Your search keyword '"Lauro FM"' showing total 137 results

51. Draft Genome Sequence of Enterobacter sp. Strain EA-1, an Electrochemically Active Microorganism Isolated from Tropical Sediment.

Author

Doyle LE, Williams RBH, Rice SA, Marsili E, and Lauro FM

Abstract

Enterobacter sp. strain EA-1 is an electrochemically active bacterium isolated from tropical sediment in Singapore. Here, the annotated draft genome assembly of the bacterium is reported. Whole-genome comparison indicates that Enterobacter sp. EA-1, along with a previously sequenced Enterobacter isolate from East Asia, forms a distinct clade within the Enterobacter genus., (Copyright © 2018 Doyle et al.)

Published

2018

52. MetaLIMS, a simple open-source laboratory information management system for small metagenomic labs.

Author

Heinle CE, Gaultier NPE, Miller D, Purbojati RW, and Lauro FM

Subjects

Internet, Laboratories, Management Information Systems, Software, User-Computer Interface, Database Management Systems, Metagenomics

Abstract

Background: As the cost of sequencing continues to fall, smaller groups increasingly initiate and manage larger sequencing projects and take on the complexity of data storage for high volumes of samples. This has created a need for low-cost laboratory information management systems (LIMS) that contain flexible fields to accommodate the unique nature of individual labs. Many labs do not have a dedicated information technology position, so LIMS must also be easy to setup and maintain with minimal technical proficiency. MetaLIMS is a free and open-source web-based application available via GitHub. The focus of MetaLIMS is to store sample metadata prior to sequencing and analysis pipelines. Initially designed for environmental metagenomics labs, in addition to storing generic sample collection information and DNA/RNA processing information, the user can also add fields specific to the user's lab. MetaLIMS can also produce a basic sequencing submission form compatible with the proprietary Clarity LIMS system used by some sequencing facilities. To help ease the technical burden associated with web deployment, MetaLIMS options the use of commercial web hosting combined with MetaLIMS bash scripts for ease of setup. MetaLIMS overcomes key challenges common in LIMS by giving labs access to a low-cost and open-source tool that also has the flexibility to meet individual lab needs and an option for easy deployment. By making the web application open source and hosting it on GitHub, we hope to encourage the community to build upon MetaLIMS, making it more robust and tailored to the needs of more researchers., (© The Authors 2017. Published by Oxford University Press.)

Published

2017

53. Erratum: Global transcriptomic responses of Escherichia coli K-12 to volatile organic compounds.

Author

Yung PY, Lo Grasso L, Mohidin AF, Acerbi E, Hinks J, Seviour T, Marsili E, and Lauro FM

Published

2017

54. Ecological succession of the microbial communities of an air-conditioning cooling coil in the tropics.

Author

Acerbi E, Chénard C, Miller D, Gaultier NE, Heinle CE, Chang VW, Uchida A, Drautz-Moses DI, Schuster SC, and Lauro FM

Subjects

Ecosystem, Environmental Monitoring methods, Fungi growth & development, RNA, Ribosomal, 16S analysis, Sphingomonas growth & development, Air Conditioning instrumentation, Air Microbiology, Air Pollution, Indoor analysis, Tropical Climate

Abstract

Air-conditioning systems harbor microorganisms, potentially spreading them to indoor environments. While air and surfaces in air-conditioning systems are periodically sampled as potential sources of indoor microbes, little is known about the dynamics of cooling coil-associated communities and their effect on the downstream airflow. Here, we conducted a 4-week time series sampling to characterize the succession of an air-conditioning duct and cooling coil after cleaning. Using an universal primer pair targeting hypervariable regions of the 16S/18S ribosomal RNA, we observed a community succession for the condensed water, with the most abundant airborne taxon Agaricomycetes fungi dominating the initial phase and Sphingomonas bacteria becoming the most prevalent taxa toward the end of the experiment. Duplicate air samples collected upstream and downstream of the coil suggest that the system does not act as ecological filter or source/sink for specific microbial taxa during the duration of the experiment., (© 2016 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2017

55. The Anti-Oxidant Defense System of the Marine Polar Ciliate Euplotes nobilii: Characterization of the MsrB Gene Family.

