daniel D. Sommer, Krista L. Ternus, Gherman Uritskiy, Sean X. Zhang, Mihai Pop, and Todd J. Treangen

Subjects

Microbiome, Metagenomics, Bioinformatics, Biodefense, Biothreats, Pathogen detection, Microbial ecology, QR100-130

Abstract

Abstract The Mid-Atlantic Microbiome Meet-up (M3) organization brings together academic, government, and industry groups to share ideas and develop best practices for microbiome research. In January of 2018, M3 held its fourth meeting, which focused on recent advances in biodefense, specifically those relating to infectious disease, and the use of metagenomic methods for pathogen detection. Presentations highlighted the utility of next-generation sequencing technologies for identifying and tracking microbial community members across space and time. However, they also stressed the current limitations of genomic approaches for biodefense, including insufficient sensitivity to detect low-abundance pathogens and the inability to quantify viable organisms. Participants discussed ways in which the community can improve software usability and shared new computational tools for metagenomic processing, assembly, annotation, and visualization. Looking to the future, they identified the need for better bioinformatics toolkits for longitudinal analyses, improved sample processing approaches for characterizing viruses and fungi, and more consistent maintenance of database resources. Finally, they addressed the necessity of improving data standards to incentivize data sharing. Here, we summarize the presentations and discussions from the meeting, identifying the areas where microbiome analyses have improved our ability to detect and manage biological threats and infectious disease, as well as gaps of knowledge in the field that require future funding and focus.

Published

2018

2. MetaWRAP—a flexible pipeline for genome-resolved metagenomic data analysis

Author

Gherman V. Uritskiy, Jocelyne DiRuggiero, and James Taylor

Subjects

Metagenomics, WGS, Metagenome, Binning, Bin, Draft genome, Microbial ecology, QR100-130

Abstract

Abstract Background The study of microbiomes using whole-metagenome shotgun sequencing enables the analysis of uncultivated microbial populations that may have important roles in their environments. Extracting individual draft genomes (bins) facilitates metagenomic analysis at the single genome level. Software and pipelines for such analysis have become diverse and sophisticated, resulting in a significant burden for biologists to access and use them. Furthermore, while bin extraction algorithms are rapidly improving, there is still a lack of tools for their evaluation and visualization. Results To address these challenges, we present metaWRAP, a modular pipeline software for shotgun metagenomic data analysis. MetaWRAP deploys state-of-the-art software to handle metagenomic data processing starting from raw sequencing reads and ending in metagenomic bins and their analysis. MetaWRAP is flexible enough to give investigators control over the analysis, while still being easy-to-install and easy-to-use. It includes hybrid algorithms that leverage the strengths of a variety of software to extract and refine high-quality bins from metagenomic data through bin consolidation and reassembly. MetaWRAP’s hybrid bin extraction algorithm outperforms individual binning approaches and other bin consolidation programs in both synthetic and real data sets. Finally, metaWRAP comes with numerous modules for the analysis of metagenomic bins, including taxonomy assignment, abundance estimation, functional annotation, and visualization. Conclusions MetaWRAP is an easy-to-use modular pipeline that automates the core tasks in metagenomic analysis, while contributing significant improvements to the extraction and interpretation of high-quality metagenomic bins. The bin refinement and reassembly modules of metaWRAP consistently outperform other binning approaches. Each module of metaWRAP is also a standalone component, making it a flexible and versatile tool for tackling metagenomic shotgun sequencing data. MetaWRAP is open-source software available at https://github.com/bxlab/metaWRAP.

Published

2018

3. Current progress and future opportunities in applications of bioinformatics for biodefense and pathogen detection: report from the Winter Mid-Atlantic Microbiome Meet-up, College Park, MD, January 10, 2018

Author

Gherman Uritskiy, Alexis Brown, Eric G. Sakowski, Brian Brubach, Todd J. Treangen, Marcus W. Fedarko, Kiran Javkar, Mihai Pop, Shashikala Ratnayake, Nathan D. Olson, Samuel P. Forry, Paul M. Luethy, Jay Ghurye, Hector Corrada-Bravo, J. Gregory Caporaso, Jacquelyn S. Meisel, Donald K. Milton, Sarah P. Preheim, Daniel J. Nasko, Adam L. Bazinet, Sean X. Zhang, Nicholas H. Bergman, Jason G. Kralj, Nur A. Hasan, Nils Oliver Schliebs, Victoria Cepeda-Espinoza, Sarah M. Allard, Jessica Chopyk, Stephanie M. Rogers, M. J. Rosovitz, Daniel D. Sommer, Nidhi Shah, Brian D. Ondov, Jocelyne DiRuggiero, Sean Conlan, and Krista Ternus

