Your search keyword '"Microbial Genomics"' showing total 6,786 results

1. Genomic and phylogenetic characterisation of SARS-CoV-2 genomes isolated in patients from Lambayeque Region, Peru

Author

Aguilar-Martinez, Sergio Luis, Sandoval-Pena, Gustavo Adolfo, Molina-Mora, Jose Arturo, Tsukayama-Cisneros, Pablo, Diaz-Velez, Cristian, Aguilar-Gamboa, Franklin Romulo, Bonilla-Aldana, D Katterine, and RodrIguez-Morales, Alfonso J

Published

2024

2. Potential applications of microbial genomics in nuclear non-proliferation.

Author

MacGregor, Heather, Fukai, Isis, Ash, Kurt, Arkin, Adam Paul, and Hazen, Terry C.

Subjects

FUEL cycle, NUCLEAR nonproliferation, MACHINE learning, NUCLEAR facilities, RADIOACTIVE substances, NUCLEAR energy, NUCLEAR fuels

Abstract

As nuclear technology evolves in response to increased demand for diversification and decarbonization of the energy sector, new and innovative approaches are needed to effectively identify and deter the proliferation of nuclear arms, while ensuring safe development of global nuclear energy resources. Preventing the use of nuclear material and technology for unsanctioned development of nuclear weapons has been a long-standing challenge for the International Atomic Energy Agency and signatories of the Treaty on the Non-Proliferation of Nuclear Weapons. Environmental swipe sampling has proven to be an effective technique for characterizing clandestine proliferation activities within and around known locations of nuclear facilities and sites. However, limited tools and techniques exist for detecting nuclear proliferation in unknown locations beyond the boundaries of declared nuclear fuel cycle facilities, representing a critical gap in non-proliferation safeguards. Microbiomes, defined as "characteristic communities of microorganisms" found in specific habitats with distinct physical and chemical properties, can provide valuable information about the conditions and activities occurring in the surrounding environment. Microorganisms are known to inhabit radionuclide-contaminated sites, spent nuclear fuel storage pools, and cooling systems of water-cooled nuclear reactors, where they can cause radionuclide migration and corrosion of critical structures. Microbial transformation of radionuclides is a well-established process that has been documented in numerous field and laboratory studies. These studies helped to identify key bacterial taxa and microbially-mediated processes that directly and indirectly control the transformation, mobility, and fate of radionuclides in the environment. Expanding on this work, other studies have used microbial genomics integrated with machine learning models to successfully monitor and predict the occurrence of heavy metals, radionuclides, and other process wastes in the environment, indicating the potential role of nuclear activities in shaping microbial community structure and function. Results of this previous body of work suggest fundamental geochemical-microbial interactions occurring at nuclear fuel cycle facilities could give rise to microbiomes that are characteristic of nuclear activities. These microbiomes could provide valuable information for monitoring nuclear fuel cycle facilities, planning environmental sampling campaigns, and developing biosensor technology for the detection of undisclosed fuel cycle activities and proliferation concerns. [ABSTRACT FROM AUTHOR]

Published

2024

3. Lung microbiota: implications and interactions in chronic pulmonary diseases.

Author

Jing Zhou, Wang Hou, Huilin Zhong, and Dan Liu

Subjects

CHRONIC obstructive pulmonary disease, IDIOPATHIC pulmonary fibrosis, LUNG diseases, MICROBIAL genomics, POLLUTANTS

Abstract

The lungs, as vital organs in the human body, continuously engage in gas exchange with the external environment. The lung microbiota, a critical component in maintaining internal homeostasis, significantly influences the onset and progression of diseases. Beneficial interactions between the host and its microbial community are essential for preserving the host's health, whereas disease development is often linked to dysbiosis or alterations in the microbial community. Evidence has demonstrated that changes in lung microbiota contribute to the development of major chronic lung diseases, including chronic obstructive pulmonary disease (COPD), idiopathic pulmonary fibrosis (IPF), asthma, and lung cancer. However, in-depth mechanistic studies are constrained by the small scale of the lung microbiota and its susceptibility to environmental pollutants and other factors, leaving many questions unanswered. This review examines recent research on the lung microbiota and lung diseases, as well as methodological advancements in studying lung microbiota, summarizing the ways in which lung microbiota impacts lung diseases and introducing research methods for investigating lung microbiota. [ABSTRACT FROM AUTHOR]

Published

2024

4. From raw milk cheese to the gut: investigating the colonization strategies of Bifidobacterium mongoliense.

Author

Longhi, Giulia, Lugli, Gabriele Andrea, Tarracchini, Chiara, Fontana, Federico, Bianchi, Massimiliano Giovanni, Carli, Elisa, Bussolati, Ovidio, van Sinderen, Douwe, Turroni, Francesca, and Ventura, Marco

Subjects

*COMPARATIVE genomics, *MICROBIAL genomics, *MICROBIAL ecology, *GENE expression, *COLONIZATION (Ecology), *RAW milk

Abstract

The microbial ecology of raw milk cheeses is determined by bacteria originating from milk and milk-producing animals. Recently, it has been shown that members of the Bifidobacterium mongoliense species may become transmitted along the Parmigiano Reggiano cheese production chain and ultimately may colonize the consumer intestine. However, there is a lack of knowledge regarding the molecular mechanisms that mediate the interaction between B. mongoliense and the human gut. Based on 128 raw milk cheeses collected from different Italian regions, we isolated and characterized 10 B. mongoliense strains. Comparative genomics allowed us to unveil the presence of enzymes required for the degradation of sialylated host-glycans in B. mongoliense, corroborating the appreciable growth on de Man-Rogosa-Sharpe (MRS) medium supplemented with 3'-sialyllactose (3'-SL) or 6'-sialyllactose (6'-SL). The B. mongoliense BMONG18 was chosen, due to its superior ability to utilize 3'-SL and mucin as representative strain, to investigate its behavior when co-inoculated with other bifidobacterial species. Conversely, members of other bifidobacterial species did not appear to benefit from the presence of BMONG18, highlighting a competitive scenario for nutrient acquisition. Transcriptomic data of BMONG18 reveal no significant differences in gene expression when cultivated in a gut simulating medium (GSM), regardless of whether cheese was included or not. Furthermore, BMONG18 was shown to exhibit high adhesion capabilities to HT29-MTX human cells, in line with its colonization ability of a human host. [ABSTRACT FROM AUTHOR]

Published

2024

5. Compression rates of microbial genomes are associated with genome size and base composition

Author

Jon Bohlin and John H.-O. Pettersson

Subjects

MBGC, ZPAQ, Microbial Genomics, Compression, Information potential, Base composition, Genetics, QH426-470

Abstract

Abstract Background To what degree a string of symbols can be compressed reveals important details about its complexity. For instance, strings that are not compressible are random and carry a low information potential while the opposite is true for highly compressible strings. We explore to what extent microbial genomes are amenable to compression as they vary considerably both with respect to size and base composition. For instance, microbial genome sizes vary from less than 100,000 base pairs in symbionts to more than 10 million in soil-dwellers. Genomic base composition, often summarized as genomic AT or GC content due to the similar frequencies of adenine and thymine on one hand and cytosine and guanine on the other, also vary substantially; the most extreme microbes can have genomes with AT content below 25% or above 85% AT. Base composition determines the frequency of DNA words, consisting of multiple nucleotides or oligonucleotides, and may therefore also influence compressibility. Using 4,713 RefSeq genomes, we examined the association between compressibility, using both a DNA based- (MBGC) and a general purpose (ZPAQ) compression algorithm, and genome size, AT content as well as genomic oligonucleotide usage variance (OUV) using generalized additive models. Results We find that genome size (p

Published

2024

6. An unusual two-strain cholera outbreak in Lebanon, 2022-2023: a genomic epidemiology study.

Author

Abou Fayad, Antoine, Rafei, Rayane, Njamkepo, Elisabeth, Ezzeddine, Jana, Hussein, Hadi, Sinno, Solara, Gerges, Jose-Rita, Barada, Sara, Sleiman, Ahmad, Assi, Moubadda, Baakliny, Maryo, Hamedeh, Lama, Mahfouz, Rami, Dabboussi, Fouad, Feghali, Rita, Mohsen, Zeina, Rady, Alisar, Ghosn, Nada, Abiad, Firas, and Abubakar, Abdinasir

Subjects

VIBRIO cholerae, MICROBIAL genomics, CHOLERA, DRUG resistance in bacteria, EPIDEMIOLOGY

Abstract

Cholera is a life-threatening gastrointestinal infection caused by a toxigenic bacterium, Vibrio cholerae. After a lull of almost 30 years, a first case of cholera was detected in Lebanon in October 2022. The outbreak lasted three months, with 8007 suspected cases (671 laboratory-confirmed) and 23 deaths. In this study, we use phenotypic methods and microbial genomics to study 34 clinical and environmental Vibrio cholerae isolates collected throughout this outbreak. All isolates are identified as V. cholerae O1, serotype Ogawa strains from wave 3 of the seventh pandemic El Tor (7PET) lineage. Phylogenomic analysis unexpectedly reveals the presence of two different strains of the seventh pandemic El Tor (7PET) lineage. The dominant strain has a narrow antibiotic resistance profile and is phylogenetically related to South Asian V. cholerae isolates and derived African isolates from the AFR15 sublineage. The second strain is geographically restricted and extensively drug-resistant. It belongs to the AFR13 sublineage and clusters with V. cholerae isolates collected in Yemen. In conclusion, the 2022-2023 Lebanese cholera outbreak is caused by the simultaneous introduction of two different 7PET strains. Genomic surveillance with cross-border collaboration is therefore crucial for the identification of new introductions and routes of circulation of cholera, improving our understanding of cholera epidemiology. Here the authors provide results from a genomic epidemiology study of a cholera outbreak in Lebanon, showing that it was caused by two Vibrio cholerae strains of serogroup O1 (El Tor biotype), namely an AFR15 sublineage related to South Asian isolates and extensively drug-resistant Yemeni AFR13. [ABSTRACT FROM AUTHOR]