Author

Ricci F, Lauro FM, Grzymski JJ, Read R, Bakiu R, Santovito G, Luporini P, and Vallesi A

Abstract

Organisms living in polar waters must cope with an extremely stressful environment dominated by freezing temperatures, high oxygen concentrations and UV radiation. To shed light on the genetic mechanisms on which the polar marine ciliate, Euplotes nobilii , relies to effectively cope with the oxidative stress, attention was focused on methionine sulfoxide reductases which repair proteins with oxidized methionines. A family of four structurally distinct MsrB genes, encoding enzymes specific for the reduction of the methionine-sulfoxide R-forms, were identified from a draft of the E. nobilii transcriptionally active (macronuclear) genome. The En-MsrB genes are constitutively expressed to synthesize proteins markedly different in amino acid sequence, number of CXXC motifs for zinc-ion binding, and presence/absence of a cysteine residue specific for the mechanism of enzyme regeneration. The En-MsrB proteins take different localizations in the nucleus, mitochondria, cytosol and endoplasmic reticulum, ensuring a pervasive protection of all the major subcellular compartments from the oxidative damage. These observations have suggested to regard the En-MsrB gene activity as playing a central role in the genetic mechanism that enables E. nobilii and ciliates in general to live in the polar environment.

Published

2017

56. Sub-toxic concentrations of volatile organic compounds inhibit extracellular respiration of Escherichia coli cells grown in anodic bioelectrochemical systems.

Author

Santoro C, Mohidin AF, Grasso LL, Seviour T, Palanisamy K, Hinks J, Lauro FM, and Marsili E

Subjects

Cell Proliferation drug effects, Dose-Response Relationship, Drug, Electric Conductivity, Electrochemistry, Electrodes, Escherichia coli cytology, Escherichia coli drug effects, Escherichia coli metabolism, Extracellular Space drug effects, Extracellular Space metabolism, Volatile Organic Compounds toxicity, Water Pollutants, Chemical toxicity

Abstract

Low-cost and rapid detection of volatile organic compounds (VOCs) is important for the control of water quality of used water and protection of downstream used water treatment processes. In this work, the effect of sub-toxic concentration of VOCs on the current output of Escherichia coli in bioelectrochemical systems (BES) is shown, in light of environmental sensing applications for sewage and used water networks. E. coli cells were grown on carbon felt electrodes in artificial used water, to increase sensitivity and decrease response time for detection. Extracellular electron transfer was promoted by the addition of a biocompatible redox mediator, 2-hydroxy-1,4-naphthoquinone (HNQ). Among the eight VOCs investigated, toluene is the most toxic to E. coli, with a detection limit of 50±2mgL(-1) and current output of 32±1nAmg(-1)L(-1). This work offers a straightforward route to enhance the detection of organic contaminants in used water for environmental applications., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

57. Global transcriptomic responses of Escherichia coli K-12 to volatile organic compounds.

Author

Yung PY, Grasso LL, Mohidin AF, Acerbi E, Hinks J, Seviour T, Marsili E, and Lauro FM

Subjects

Cluster Analysis, Computational Biology, Gene Expression Profiling, Gene Ontology, Molecular Sequence Annotation, Stress, Physiological genetics, Escherichia coli K12 drug effects, Escherichia coli K12 genetics, Gene Expression Regulation, Bacterial, Transcriptome, Volatile Organic Compounds pharmacology

Abstract

Volatile organic compounds (VOCs) are commonly used as solvents in various industrial settings. Many of them present a challenge to receiving environments, due to their toxicity and low bioavailability for degradation. Microorganisms are capable of sensing and responding to their surroundings and this makes them ideal detectors for toxic compounds. This study investigates the global transcriptomic responses of Escherichia coli K-12 to selected VOCs at sub-toxic levels. Cells grown in the presence of VOCs were harvested during exponential growth, followed by whole transcriptome shotgun sequencing (RNAseq). The analysis of the data revealed both shared and unique genetic responses compared to cells without exposure to VOCs. Results suggest that various functional gene categories, for example, those relating to Fe/S cluster biogenesis, oxidative stress responses and transport proteins, are responsive to selected VOCs in E. coli. The differential expression (DE) of genes was validated using GFP-promoter fusion assays. A variety of genes were differentially expressed even at non-inhibitory concentrations and when the cells are at their balanced-growth. Some of these genes belong to generic stress response and others could be specific to VOCs. Such candidate genes and their regulatory elements could be used as the basis for designing biosensors for selected VOCs.