Subjects

0301 basic medicine, Microbiology (medical), Pathogen detection, Bioinformatics, Best practice, Biology, Meeting Report, Microbiology, lcsh:Microbial ecology, 03 medical and health sciences, Biodefense, Microbiome, business.industry, Biothreats, Longitudinal analysis, Usability, Data sharing, 030104 developmental biology, Infectious disease (medical specialty), Metagenomics, lcsh:QR100-130, business

Abstract

The Mid-Atlantic Microbiome Meet-up (M3) organization brings together academic, government, and industry groups to share ideas and develop best practices for microbiome research. In January of 2018, M3 held its fourth meeting, which focused on recent advances in biodefense, specifically those relating to infectious disease, and the use of metagenomic methods for pathogen detection. Presentations highlighted the utility of next-generation sequencing technologies for identifying and tracking microbial community members across space and time. However, they also stressed the current limitations of genomic approaches for biodefense, including insufficient sensitivity to detect low-abundance pathogens and the inability to quantify viable organisms. Participants discussed ways in which the community can improve software usability and shared new computational tools for metagenomic processing, assembly, annotation, and visualization. Looking to the future, they identified the need for better bioinformatics toolkits for longitudinal analyses, improved sample processing approaches for characterizing viruses and fungi, and more consistent maintenance of database resources. Finally, they addressed the necessity of improving data standards to incentivize data sharing. Here, we summarize the presentations and discussions from the meeting, identifying the areas where microbiome analyses have improved our ability to detect and manage biological threats and infectious disease, as well as gaps of knowledge in the field that require future funding and focus. Electronic supplementary material The online version of this article (10.1186/s40168-018-0582-5) contains supplementary material, which is available to authorized users.

Published

2018

4. Colonization patterns of soil microbial communities in the Atacama Desert

Author

Jocelyne DiRuggiero, Bruno Jedynak, Alexander Crits-Christoph, Alfonso F. Davila, Courtney K. Robinson, W. Florian Fricke, Tyler P. Barnum, and Christopher P. McKay

Subjects

Microbiology (medical), Soil test, Biology, Microbiology, High-throughput 16S rRNA sequencing, 03 medical and health sciences, Microbial ecology, Extreme environment, Desertification, Atacama Desert, 030304 developmental biology, 2. Zero hunger, Total organic carbon, 0303 health sciences, 030306 microbiology, Ecology, Research, Mineralization (soil science), 15. Life on land, Soil microbial communities, Arid, 6. Clean water, Arid soil, UniFrac, 13. Climate action, Soil water

Abstract

Background The Atacama Desert is one of the driest deserts in the world and its soil, with extremely low moisture, organic carbon content, and oxidizing conditions, is considered to be at the dry limit for life. Results Analyses of high throughput DNA sequence data revealed that bacterial communities from six geographic locations in the hyper-arid core and along a North-South moisture gradient were structurally and phylogenetically distinct (ANOVA test for observed operating taxonomic units at 97% similarity (OTU0.03), P Rubrobacterales, Actinomycetales, Acidimicrobiales, and a number of families from the Thermoleophilia. The extremely low abundance of Firmicutes indicated that most bacteria in the soil were in the form of vegetative cells. Integrating molecular data with climate and soil geochemistry, we found that air relative humidity (RH) and soil conductivity significantly correlated with microbial communities’ diversity metrics (least squares linear regression for observed OTU0.03 and air RH and soil conductivity, P P Conclusions Our results suggest that microorganisms in the driest soils of the Atacama Desert are in a state of stasis for most of the time, but can potentially metabolize if presented with liquid water for a sufficient duration. Over geological time, rare rain events and physicochemical factors potentially played a major role in selecting micro-organisms that are most adapted to extreme desiccating conditions.

Published

2013