Published

2024

7. AMRomics: a scalable workflow to analyze large microbial genome collections.

Author

Le, Duc Quang, Nguyen, Tam Thi, Nguyen, Canh Hao, Ho, Tho Huu, Vo, Nam S., Nguyen, Trang, Nguyen, Hoang Anh, Vinh, Le Sy, Dang, Thanh Hai, Cao, Minh Duc, and Nguyen, Son Hoang

Subjects

*MICROBIAL genomes, *MICROBIAL genomics, *OPEN source software, *BACTERIAL population, *TURNAROUND time

Abstract

Whole genome analysis for microbial genomics is critical to studying and monitoring antimicrobial resistance strains. The exponential growth of microbial sequencing data necessitates a fast and scalable computational pipeline to generate the desired outputs in a timely and cost-effective manner. Recent methods have been implemented to integrate individual genomes into large collections of specific bacterial populations and are widely employed for systematic genomic surveillance. However, they do not scale well when the population expands and turnaround time remains the main issue for this type of analysis. Here, we introduce AMRomics, an optimized microbial genomics pipeline that can work efficiently with big datasets. We use different bacterial data collections to compare AMRomics against competitive tools and show that our pipeline can generate similar results of interest but with better performance. The software is open source and is publicly available at https://github.com/amromics/amromics under an MIT license. [ABSTRACT FROM AUTHOR]

Published

2024

8. Reusable tutorials for using cloud-based computing environments for the analysis of bacterial gene expression data from bulk RNA sequencing.

Author

Allers, Steven, O'Connell, Kyle A, Carlson, Thad, Belardo, David, and King, Benjamin L

Subjects

*GENE expression, *BACTERIAL genes, *CLOUD computing, *DATA science, *DATA analysis

Abstract

This manuscript describes the development of a resource module that is part of a learning platform named "NIGMS Sandbox for Cloud-based Learning" https://github.com/NIGMS/NIGMS-Sandbox. The overall genesis of the Sandbox is described in the editorial NIGMS Sandbox at the beginning of this Supplement. This module delivers learning materials on RNA sequencing (RNAseq) data analysis in an interactive format that uses appropriate cloud resources for data access and analyses. Biomedical research is increasingly data-driven, and dependent upon data management and analysis methods that facilitate rigorous, robust, and reproducible research. Cloud-based computing resources provide opportunities to broaden the application of bioinformatics and data science in research. Two obstacles for researchers, particularly those at small institutions, are: (i) access to bioinformatics analysis environments tailored to their research; and (ii) training in how to use Cloud-based computing resources. We developed five reusable tutorials for bulk RNAseq data analysis to address these obstacles. Using Jupyter notebooks run on the Google Cloud Platform, the tutorials guide the user through a workflow featuring an RNAseq dataset from a study of prophage altered drug resistance in Mycobacterium chelonae. The first tutorial uses a subset of the data so users can learn analysis steps rapidly, and the second uses the entire dataset. Next, a tutorial demonstrates how to analyze the read count data to generate lists of differentially expressed genes using R/DESeq2. Additional tutorials generate read counts using the Snakemake workflow manager and Nextflow with Google Batch. All tutorials are open-source and can be used as templates for other analysis. [ABSTRACT FROM AUTHOR]

Published

2024

9. Editorial: Microbial comparative genomics and pangenomics: new tools, approaches and insights into gene and genome evolution

Author

Digvijay Verma, Tulasi Satyanarayana, and Paulo Jorge Dias

Subjects

pangenomics, microbial genomics, next-generation sequencing, whole genome sequencing, metagenome, Genetics, QH426-470

Published

2024

10. Potential applications of microbial genomics in nuclear non-proliferation

Author

Heather MacGregor, Isis Fukai, Kurt Ash, Adam Paul Arkin, and Terry C. Hazen

Subjects

radionuclides, microbial genomics, nuclear non-proliferation, environmental bioindicators, microbial ecology, systems biology, Microbiology, QR1-502

Abstract

As nuclear technology evolves in response to increased demand for diversification and decarbonization of the energy sector, new and innovative approaches are needed to effectively identify and deter the proliferation of nuclear arms, while ensuring safe development of global nuclear energy resources. Preventing the use of nuclear material and technology for unsanctioned development of nuclear weapons has been a long-standing challenge for the International Atomic Energy Agency and signatories of the Treaty on the Non-Proliferation of Nuclear Weapons. Environmental swipe sampling has proven to be an effective technique for characterizing clandestine proliferation activities within and around known locations of nuclear facilities and sites. However, limited tools and techniques exist for detecting nuclear proliferation in unknown locations beyond the boundaries of declared nuclear fuel cycle facilities, representing a critical gap in non-proliferation safeguards. Microbiomes, defined as “characteristic communities of microorganisms” found in specific habitats with distinct physical and chemical properties, can provide valuable information about the conditions and activities occurring in the surrounding environment. Microorganisms are known to inhabit radionuclide-contaminated sites, spent nuclear fuel storage pools, and cooling systems of water-cooled nuclear reactors, where they can cause radionuclide migration and corrosion of critical structures. Microbial transformation of radionuclides is a well-established process that has been documented in numerous field and laboratory studies. These studies helped to identify key bacterial taxa and microbially-mediated processes that directly and indirectly control the transformation, mobility, and fate of radionuclides in the environment. Expanding on this work, other studies have used microbial genomics integrated with machine learning models to successfully monitor and predict the occurrence of heavy metals, radionuclides, and other process wastes in the environment, indicating the potential role of nuclear activities in shaping microbial community structure and function. Results of this previous body of work suggest fundamental geochemical-microbial interactions occurring at nuclear fuel cycle facilities could give rise to microbiomes that are characteristic of nuclear activities. These microbiomes could provide valuable information for monitoring nuclear fuel cycle facilities, planning environmental sampling campaigns, and developing biosensor technology for the detection of undisclosed fuel cycle activities and proliferation concerns.

Published

2024

11. Crosstalk between 6-methyladenine and 4-methylcytosine in Geobacter sulfurreducens exposed to extremely low-frequency electromagnetic field

Author

Zhenhua Shi, Yingrong Zhang, Wanqiu Chen, and Zhen Yu

Subjects

Exposure, Electromagnetic field, Epigenetics, Microbial genomics, Molecular microbiology, Science

Abstract

Summary: 4-Methylcytosine (4mC) and 6-methyladenine (6mA) are the most prevalent types of DNA modifications in prokaryotes. However, whether there is crosstalk between 4mC and 6mA remain unknown. Here, methylomes and transcriptomes of Geobacter sulfurreducens exposed to different intensities of extremely low frequency electromagnetic fields (ELF-EMF) were investigated. Results showed that the second adenine of all the 5′-GTACAG-3′ motif was modified to 6mA (M-6mA). For the other 6mA (O-6mA), the variation in their distance from the neighboring M-6mA increased with the intensity of ELF-EMF. Moreover, cytosine adjacent to O-6mA has a much higher probability of being modified to 4mC than cytosine adjacent to M-6mA, and the closer an unmodified cytosine is to 4mC, the higher the probability that the cytosine will be modified to 4mC. Furthermore, there was no significant correlation between DNA methylation and gene expression regulation. These results suggest a reference signal that goes from M-6mA to O-6mA to 4mC.

Published

2024

12. Role and Relation of Microbiome to Address Antimicrobial Resistance

Author

Bhattacharya, Chandrima, Dinc, Mehmed Taha, Basu, Srijani, Chaudhuri, Riddhi, Fu, Chenlian, Cervantes, Gresia, Adhikari, Upasana Das, Panja, Rupobrata, Qiu, Jake, Aditya, Anusha, Mason, Christopher E., Soni, Vijay, editor, and Akhade, Ajay Suresh, editor

Published

2024

13. AMRViz enables seamless genomics analysis and visualization of antimicrobial resistance

Author

Duc Quang Le, Son Hoang Nguyen, Tam Thi Nguyen, Canh Hao Nguyen, Tho Huu Ho, Nam S. Vo, Trang Nguyen, Hoang Anh Nguyen, and Minh Duc Cao

Subjects

Microbial genomics, Visualization, Antimicrobial resistance, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract We have developed AMRViz, a toolkit for analyzing, visualizing, and managing bacterial genomics samples. The toolkit is bundled with the current best practice analysis pipeline allowing researchers to perform comprehensive analysis of a collection of samples directly from raw sequencing data with a single command line. The analysis results in a report showing the genome structure, genome annotations, antibiotic resistance and virulence profile for each sample. The pan-genome of all samples of the collection is analyzed to identify core- and accessory-genes. Phylogenies of the whole genome as well as all gene clusters are also generated. The toolkit provides a web-based visualization dashboard allowing researchers to interactively examine various aspects of the analysis results. Availability: AMRViz is implemented in Python and NodeJS, and is publicly available under open source MIT license at https://github.com/amromics/amrviz .