Published

2016

58. Spatially extensive microbial biogeography of the Indian Ocean provides insights into the unique community structure of a pristine coral atoll.

Author

Jeffries TC, Ostrowski M, Williams RB, Xie C, Jensen RM, Grzymski JJ, Senstius SJ, Givskov M, Hoeke R, Philip GK, Neches RY, Drautz-Moses DI, Chénard C, Paulsen IT, and Lauro FM

Subjects

Animals, Indian Ocean, Metagenome, Metagenomics methods, Biodiversity, Ecosystem, Water Microbiology

Abstract

Microorganisms act both as drivers and indicators of perturbations in the marine environment. In an effort to establish baselines to predict the response of marine habitats to environmental change, here we report a broad survey of microbial diversity across the Indian Ocean, including the first microbial samples collected in the pristine lagoon of Salomon Islands, Chagos Archipelago. This was the first large-scale ecogenomic survey aboard a private yacht employing a 'citizen oceanography' approach and tools and protocols easily adapted to ocean going sailboats. Our data highlighted biogeographic patterns in microbial community composition across the Indian Ocean. Samples from within the Salomon Islands lagoon contained a community which was different even from adjacent samples despite constant water exchange, driven by the dominance of the photosynthetic cyanobacterium Synechococcus. In the lagoon, Synechococcus was also responsible for driving shifts in the metatranscriptional profiles. Enrichment of transcripts related to photosynthesis and nutrient cycling indicated bottom-up controls of community structure. However a five-fold increase in viral transcripts within the lagoon during the day, suggested a concomitant top-down control by bacteriophages. Indeed, genome recruitment against Synechococcus reference genomes suggested a role of viruses in providing the ecological filter for determining the β-diversity patterns in this system.

Published

2015

59. The ocean sampling day consortium.

Author

Kopf A, Bicak M, Kottmann R, Schnetzer J, Kostadinov I, Lehmann K, Fernandez-Guerra A, Jeanthon C, Rahav E, Ullrich M, Wichels A, Gerdts G, Polymenakou P, Kotoulas G, Siam R, Abdallah RZ, Sonnenschein EC, Cariou T, O'Gara F, Jackson S, Orlic S, Steinke M, Busch J, Duarte B, Caçador I, Canning-Clode J, Bobrova O, Marteinsson V, Reynisson E, Loureiro CM, Luna GM, Quero GM, Löscher CR, Kremp A, DeLorenzo ME, Øvreås L, Tolman J, LaRoche J, Penna A, Frischer M, Davis T, Katherine B, Meyer CP, Ramos S, Magalhães C, Jude-Lemeilleur F, Aguirre-Macedo ML, Wang S, Poulton N, Jones S, Collin R, Fuhrman JA, Conan P, Alonso C, Stambler N, Goodwin K, Yakimov MM, Baltar F, Bodrossy L, Van De Kamp J, Frampton DM, Ostrowski M, Van Ruth P, Malthouse P, Claus S, Deneudt K, Mortelmans J, Pitois S, Wallom D, Salter I, Costa R, Schroeder DC, Kandil MM, Amaral V, Biancalana F, Santana R, Pedrotti ML, Yoshida T, Ogata H, Ingleton T, Munnik K, Rodriguez-Ezpeleta N, Berteaux-Lecellier V, Wecker P, Cancio I, Vaulot D, Bienhold C, Ghazal H, Chaouni B, Essayeh S, Ettamimi S, Zaid el H, Boukhatem N, Bouali A, Chahboune R, Barrijal S, Timinouni M, El Otmani F, Bennani M, Mea M, Todorova N, Karamfilov V, Ten Hoopen P, Cochrane G, L'Haridon S, Bizsel KC, Vezzi A, Lauro FM, Martin P, Jensen RM, Hinks J, Gebbels S, Rosselli R, De Pascale F, Schiavon R, Dos Santos A, Villar E, Pesant S, Cataletto B, Malfatti F, Edirisinghe R, Silveira JA, Barbier M, Turk V, Tinta T, Fuller WJ, Salihoglu I, Serakinci N, Ergoren MC, Bresnan E, Iriberri J, Nyhus PA, Bente E, Karlsen HE, Golyshin PN, Gasol JM, Moncheva S, Dzhembekova N, Johnson Z, Sinigalliano CD, Gidley ML, Zingone A, Danovaro R, Tsiamis G, Clark MS, Costa AC, El Bour M, Martins AM, Collins RE, Ducluzeau AL, Martinez J, Costello MJ, Amaral-Zettler LA, Gilbert JA, Davies N, Field D, and Glöckner FO