Published

2024

14. AMRViz enables seamless genomics analysis and visualization of antimicrobial resistance.

Author

Le, Duc Quang, Nguyen, Son Hoang, Nguyen, Tam Thi, Nguyen, Canh Hao, Ho, Tho Huu, Vo, Nam S., Nguyen, Trang, Nguyen, Hoang Anh, and Cao, Minh Duc

Subjects

*DRUG resistance in microorganisms, *GENOMICS, *DATA visualization, *DRUG resistance in bacteria, *PAN-genome

Abstract

We have developed AMRViz, a toolkit for analyzing, visualizing, and managing bacterial genomics samples. The toolkit is bundled with the current best practice analysis pipeline allowing researchers to perform comprehensive analysis of a collection of samples directly from raw sequencing data with a single command line. The analysis results in a report showing the genome structure, genome annotations, antibiotic resistance and virulence profile for each sample. The pan-genome of all samples of the collection is analyzed to identify core- and accessory-genes. Phylogenies of the whole genome as well as all gene clusters are also generated. The toolkit provides a web-based visualization dashboard allowing researchers to interactively examine various aspects of the analysis results. Availability: AMRViz is implemented in Python and NodeJS, and is publicly available under open source MIT license at https://github.com/amromics/amrviz. [ABSTRACT FROM AUTHOR]

Published

2024

15. AnnoView enables large-scale analysis, comparison, and visualization of microbial gene neighborhoods.

Author

Wei, Xin, Tan, Huagang, Lobb, Briallen, Zhen, William, Wu, Zijing, Parks, Donovan H, Neufeld, Josh D, Moreno-Hagelsieb, Gabriel, and Doxey, Andrew C

Subjects

*MICROBIAL genes, *BACTERIAL genomes, *NEIGHBORHOODS, *MICROBIAL genomes, *WEB design, *INTERNET servers

Abstract

The analysis and comparison of gene neighborhoods is a powerful approach for exploring microbial genome structure, function, and evolution. Although numerous tools exist for genome visualization and comparison, genome exploration across large genomic databases or user-generated datasets remains a challenge. Here, we introduce AnnoView, a web server designed for interactive exploration of gene neighborhoods across the bacterial and archaeal tree of life. Our server offers users the ability to identify, compare, and visualize gene neighborhoods of interest from 30 238 bacterial genomes and 1672 archaeal genomes, through integration with the comprehensive Genome Taxonomy Database and AnnoTree databases. Identified gene neighborhoods can be visualized using pre-computed functional annotations from different sources such as KEGG, Pfam and TIGRFAM, or clustered based on similarity. Alternatively, users can upload and explore their own custom genomic datasets in GBK, GFF or CSV format, or use AnnoView as a genome browser for relatively small genomes (e.g. viruses and plasmids). Ultimately, we anticipate that AnnoView will catalyze biological discovery by enabling user-friendly search, comparison, and visualization of genomic data. AnnoView is available at http://annoview.uwaterloo.ca [ABSTRACT FROM AUTHOR]

Published

2024

16. Microbial Diversity and Open Questions about the Deep Tree of Life.

Author

Eme, Laura and Tamarit, Daniel

Subjects

*OPEN-ended questions, *MICROORGANISMS, *MICROBIAL diversity, *MICROBIAL genomics, *GENOMICS

Abstract

In this perspective, we explore the transformative impact and inherent limitations of metagenomics and single-cell genomics on our understanding of microbial diversity and their integration into the Tree of Life. We delve into the key challenges associated with incorporating new microbial lineages into the Tree of Life through advanced phylogenomic approaches. Additionally, we shed light on enduring debates surrounding various aspects of the microbial Tree of Life, focusing on recent advances in some of its deepest nodes, such as the roots of bacteria, archaea, and eukaryotes. We also bring forth current limitations in genome recovery and phylogenomic methodology, as well as new avenues of research to uncover additional key microbial lineages and resolve the shape of the Tree of Life. [ABSTRACT FROM AUTHOR]

Published

2024

17. Chromosome-scale genome assembly reveals insights into the evolution and ecology of the harmful algal bloom species Phaeocystis globosa Scherffel

Author

Nansheng Chen, Qing Xu, Jianan Zhu, Huiyin Song, Liyan He, Shuya Liu, Xiuxian Song, Yongquan Yuan, Yang Chen, Xihua Cao, and Zhiming Yu

Subjects

Environmental science, Ecology, Microbiology, Microbial genomics, Evolutionary ecology, Aquatic biology, Science

Abstract

Summary: The phytoplankton Phaeocystis globosa plays an important role in sulfur cycling and climate control, and can develop harmful algal blooms (HABs). Here we report a chromosome-scale reference genome assembly of P. globosa, which enable in-depth analysis of molecular underpinnings of important ecological characteristics. Comparative genomic analyses detected two-rounds of genome duplications that may have fueled evolutionary innovations. The genome duplication may have resulted in the formation of dual HiDP and LoDP dimethylsulphoniopropionate (DMSP) biosynthesis pathways in P. globosa. Selective gene family expansions may have strengthened biological pathways critical for colonial formation that is often associated with the development of algal blooms. The copy numbers of rhodopsin genes are variable in different strains, suggesting that rhodopsin genes may play a role in strain-specific adaptation to ecological factors. The successful reconstruction of the P. globosa genome sets up an excellent platform that facilitates in-depth research on bloom development and DMSP metabolism.

Published

2024

18. Genomic analysis of Staphylococcus aureus isolates from bacteremia reveals genetic features associated with the COVID-19 pandemic

Author

Miquel Sánchez-Osuna, Marc Pedrosa, Paula Bierge, Inmaculada Gómez-Sánchez, Marina Alguacil-Guillén, Mateu Espasa, Ivan Erill, Oriol Gasch, and Oscar Q. Pich

Subjects

Evolutionary mechanisms, Genomic analysis, Microbial genomics, Science

Abstract

Summary: Genomic analyses of bacterial isolates are effective to compare the prevalence of antibiotic resistance genes and virulence determinants in different contexts. This study provides a comprehensive genomic description of 339 Staphylococcus aureus strains isolated from patients with bacteremia (2014–2022). Nosocomial acquisition accounted for 56.6% of cases, with vascular catheters being the main infection source (31.8%). Fatality (27.4%), persistent bacteremia (19.5%), and septic emboli (24.2%) were documented. During the COVID-19 pandemic, S. aureus bacteremia episodes increased by 140%. Genetic features in pandemic isolates revealed higher prevalence of methicillin (mecA) and macrolide (msrA and mphC) resistance genes. Additionally, genes encoding clumping factors A and B, involved in fibrinogen binding, were more prevalent. This was linked to extensive macrolide use in COVID-19 accessory therapy and elevated fibrinogen levels in SARS-CoV-2 infection. These findings highlight S. aureus adaptation to COVID-19 selective pressures and the value of whole-genome sequencing in molecular epidemiology studies.

Published

2024

19. zDB: bacterial comparative genomics made easy

Author

Bastian Marquis, Trestan Pillonel, Alessia Carrara, and Claire Bertelli

Subjects

comparative genomics, microbial genomics, genome visualization, Microbiology, QR1-502

Abstract

ABSTRACT The analysis and comparison of genomes rely on different tools for tasks such as annotation, orthology prediction, and phylogenetic inference. Most tools are specialized for a single task, and additional efforts are necessary to integrate and visualize the results. To fill this gap, we developed zDB, an application integrating a Nextflow analysis pipeline and a Python visualization platform built on the Django framework. The application is available on GitHub (https://github.com/metagenlab/zDB) and from the bioconda channel. Starting from annotated Genbank files, zDB identifies orthologs and infers a phylogeny for each orthogroup. A species phylogeny is also constructed from shared single-copy orthologs. The results can be enriched with Pfam protein domain prediction, Cluster of Orthologs Genes and Kyoto Encyclopedia of Genes and Genomes annotations, and Swissprot homologs. The web application allows searching for specific genes or annotations, running Blast queries, and comparing genomic regions and whole genomes. The metabolic capacities of organisms can be compared at either the module or pathway levels. Finally, users can run queries to examine the conservation of specific genes or annotations across a chosen subset of genomes and display the results as a list of genes, Venn diagram, or heatmaps. Those features make zDB useful for both bioinformaticians and researchers more accustomed to laboratory research.IMPORTANCEGenome comparison and analysis rely on many independent tools, leaving to scientists the burden to integrate and visualize their results for interpretation. To alleviate this burden, we have built zDB, a comparative genomics tool that includes both an analysis pipeline and a visualization platform. The analysis pipeline automates gene annotation, orthology prediction, and phylogenetic inference, while the visualization platform allows scientists to easily explore the results in a web browser. Among other features, the interface allows users to visually compare whole genomes and targeted regions, assess the conservation of genes or metabolic pathways, perform Blast searches, or look for specific annotations. Altogether, this tool will be useful for a broad range of applications in comparative studies between two and hundred genomes. Furthermore, it is designed to allow sharing of data sets easily at a local or international scale, thereby supporting exploratory analyses for non-bioinformaticians on the genome of their favorite organisms.

Published

2024

20. Effect of time-restricted eating regimen on weight loss is mediated by gut microbiome

Author

Chensihan Huang, Deying Liu, Shunyu Yang, Yan Huang, Xueyun Wei, Peizhen Zhang, Jiayang Lin, Bingyan Xu, Yating Liu, Dan Guo, Yafeng Li, Jin Li, and Huijie Zhang

Subjects

Human metabolism, Microbial genomics, Microbiome, Physiology, Science

Abstract

Summary: Time-restricted eating (TRE) is a promising obesity management strategy, but weight-loss efficacy varies among participants, and the underlying mechanism is unclear. The study aimed to investigate the role of gut microbiota in weight-loss response during long-term TRE intervention. We analyzed data from 51 obese adults in a 12-month TRE program, categorizing them into distinct weight loss groups (DG) and moderate weight loss groups (MG) based on their TRE responses. Shotgun metagenomic sequencing analysis revealed a significant increase in species closely associated with weight loss effectiveness and metabolic parameter changes in the DG group. Pathways related to fatty acid biosynthesis, glycogen biosynthesis, and nucleotide metabolism were reduced in the DG group and enhanced in the MG group. Next, we identified nine specific species at baseline that contributed better responses to TRE intervention and significant weight loss. Collectively, gut microbiota contributes to responsiveness heterogeneity in TRE and can predict weight-loss effectiveness.

Published

2024

21. Evolution of zygomycete secretomes and the origins of terrestrial fungal ecologies

Author

Chang, Ying, Wang, Yan, Mondo, Stephen, Ahrendt, Steven, Andreopoulos, William, Barry, Kerrie, Beard, Jeff, Benny, Gerald L, Blankenship, Sabrina, Bonito, Gregory, Cuomo, Christina, Desiro, Alessandro, Gervers, Kyle A, Hundley, Hope, Kuo, Alan, LaButti, Kurt, Lang, B Franz, Lipzen, Anna, O'Donnell, Kerry, Pangilinan, Jasmyn, Reynolds, Nicole, Sandor, Laura, Smith, Matthew E, Tsang, Adrian, Grigoriev, Igor V, Stajich, Jason E, and Spatafora, Joseph W

Subjects

Microbiology, Biological Sciences, Evolutionary Biology, 2.2 Factors relating to the physical environment, Biological sciences, microbial genomics, microbial metabolism, microbiology, omics

Abstract

Fungi survive in diverse ecological niches by secreting proteins and other molecules into the environment to acquire food and interact with various biotic and abiotic stressors. Fungal secretome content is, therefore, believed to be tightly linked to fungal ecologies. We sampled 132 genomes from the early-diverging terrestrial fungal lineage zygomycetes (Mucoromycota and Zoopagomycota) and characterized their secretome composition. Our analyses revealed that phylogeny played an important role in shaping the secretome composition of zygomycete fungi with trophic mode contributing a smaller amount. Reconstruction of the evolution of secreted digestive enzymes revealed lineage-specific expansions, indicating that Mucoromycota and Zoopagomycota followed different trajectories early in their evolutionary history. We identified the presence of multiple pathogenicity-related proteins in the lineages known as saprotrophs, suggesting that either the ecologies of these fungi are incompletely known, and/or that these pathogenicity-related proteins have important functions associated with saprotrophic ecologies, both of which invite further investigation.

Published

2022

22. Microbial genomics: a potential toolkit for forensic investigations

Author

Tripathi, Pooja, Render, Riya, Nidhi, Sweta, and Tripathi, Vijay

Published

2024

23. Editorial: Community series-extremophiles: microbial genomics and taxogenomics, volume II.

Author

Antunes, André, de la Haba, Rafael R., Jebbar, Mohamed, and Hedlund, Brian P.

Subjects

MICROBIAL genomics, MICROBIAL communities, ASTROBIOLOGY, METAGENOMICS

Published

2024

24. Exploring Genomics and Microbial Ecology: Analysis of Bidens pilosa L. Genetic Structure and Soil Microbiome Diversity by RAD-Seq and Metabarcoding.

Author

Reyes-Ardila, Wendy Lorena, Rugeles-Silva, Paula Andrea, Duque-Zapata, Juan Diego, Vélez-Martínez, Glever Alexander, Tarazona Pulido, Lina, Cardona Tobar, Karen Melissa, Díaz Gallo, Sergio Alberto, Muñoz Flórez, Jaime Eduardo, Díaz-Ariza, Lucia Ana, and López-Alvarez, Diana

Subjects

MICROBIAL ecology, SOIL structure, MICROBIAL genomics, GENETIC barcoding, SOIL composition

Abstract

Bidens pilosa L., native to South America and commonly used for medicinal purposes, has been understudied at molecular and genomic levels and in its relationship with soil microorganisms. In this study, restriction site-associated DNA markers (RADseq) techniques were implemented to analyze genetic diversity and population structure, and metabarcoding to examine microbial composition in soils from Palmira, Sibundoy, and Bogotá, Colombia. A total of 2,984,123 loci and 3485 single nucleotide polymorphisms (SNPs) were identified, revealing a genetic variation of 12% between populations and 88% within individuals, and distributing the population into three main genetic groups, FST = 0.115 (p < 0.001) and FIT = 0.013 (p > 0.05). In the soil analysis, significant correlations were found between effective cation exchange capacity (ECEC) and apparent density, soil texture, and levels of Mg and Fe, as well as negative correlations between ECEC and Mg, and Mg, Fe, and Ca. Proteobacteria and Ascomycota emerged as the predominant bacterial and fungal phyla, respectively. Analyses of alpha, beta, and multifactorial diversity highlight the influence of ecological and environmental factors on these microbial communities, revealing specific patterns of clustering and association between bacteria and fungi in the studied locations. [ABSTRACT FROM AUTHOR]

Published

2024

25. The military gear microbiome: risk factors surrounding the warfighter.

Author

Kok, Car Reen, Bram, Zakariae, Thissen, James B., Horseman, Timothy S., Fong, Keith S. K., Reichert-Scrivner, Susan A., Paguirigan, Carmen, O'Connor, Kelsey, Thompson, Kristina, Scheiber, Alexander E., Mabery, Shalini, Ngauy, Viseth, Uyehara, Catherine F., and Be, Nicholas A.

Subjects

*MILITARY personnel, *BLAST injuries, *DEPLOYMENT (Military strategy), *SPECIES diversity, *INFECTION control

Abstract

Combat extremity wounds are highly susceptible to contamination from surrounding environmental material. This bioburden could be partially transferred from materials in immediate proximity to the wound, including fragments of the uniform and gear. However, the assessment of the microbial bioburden present on military gear during operational conditions of deployment or training is relatively unexplored. Opportunistic pathogens that can survive on gear represent risk factors for infection following injury, especially following combat blasts, where fibers and other materials are embedded in wounded tissue. We utilized 16S rRNA sequencing to assess the microbiome composition of different military gear types (boot, trouser, coat, and canteen) from two operational environments (training in Hawai'i and deployed in Indonesia) across time (days 0 and 14). We found that microbiome diversity, stability, and composition were dependent on gear type, training location, and sampling timepoint. At day 14, species diversity was significantly higher in Hawai'i samples compared to Indonesia samples for boot, coat, and trouser swabs. In addition, we observed the presence of potential microbial risk factors, as opportunistic pathogenic species, such as Acinetobacter, Pseudomonas, and Staphylococcus, were found to be present in all sample types and in both study sites. These study outcomes will be used to guide the design of antimicrobial materials and uniforms and for infection control efforts following combat blasts and other injuries, thereby improving treatment guidance during military training and deployment. [ABSTRACT FROM AUTHOR]

Published

2024

26. Evolution and diversity of pathogenic Vibrio species of importance in aquaculture

Author

Coyle, Nicola, Feil, Edward, and Martinez-Urtaza, Jaime

Subjects

Vibrio, Aquculture, Microbial genomics, Evolution

Abstract

The advent of whole-genome sequencing (WGS) has provided powerful insights into bacterial evolution, and greatly facilitated the surveillance and management of human and animal pathogens. The application of this technology to aquaculture will become more critical as the industry continues to grow. In this thesis, I describe and analyse novel WGS datasets for 4 pathogenic Vibrio species of importance to aquaculture: specifically V. anguillarum, its close relative V. ordalii, V. aestuarianus (a pathogen of oysters) and representatives of the V. splendidus species complex. In chapters 2 and 3, I describe the genomic diversity within the population of V. anguillarum. I identify thirty-seven lineages within the population, six of which have been sequenced multiple times and likely represent important lineages to the aquaculture industry. In addition, I uncover multiple novel large recombination events that have shaped the evolution of specific lineages. Lastly, I explore lipopolysaccharide and exopolysaccharide biosynthesis genomic islands that are linked to serotype switching events. In chapter 4, I examine strains of V. aestuarianus and the V. splendidus species complex isolated from outbreaks of oyster mortality across Ireland. This revealed that V. aestuarianus isolates detected in Ireland were closely related to two clades previously described in France. Isolates from the V. splendidus species complex were highly dissimilar, with the exception of a small clonal group that was observed in 2009. Lastly, chapter 5 combines genomic datasets from previous chapters to study gene content variation in the V. anguillarum species complex which comprises of V. anguillarum, V. aestuarianus and V. ordalii. This included an evaluation of the application of the pangenome concept to RNA loci and intergenic regions. In addition, this chapter showed that an isolate thought to be intermediate to V. ordalii and V. anguillarum likely represents a pool of more diverse V. anguillarum strains.

Published

2022

27. Long COVID across SARS-CoV-2 variants, lineages, and sublineages

Author

Sergio Padilla, Christian Ledesma, Javier García-Abellán, José Alberto García, Marta Fernández-González, Alba de la Rica, Antonio Galiana, Félix Gutiérrez, and Mar Masiá

Subjects

Biological sciences, Microbiology, Virology, Microbial genomics, Science

Abstract

Summary: This prospective study aimed to determine the prevalence of long COVID in patients hospitalized for SARS-CoV-2 infection from March 2020 to July 2022 and assess the impact of different viral lineages. A total of 2,524 patients were followed up for 12 months, with persistent symptoms reported in 35.2% at one month, decreasing thereafter. Omicron variant patients initially showed higher symptom intensity, but this trend diminished over time. Certain viral lineages, notably Delta lineages AY.126 and AY.43, and Omicron sublineages BA.1.17, BA.2.56, and BA.5.1, consistently correlated with more severe symptoms. Overall, long COVID prevalence and severity were similar across SARS-CoV-2 variants. Specific lineages may influence post-COVID sequelae persistence and severity.

Published

2024

28. Classification of Neisseria meningitidis genomes with a bag-of-words approach and machine learning

Author

Marco Podda, Simone Bonechi, Andrea Palladino, Mattia Scaramuzzino, Alessandro Brozzi, Guglielmo Roma, Alessandro Muzzi, Corrado Priami, Alina Sîrbu, and Margherita Bodini

Subjects

Microbial genomics, Classification of bioinformatical subject, Machine learning, Science

Abstract

Summary: Whole genome sequencing of bacteria is important to enable strain classification. Using entire genomes as an input to machine learning (ML) models would allow rapid classification of strains while using information from multiple genetic elements. We developed a “bag-of-words” approach to encode, using SentencePiece or k-mer tokenization, entire bacterial genomes and analyze these with ML. Initial model selection identified SentencePiece with 8,000 and 32,000 words as the best approach for genome tokenization. We then classified in Neisseria meningitidis genomes the capsule B group genotype with 99.6% accuracy and the multifactor invasive phenotype with 90.2% accuracy, in an independent test set. Subsequently, in silico knockouts of 2,808 genes confirmed that the ML model predictions aligned with our current understanding of the underlying biology. To our knowledge, this is the first ML method using entire bacterial genomes to classify strains and identify genes considered relevant by the classifier.

Published

2024

29. Global genomic analysis of microbial biotransformation of arsenic highlights the importance of arsenic methylation in environmental and human microbiomes

Author

Keren, Ray, Méheust, Raphaël, Santini, Joanne M, Thomas, Alex, West-Roberts, Jacob, Banfield, Jillian F, and Alvarez-Cohen, Lisa

Subjects

Microbiology, Biological Sciences, Genetics, Human Genome, Foodborne Illness, Arsenic, Microbial genomics, Machine Learning, Human microbiome, Numerical and Computational Mathematics, Computation Theory and Mathematics, Biochemistry and cell biology, Applied computing

Abstract

Arsenic is a ubiquitous toxic element, the global cycle of which is highly affected by microbial redox reactions and assimilation into organoarsenic compounds through sequential methylation reactions. While microbial biotransformation of arsenic has been studied for decades, the past years have seen the discovery of multiple new genes related to arsenic metabolism. Still, most studies focus on a small set of key genes or a small set of cultured microorganisms. Here, we leveraged the recently greatly expanded availability of microbial genomes of diverse organisms from lineages lacking cultivated representatives, including those reconstructed from metagenomes, to investigate genetic repertoires of taxonomic and environmental controls on arsenic metabolic capacities. Based on the collection of arsenic-related genes, we identified thirteen distinct metabolic guilds, four of which combine the aio and ars operons. We found that the best studied phyla have very different combinations of capacities than less well-studied phyla, including phyla lacking isolated representatives. We identified a distinct arsenic gene signature in the microbiomes of humans exposed or likely exposed to drinking water contaminated by arsenic and that arsenic methylation is important in soil and in human microbiomes. Thus, the microbiomes of humans exposed to arsenic have the potential to exacerbate arsenic toxicity. Finally, we show that machine learning can predict bacterial arsenic metabolism capacities based on their taxonomy and the environment from which they were sampled.

Published

2022

30. Industrialisation and the environmental exposome: The role in microbial dysbiosis and obesity

Author

Grant-Stegehuis, Narelle and Simonis, Jessica

Published

2023

31. Microbial Genomics and Modulation in Ruminants: An Environmental Perspective with Special Reference to Methane Migration

Author

Debbarma, Sarmistha, Talukdar, Jupi, Sarma, Anindita, Maurya, Prabhakar, Deka, Dipak, Barkalita, Luit, Malik, Yashpal Singh, Series Editor, Singh, Rameshwar, Editorial Board Member, Gehlot, A. K., Editorial Board Member, Raj, G. Dhinakar, Editorial Board Member, Bujarbaruah, K. M., Editorial Board Member, Goyal, Sagar M., Editorial Board Member, Tikoo, Suresh K., Editorial Board Member, Mukhopadhyay, Chandra Sekhar, editor, Choudhary, Ratan Kumar, editor, and Panwar, Harsh, editor

Published

2023

32. Microbial Genomics and Antimicrobial Susceptibility Testing

Author

Kalambhe, Deepali, K.M., Lokesh, Basak, Gourab, Singh, Sumeet, Jadhao, Abhilash, Malik, Yashpal Singh, Series Editor, Singh, Rameshwar, Editorial Board Member, Gehlot, A. K., Editorial Board Member, Raj, G. Dhinakar, Editorial Board Member, Bujarbaruah, K. M., Editorial Board Member, Goyal, Sagar M., Editorial Board Member, Tikoo, Suresh K., Editorial Board Member, Mukhopadhyay, Chandra Sekhar, editor, Choudhary, Ratan Kumar, editor, and Panwar, Harsh, editor

Published

2023

33. Metagenomic strategies identify diverse integron‐integrase and antibiotic resistance genes in the Antarctic environment

Author

Antelo, Verónica, Giménez, Matías, Azziz, Gastón, Valdespino‐Castillo, Patricia, Falcón, Luisa I, Ruberto, Lucas AM, Cormack, Walter P Mac, Mazel, Didier, and Batista, Silvia

Subjects

Biotechnology, Genetics, Antarctic Regions, Bacteria, Computational Biology, Drug Resistance, Microbial, Genes, Bacterial, High-Throughput Nucleotide Sequencing, Integrases, Integrons, Metagenome, Metagenomics, Phylogeny, Soil Microbiology, antibiotic resistance, bioinformatics, horizontal gene transfer, microbial genomics, Microbiology

Abstract

The objective of this study is to identify and analyze integrons and antibiotic resistance genes (ARGs) in samples collected from diverse sites in terrestrial Antarctica. Integrons were studied using two independent methods. One involved the construction and analysis of intI gene amplicon libraries. In addition, we sequenced 17 metagenomes of microbial mats and soil by high-throughput sequencing and analyzed these data using the IntegronFinder program. As expected, the metagenomic analysis allowed for the identification of novel predicted intI integrases and gene cassettes (GCs), which mostly encode unknown functions. However, some intI genes are similar to sequences previously identified by amplicon library analysis in soil samples collected from non-Antarctic sites. ARGs were analyzed in the metagenomes using ABRIcate with CARD database and verified if these genes could be classified as GCs by IntegronFinder. We identified 53 ARGs in 15 metagenomes, but only four were classified as GCs, one in MTG12 metagenome (Continental Antarctica), encoding an aminoglycoside-modifying enzyme (AAC(6´)acetyltransferase) and the other three in CS1 metagenome (Maritime Antarctica). One of these genes encodes a class D β-lactamase (blaOXA-205) and the other two are located in the same contig. One is part of a gene encoding the first 76 amino acids of aminoglycoside adenyltransferase (aadA6), and the other is a qacG2 gene.

Published

2021

34. Detecting patterns of accessory genome coevolution in Staphylococcus aureus using data from thousands of genomes

Author

Rohan S Mehta, Robert A Petit, Timothy D Read, and Daniel B Weissman

Subjects

Genomics, Genetic interaction, Horizontal gene transfer, Staphylococcus aureus, Software, Microbial genomics, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Bacterial genomes exhibit widespread horizontal gene transfer, resulting in highly variable genome content that complicates the inference of genetic interactions. In this study, we develop a method for detecting coevolving genes from large datasets of bacterial genomes based on pairwise comparisons of closely related individuals, analogous to a pedigree study in eukaryotic populations. We apply our method to pairs of genes from the Staphylococcus aureus accessory genome of over 75,000 annotated gene families using a database of over 40,000 whole genomes. We find many pairs of genes that appear to be gained or lost in a coordinated manner, as well as pairs where the gain of one gene is associated with the loss of the other. These pairs form networks of rapidly coevolving genes, primarily consisting of genes involved in virulence, mechanisms of horizontal gene transfer, and antibiotic resistance, particularly the SCCmec complex. While we focus on gene gain and loss, our method can also detect genes that tend to acquire substitutions in tandem, or genotype-phenotype or phenotype-phenotype coevolution. Finally, we present the R package DeCoTUR that allows for the computation of our method.

Published

2023

35. Compression rates of microbial genomes are associated with genome size and base composition

Author

Bohlin, Jon and Pettersson, John H.-O.

Published

2024

36. Targeted metagenomic assessment reflects critical colonization in battlefield injuries

Author

Car Reen Kok, Nisha Mulakken, James B. Thissen, Scott F. Grey, Aram Avila-Herrera, Meenu M. Upadhyay, Felipe A. Lisboa, Shalini Mabery, Eric A. Elster, Seth A. Schobel, and Nicholas A. Be

Subjects

combat injury, wound infection, antimicrobial resistance, virulence, targeted sequencing, microbial genomics, Microbiology, QR1-502

Abstract

ABSTRACT Current diagnostics and clinical management strategies for combat wounds are based on decisions made by expert clinicians. However, even in the hands of experienced surgeons, wounds from combat injuries can exhibit failed healing and complications related to limitations in the rapid and comprehensive generation of diagnostic information. Previous studies have demonstrated the possible use of genomic sequencing approaches to detect microbial signatures involved in combat casualty care. While effective, whole metagenome sequencing is limited by the depth required to confidently detect all relevant signatures. To address this, we developed a targeted capture sequencing panel to detect microbial signatures relevant to wound healing. These targets include known microbial nosocomial pathogens, wound colonizers, and genes involved in virulence and antimicrobial resistance. A bioinformatics pipeline was built to identify genomic regions of interest and over 8,000 oligonucleotide probes were designed for capture. The panel was synthesized and validated using control reference genomes in human background and on wound-effluent samples from a cohort of combat-injured U.S. service members. Our panel was sensitive against wound-colonizing species, Acinetobacter baumannii and Pseudomonas aeruginosa, and was specific in detecting corresponding virulence and antimicrobial-resistance genes as well as other pathogenic species present in microflora mixtures. Random forest feature permutation confirmed the prevalence of Acinetobacter and Pseudomonas in critically colonized wounds and wounds that failed to heal, respectively. Our results demonstrate the capability of targeted sequencing tools and analysis platforms to profile and deliver information on pathogenic factors influencing wound progression, thereby guiding therapeutic intervention. IMPORTANCE Microbial contamination in combat wounds can lead to opportunistic infections and adverse outcomes. However, current microbiological detection has a limited ability to capture microbial functional genes. This work describes the application of targeted metagenomic sequencing to profile wound bioburden and capture relevant wound-associated signatures for clinical utility. Ultimately, the ability to detect such signatures will help guide clinical decisions regarding wound care and management and aid in the prediction of wound outcomes.

Published

2023

37. The population-level impact of Enterococcus faecalis genetics on intestinal colonization and extraintestinal infection

Author

Chrispin Chaguza, Anna K. Pöntinen, Janetta Top, Sergio Arredondo-Alonso, Ana R. Freitas, Carla Novais, Carmen Torres, Stephen D. Bentley, Luisa Peixe, Teresa M. Coque, Rob J. L. Willems, and Jukka Corander

Subjects

microbial genomics, infectious disease, genome-wide association study, bacteria, Microbiology, QR1-502

Abstract

ABSTRACT Enterococcus faecalis is a commensal bacterium of the human gastrointestinal tract that causes opportunistic infections. The E. faecalis genetic changes associated with pathogenicity, particularly gut-to-bloodstream translocation, remain poorly understood. Here, we performed a genome-wide association study (GWAS) of 736 whole-genome sequences of fecal and bloodstream E. faecalis isolates from hospitalized and nonhospitalized individuals, respectively, to identify E. faecalis genetic signatures associated with the patient’s hospitalization status and body isolation source. We found that infection by hospitalization status and extraintestinal infection are heritable traits, with ~40% and ~30% of their variation explained by E. faecalis genetics, respectively. Furthermore, a GWAS using linear mixed models did not pinpoint any clear overrepresentation of individual genetic changes by hospitalization status or body isolation source after controlling for the population structure. However, we observed elevated signals in a genomic region containing a prophage element. However, the lineages themselves and their associated virulence factors and antibiotic resistance genes showed variable frequency among blood and fecal isolates and in hospitalized and nonhospitalized individuals. Altogether, our findings indicate that E. faecalis infection by hospitalization status and body sites is partially influenced by the overall genetic background of the isolates and antibiotic resistance patterns rather than genetic variation at individual loci, which suggests a greater role of other host and environmental factors and ultimately the opportunistic pathogenic lifestyle of this versatile host generalist bacterium. IMPORTANCE Enterococcus faecalis causes life-threatening invasive hospital- and community-associated infections that are usually associated with multidrug resistance globally. Although E. faecalis infections cause opportunistic infections typically associated with antibiotic use, immunocompromised immune status, and other factors, they also possess an arsenal of virulence factors crucial for their pathogenicity. Despite this, the relative contribution of these virulence factors and other genetic changes to the pathogenicity of E. faecalis strains remain poorly understood. Here, we investigated whether specific genomic changes in the genome of E. faecalis isolates influence its pathogenicity—infection of hospitalized and nonhospitalized individuals and the propensity to cause extraintestinal infection and intestinal colonization. Our findings indicate that E. faecalis genetics partially influence the infection of hospitalized and nonhospitalized individuals and the propensity to cause extraintestinal infection, possibly due to gut-to-bloodstream translocation, highlighting the potential substantial role of host and environmental factors, including gut microbiota, on the opportunistic pathogenic lifestyle of this bacterium.

Published

2023

38. Current Uses and Future Perspectives of Genomic Technologies in Clinical Microbiology.

Author

Bianconi, Irene, Aschbacher, Richard, and Pagani, Elisabetta

Subjects

MEDICAL microbiology, MICROBIAL sensitivity tests, PUBLIC health, GENOMICS, NUCLEOTIDE sequencing

Abstract

Recent advancements in sequencing technology and data analytics have led to a transformative era in pathogen detection and typing. These developments not only expedite the process, but also render it more cost-effective. Genomic analyses of infectious diseases are swiftly becoming the standard for pathogen analysis and control. Additionally, national surveillance systems can derive substantial benefits from genomic data, as they offer profound insights into pathogen epidemiology and the emergence of antimicrobial-resistant strains. Antimicrobial resistance (AMR) is a pressing global public health issue. While clinical laboratories have traditionally relied on culture-based antimicrobial susceptibility testing, the integration of genomic data into AMR analysis holds immense promise. Genomic-based AMR data can furnish swift, consistent, and highly accurate predictions of resistance phenotypes for specific strains or populations, all while contributing invaluable insights for surveillance. Moreover, genome sequencing assumes a pivotal role in the investigation of hospital outbreaks. It aids in the identification of infection sources, unveils genetic connections among isolates, and informs strategies for infection control. The One Health initiative, with its focus on the intricate interconnectedness of humans, animals, and the environment, seeks to develop comprehensive approaches for disease surveillance, control, and prevention. When integrated with epidemiological data from surveillance systems, genomic data can forecast the expansion of bacterial populations and species transmissions. Consequently, this provides profound insights into the evolution and genetic relationships of AMR in pathogens, hosts, and the environment. [ABSTRACT FROM AUTHOR]

Published

2023

39. A Comprehensive Bioinformatics Resource Guide for Genome-Based Antimicrobial Resistance Studies.

Author

Samantray, Debyani, Tanwar, Ankit Singh, Murali, Thokur Sreepathy, Brand, Angela, Satyamoorthy, Kapaettu, and Paul, Bobby

Subjects

*DRUG resistance in microorganisms, *GENOMICS, *MICROBIAL genomes, *NUCLEOTIDE sequencing, *COMPUTATIONAL biology, *DRUG resistance in bacteria

Abstract

The use of high-throughput sequencing technologies and bioinformatic tools has greatly transformed microbial genome research. With the help of sophisticated computational tools, it has become easier to perform whole genome assembly, identify and compare different species based on their genomes, and predict the presence of genes responsible for proteins, antimicrobial resistance, and toxins. These bioinformatics resources are likely to continuously improve in quality, become more user-friendly to analyze the multiple genomic data, efficient in generating information and translating it into meaningful knowledge, and enhance our understanding of the genetic mechanism of AMR. In this manuscript, we provide an essential guide for selecting the popular resources for microbial research, such as genome assembly and annotation, antibiotic resistance gene profiling, identification of virulence factors, and drug interaction studies. In addition, we discuss the best practices in computer-oriented microbial genome research, emerging trends in microbial genomic data analysis, integration of multi-omics data, the appropriate use of machine-learning algorithms, and open-source bioinformatics resources for genome data analytics. [ABSTRACT FROM AUTHOR]

Published

2023

40. Rumen Lachnospiraceae isolate NK3A20 exhibits metabolic flexibility in response to substrate and coculture with a methanogen.

Author

Kaminsky, Rachel A., Reid, Peter M., Altermann, Eric, Kenters, Nikki, Kelly, William J., Noel, Samantha J., Attwood, Graeme T., and Janssen, Peter H.

Subjects

*GALACTURONIC acid, *PARTIAL pressure, *BUTYRATES, *MICROBIAL physiology, *ELECTRON donors, *MICROBIAL genomics, *DEHYDROGENASES

Abstract

Hydrogen (H2) is the primary electron donor for methane formation in ruminants, but the H2-producing organisms involved are largely uncharacterized. This work integrated studies of microbial physiology and genomics to characterize rumen bacterial isolate NK3A20 of the family Lachnospiraceae. Isolate NK3A20 was the first recognized isolate of the NK3A20 group, which is among the ten most abundant bacterial genera in 16S rRNA gene surveys of rumen microbiota. NK3A20 produced acetate, butyrate, H2, and formate from glucose. The end product ratios varied when grown with different substrates and at different H2 partial pressures. NK3A20 produced butyrate as a major product using glucose or under high H2 partial pressures and switched to mainly acetate in the presence of galacturonic acid (an oxidized sugar) or in coculture with a methanogen. Growth with galacturonic acid was faster at elevated H2 concentrations, while elevated H2 slowed growth with glucose. Genome analyses revealed the presence of multiple hydrogenases including a membrane-bound Ech hydrogenase, an electron bifurcating butyryl-CoA dehydrogenase (Bcd-Etf), and an Rnf complex that may be involved in modulating the observed metabolic pathway changes, providing insight into H2 formation in the rumen. [ABSTRACT FROM AUTHOR]

Published

2023

41. SABRes: in silico detection of drug resistance conferring mutations in subpopulations of SARS-CoV-2 genomes

Author

Winkie Fong, Rebecca J. Rockett, Jessica E. Agius, Shona Chandra, Jessica Johnson-Mckinnon, Eby Sim, Connie Lam, Alicia Arnott, Mailie Gall, Jenny Draper, Susan Maddocks, Sharon Chen, Jen Kok, Dominic Dwyer, Matthew O’Sullivan, and Vitali Sintchenko

Subjects

SARS-CoV-2, COVID-19, Antiviral Resistance, Bioinformatics, Microbial Genomics, Infectious and parasitic diseases, RC109-216

Abstract

Abstract The emergence of resistance to antiviral drugs increasingly used to treat SARS-CoV-2 infections has been recognised as a significant threat to COVID-19 control. In addition, some SARS-CoV-2 variants of concern appear to be intrinsically resistant to several classes of these antiviral agents. Therefore, there is a critical need for rapid recognition of clinically relevant polymorphisms in SARS-CoV-2 genomes associated with significant reduction of drug activity in virus neutralisation experiments. Here we present SABRes, a bioinformatic tool, which leverages on expanding public datasets of SARS-CoV-2 genomes and allows detection of drug resistance mutations in consensus genomes as well as in viral subpopulations. We have applied SABRes to detect resistance-conferring mutations in 25,197 genomes generated over the course of the SARS-CoV-2 pandemic in Australia and identified 299 genomes containing resistance conferring mutations to the five antiviral therapeutics that retain effectiveness against currently circulating strains of SARS-CoV-2 – Sotrovimab, Bebtelovimab, Remdesivir, Nirmatrelvir and Molnupiravir. These genomes accounted for a 1.18% prevalence of resistant isolates discovered by SABRes, including 80 genomes with resistance conferring mutations found in viral subpopulations. Timely recognition of these mutations within subpopulations is critical as these mutations can provide an advantage under selective pressure and presents an important step forward in our ability to monitor SARS-CoV-2 drug resistance.

Published

2023

42. Whole genome sequencing to study antimicrobial resistance and RTX virulence genes in equine Actinobacillus isolates

Author

Nick Vereecke, Arlette Vandekerckhove, Sebastiaan Theuns, Freddy Haesebrouck, and Filip Boyen

Subjects

SNP-tree, virulence, microbial genomics, nanopore sequencing, Actinobacillus genomospecies 1, Veterinary medicine, SF600-1100

Abstract

Abstract Actinobacillus equuli is mostly associated with disease in horses and is most widely known as the causative agent of sleepy foal disease. Even though existing phenotypic tools such as biochemical tests, 16S rRNA gene sequencing, and Matrix Assisted Laser Desorption Ionization Time of Flight Mass Spectrometry (MALDI-TOF MS) can be used to identify members of the Actinobacillus genus, these methods struggle to differentiate between certain species and do not allow strain, virulence, and antimicrobial susceptibility typing. Hence, we performed in-depth analysis of 24 equine Actinobacillus isolates using phenotypic identification and susceptibility testing on the one hand, and long-read nanopore whole genome sequencing on the other hand. This allowed to address strain divergence down to the whole genome single nucleotide polymorphism (SNP) level. While lowest resolution was observed for 16S rRNA gene classification, a new multi-locus sequence typing (MLST) scheme allowed proper classification up to the species level. Nevertheless, a SNP-level analysis was required to distinguish A. equuli subspecies equuli and haemolyticus. Our data provided first WGS data on Actinobacillus genomospecies 1, Actinobacillus genomospecies 2, and A. arthritidis, which allowed the identification of a new Actinobacillus genomospecies 1 field isolate. Also, in-depth characterization of RTX virulence genes provided information on the distribution, completeness, and potential complementary nature of the RTX gene operons within the Actinobacillus genus. Even though overall low prevalence of acquired resistance was observed, two plasmids were identified conferring resistance to penicillin-ampicillin-amoxicillin and chloramphenicol in one A. equuli strain. In conclusion our data delivered new insights in the use of long-read WGS in high resolution identification, virulence gene typing, and antimicrobial resistance (AMR) of equine Actinobacillus species.

Published

2023

43. Using bacterial DNA sequencing data to investigate the epidemiology of plasmid-mediated antibiotic resistance

Author

Orlek, Alex, Walker, Sarah (Ann), Peto, Timothy, Sheppard, Anna, Phan, Hang, Anjum, Muna F., and Doumith, Michel

Subjects

Computational biology, Molecular epidemiology, Epidemiology--Statistical methods, Plasmids, Drug resistance in microorganisms, Microbial genomics

Abstract

Bacterial plasmids are extra-chromosomal genetic elements, which can act as efficient vectors of antibiotic resistance. Epidemiological insight into plasmids may be gained by applying plasmid typing schemes, which exploit loci involved in replication and mobility functions (replicon and MOB typing, respectively). In Chapter 2, I compiled a curated dataset of complete NCBI plasmids to assess the performance of in silico replicon and MOB typing in terms of concordance and 'typeability' (proportion of plasmids typed). I found a degree of non-concordance between the schemes, which was attributed to either ambiguous boundaries between MOBP/MOBQ types, or the mosaic nature of some plasmid genomes. Ultimately, I showed that the schemes fail to accommodate the diversity of plasmid genomes; of ~14000 curated bacterial plasmids, only 42% and 55% could be assigned a replicon and MOB type, respectively. Given the limitations of plasmid typing, I subsequently focused on whole genome sequencing (WGS) analysis approaches capitalising on the wider plasmid genome. High-throughput DNA sequencing has produced 1000s of bacterial WGS datasets. However, such datasets commonly comprise short sequencing reads, which yield fragmented assemblies; this makes comparative analysis of plasmid genomes challenging. In Chapter 3, I developed two methods for comparative plasmid analysis, which cluster short-read sequenced samples according to 1) plasmid replicon types; 2) sample-vs-reference plasmid distance score profiles. However, benchmarking suggested neither method is completely reliable. The rise of long-read sequencing technology has increased the availability of complete plasmid assemblies, facilitating comparative plasmid genomic analyses. Nevertheless, available alignment-based comparative genomic tools have limitations: they often do not provide metrics on structural similarity and lack flexibility in terms of input/output options. Therefore, in Chapter 4, I developed a novel alignment-based tool ('ATCG') for calculating pairwise average nucleotide identity (ANI), coverage breadth, and structural similarity, while addressing limitations of existing alignment-based tools. Benchmarking demonstrated favourable runtimes and supported the validity of calculated ANI scores. In Chapter 5, besides curating an updated plasmid dataset, I curated sample metadata (e.g. isolation source, geography). Using this metadata and plasmid biological features, I conducted multivariate statistical analyses to determine factors associated with plasmid resistance gene carriage, analysed across major resistance gene classes. The analysis yielded interesting findings, for example, demonstrating that patterns of plasmid antibiotic resistance carriage in livestock and humans reflect known antibiotic usage.

Published

2020

44. Redefining gene distributions in K. pneumoniae and E. coli using large public datasets

Author

Horesh, Gal, Thomson, Nicholas Robert, Heinz, Eva, and Parts, Leopold

Subjects

microbial genomics, pan genome, E. coli, K. pneumoniae, toxin-antitoxin

Abstract

The work in this thesis is concerned with characterising genes and their distributions in Escherichia coli and Klebsiella pneumoniae. While both K. pneumoniae and E. coli are found in the guts of healthy individuals, as well as in animals and in the environment, they are particularly relevant organisms to study, as they represent key players in the dissemination of drug resistance and virulence in bacterial populations. Both organisms were given the highest priority by the World Health Organisation as organisms that pose the greatest threat to human health due to high levels of drug resistance. Additionally, they are both the leading cause of life-threatening extra-intestinal disease worldwide. Finally, some E. coli variants are also a major cause of severe diarrheal disease, most commonly in the developing world. The phenomena that is driving these issues is horizontal gene transfer (HGT); the process by which new genetic material is introduced into a genome from an outside source. Drug resistance is most commonly driven by gene acquisition, and it is through the acquisition of virulence genes that K. pneumoniae and E. coli can cause disease. Indeed, HGT has been estimated to occur in high rates in K. pneumoniae and E. coli. Both are highly diverse organisms with very large gene pools and multiple co-circulating lineages. These facts make studying their gene pools on large scales highly relevant, as new genes and lineages are continuously discovered with the sequencing of new genomes. The aim of this thesis was to utilise the availability of large public genomic datasets to study the gene pools of K. pneumoniae and E. coli on a scale and resolution not previously possible. Initially, the distribution of toxin-antitoxin (TA) systems was investigated in a collection of 259 K. pneumoniae isolates. TA systems are operons where one gene encodes for a toxin which inhibits a cellular process, and the other is an antitoxin which inhibits the toxin’s activity. TA systems are relevant to study in the context of HGT as they have been shown to play a role in the maintenance of resistance and virulence genes and to contribute to antibiotic tolerance. The analysis on TA systems in K. pneumoniae revealed new insights regarding the distribution TA systems in the species. These insights were then expanded to examine the distribution of all genes of the E. coli gene pool in a collection of thousands of genomes. This analysis revealed that genes from different categories undergo different dynamics of gene gain and loss, as well as exposed E. coli lineages which may be important in their contribution to gene flow in the population. Due to the novelty and scope of the analyses presented, new computational tools and approaches were developed and are presented.

Published

2020

45. Exploring the genomic and phenotypic diversity of the Vibrio cholerae species

Author

Dorman, Matthew, Thomson, Nicholas R., Salmond, George P. C., and Dougan, Gordon

Subjects

microbial genomics, cholera, Vibrio cholerae, microbiology

Abstract

Vibrio cholerae is the aetiological agent of cholera, an acute diarrhoeal disease which is estimated to result in up to 143,000 deaths per annum. Cholera is a considerable public health concern because it can spread rapidly in and explosive pandemics. Current pandemic cholera is caused by a highly-clonal phylogenetic lineage of V. cholerae serogroup O1, which spreads across the globe in periodic ‘waves’. However, V. cholerae is a species rich in diversity, and although much is known about the population structure of the pandemic lineages, the biology and pathogenicity of non-pandemic and non-O1 V. cholerae has been comparatively neglected. In this dissertation, I have studied the biology, genome dynamics, and diversity of non-pandemic V. cholerae, in comparison to the current pandemic lineage. I first present an analysis of the 1992-1998 cholera epidemic in Argentina, a country which had been free of pandemic cholera for nearly 100 years before 1992. I use the genome sequences of 490 V. cholerae from Argentina to study the micro-evolution of the pandemic lineage upon its introduction into a naïve population. I use these data to describe the progression of the Argentinian cholera epidemic using genomic epidemiology approaches, and to contrast this pandemic lineage to the non-epidemic V. cholerae that were present in Argentina at the same time as the pandemic lineage. I then present a study of important recent and historical V. cholerae isolates, sequenced to completion using long-read technologies. I describe aspects of these genomes that could only be resolved using closed assemblies, and present functional validations of several in silico observations. Having performed this forensic, manual study of a small number of genomes, I then extrapolate those insights into a wider context, by mapping the distribution of key genetic determinants of important V. cholerae phenotypes across a phylogenetic tree of 651 highly-diverse V. cholerae. Finally, I integrate the knowledge gained in this research to make a rational selection of V. cholerae isolates for transcriptomic analysis, based on their phylogenetic position and gene content, to investigate whether differential gene expression might explain the stark differences between pandemic and non-pandemic V. cholerae. The data presented here add substantially to our understanding of the diversity of V. cholerae. They emphasise the stark differences in genome flux and evolution between pandemic and non-pandemic lineages. They also show that many of the genetic and phenotypic markers of epidemic and pandemic lineages are misleading, and do not describe that which they were originally chosen to describe.

Published

2020

46. aKmerBroom: Ancient oral DNA decontamination using Bloom filters on k-mer sets

Author

Camila Duitama González, Samarth Rangavittal, Riccardo Vicedomini, Rayan Chikhi, and Hugues Richard

Subjects

Microbial genomics, Biocomputational method, Sequence analysis, Paleogenetics, Science

Abstract

Summary: Dental calculus samples are modeled as a mixture of DNA coming from dental plaque and contaminants. Current computational decontamination methods such as Recentrifuge and DeconSeq require either a reference database or sequenced negative controls, and therefore have limited use cases. We present a reference-free decontamination tool tailored for the removal of contaminant DNA of ancient oral sample called aKmerBroom. Our tool builds a Bloom filter of known ancient and modern oral k-mers, then scans an input set of ancient metagenomic reads using multiple passes to iteratively retain reads likely to be of oral origin. On synthetic data, aKmerBroom achieves over 89.53% sensitivity and 94.00% specificity. On real datasets, aKmerBroom shows higher read retainment (+60% on average) than other methods. We anticipate aKmerBroom will be a valuable tool for the processing of ancient oral samples as it will prevent contaminated datasets from being completely discarded in downstream analyses.

Published

2023

47. Analysis of the milk kefir pan-metagenome reveals four community types, core species, and associated metabolic pathways

Author

Liam H. Walsh, Mairéad Coakley, Aaron M. Walsh, Fiona Crispie, Paul W. O’Toole, and Paul D. Cotter

Subjects

Geographic areas, Microbial genomics, Microbial metabolism, Genomics, Science

Abstract

Summary: A comprehensive metagenomics-based investigation of the microorganisms present within milk kefir communities from across the globe was carried out with a view to defining the milk kefir pan-metagenome, including details relating to core and non-core components. Milk kefir samples, generated by inoculating full fat, pasteurized cow’s milk with 64 kefir grains sourced from 25 different countries, were analyzed. We identified core features, including a consistent pattern of domination by representatives from the species Lactobacillus helveticus or the sub-species Lactobacillus kefiranofaciens subsp. kefiranofaciens, Lactococcus lactis subsp. lactis or Lla. cremoris subsp. cremoris in each kefir. Notably, even in kefirs where the lactococci did not dominate, they and 51 associated metabolic pathways were identified across all metagenomes. These insights can contribute to future efforts to create tailored kefir-based microbial communities for different applications and assist regulators and producers to ensure that kefir products have a microbial composition that reflects the artisanal beverage.

Published

2023

48. Aggravated hepatic fibrosis induced by phenylalanine and tyrosine was ameliorated by chitooligosaccharides supplementation

Author

Peng Liu, Heng Li, Hongyu Xu, Jinsong Gong, Min Jiang, Zhenghong Xu, and Jinsong Shi

Subjects

Biochemical mechanism, Fibrosis, Metabolomics, Microbial genomics, Model organism, Science

Abstract

Summary: Hepatic fibrosis is a classic pathological manifestation of metabolic chronic hepatopathy. The pathological process might either gradually deteriorate into cirrhosis and ultimately liver cancer with inappropriate nutrition supply, or be slowed down by several multifunctional nutrients, alternatively. Herein, we found diet with excessive phenylalanine (Phe) and tyrosine (Tyr) exacerbated hepatic fibrosis symptoms of liver dysfunction and gut microflora dysbiosis in mice. Chitooligosaccharides (COS) could ameliorate hepatic fibrosis with the regulation of amino acid metabolism by downregulating the mTORC1 pathway, especially that of Phe and Tyr, and also with the alleviation of the dysbiosis of gut microbiota, simultaneously. Conclusively, this work presents new insight into the role of Phe and Tyr in the pathologic process of hepatic fibrosis, while revealing the effectiveness and molecular mechanism of COS in improving hepatic fibrosis from the perspective of metabolites.

Published

2023

49. Metagenomic analysis reveals the dissemination mechanisms and risks of resistance genes in plateau lakes

Author

Chengzhi Mao, Qi Li, Majid Komijani, Jie Huang, and Tao Li

Subjects

Microbiology, Microbial genomics, Aquatic biology, Science

Abstract

Summary: Antibiotic resistance genes (ARGs) are emerging as environmental pollutants that can persist and disseminate in aquatic environments. Lakes, as important sources of freshwater, also serve as potential natural reservoirs of ARGs. In this study, we analyzed the distribution and potential risks of resistance genes in five typical freshwater lakes on the Yunnan-Guizhou Plateau. Our findings revealed that multidrug and MLS ARGs dominated in the studied lakes. Notably, while Lugu Lake exhibited higher abundance of ARGs, mobile genetic elements (MGEs), and metal resistance genes (MRGs), a greater resistome risk was observed in the eutrophic Xingyun Lake. The dissemination processes of ARGs and MRGs are primarily driven by microbial communities and the horizontal gene transfer via MGEs. Limnohabitans, Flavobacterium, and Acinetobacter were identified as key players in the dissemination of ARGs. Our study highlights the persistence of ARGs and provides valuable baseline data and risk assessment of ARGs in plateau freshwater lakes.

Published

2023

50. Predicting the effect of mutations to investigate recent events of selection across 60,472 Escherichia coli strains.

Author

Vigué, Lucile and Tenaillon, Olivier

Subjects

*ESCHERICHIA coli, *GENE expression, *MICROBIAL genomics, *GENETIC mutation, *GENOMES, *NATURAL products

Abstract

Microbial genomics studies focusing on the dynamics of selection have often used a small number of distant genomes. As a result, they could only analyze mutations that had become fixed during the divergence between species. However, thousands of genomes of some species are now available in public databases, thanks to high-throughput sequencing. These data provide a more complete picture of the polymorphisms segregating within a species, offering a unique insight into the processes that shape the recent evolution of a species. In this study, we present GLASS (Gene-Level Amino-acid Score Shift), a selection test that is based on the predicted effects of amino acid changes. By comparing the distribution of effects of mutations observed in a gene to the expectation in the absence of selection, GLASS can quantify the intensity of selection. We applied GLASS to a dataset of 60,472 Escherichia coli strains and used this to reexamine the longstanding debate about the role of essentiality versus expression level in the rate of protein evolution. We found that selection has contrasting shortterm and long-term dynamics, with essential genes being subject to strong purifying selection in the short term, while expression level determines the rate of gene evolution in the long term. GLASS also found an overrepresentation of inactivating mutations in specific transcription factors, such as efflux pump repressors, which is consistent with selection for antibiotic resistance. These gene-inactivating polymorphisms do not reach fixation, suggesting another contrast between short-term fitness gains and long-term counterselection. [ABSTRACT FROM AUTHOR]

Published

2023