Subjects

Biodiversity, Database Management Systems, Metagenomics, Oceans and Seas, Marine Biology

Abstract

Ocean Sampling Day was initiated by the EU-funded Micro B3 (Marine Microbial Biodiversity, Bioinformatics, Biotechnology) project to obtain a snapshot of the marine microbial biodiversity and function of the world's oceans. It is a simultaneous global mega-sequencing campaign aiming to generate the largest standardized microbial data set in a single day. This will be achievable only through the coordinated efforts of an Ocean Sampling Day Consortium, supportive partnerships and networks between sites. This commentary outlines the establishment, function and aims of the Consortium and describes our vision for a sustainable study of marine microbial communities and their embedded functional traits.

Published

2015

60. Complete Genome Sequence and Transcriptomic Analysis of the Novel Pathogen Elizabethkingia anophelis in Response to Oxidative Stress.

Author

Li Y, Liu Y, Chew SC, Tay M, Salido MM, Teo J, Lauro FM, Givskov M, and Yang L

Subjects

Biofilms growth & development, Drug Resistance, Bacterial genetics, Flavobacteriaceae drug effects, Flavobacteriaceae pathogenicity, Flavobacteriaceae physiology, Gene Expression Profiling, Genomics, Hemoglobins pharmacology, Molecular Sequence Data, Siderophores biosynthesis, Virulence genetics, Flavobacteriaceae genetics, Genome, Bacterial, Oxidative Stress genetics

Abstract

Elizabethkingia anophelis is an emerging pathogen that can cause life-threatening infections in neonates, severely immunocompromised and postoperative patients. The lack of genomic information on E. anophelis hinders our understanding of its mechanisms of pathogenesis. Here, we report the first complete genome sequence of E. anophelis NUHP1 and assess its response to oxidative stress. Elizabethkingia anophelis NUHP1 has a circular genome of 4,369,828 base pairs and 4,141 predicted coding sequences. Sequence analysis indicates that E. anophelis has well-developed systems for scavenging iron and stress response. Many putative virulence factors and antibiotic resistance genes were identified, underscoring potential host-pathogen interactions and antibiotic resistance. RNA-sequencing-based transcriptome profiling indicates that expressions of genes involved in synthesis of an yersiniabactin-like iron siderophore and heme utilization are highly induced as a protective mechanism toward oxidative stress caused by hydrogen peroxide treatment. Chrome azurol sulfonate assay verified that siderophore production of E. anophelis is increased in the presence of oxidative stress. We further showed that hemoglobin facilitates the growth, hydrogen peroxide tolerance, cell attachment, and biofilm formation of E. anophelis NUHP1. Our study suggests that siderophore production and heme uptake pathways might play essential roles in stress response and virulence of the emerging pathogen E. anophelis., (© The Author(s) 2015. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2015

61. Marine Microbial Secondary Metabolites: Pathways, Evolution and Physiological Roles.

Author

Giordano D, Coppola D, Russo R, Denaro R, Giuliano L, Lauro FM, di Prisco G, and Verde C

Subjects

Anti-Infective Agents metabolism, Antineoplastic Agents metabolism, Aquatic Organisms genetics, Fatty Acid Synthases, Metabolic Networks and Pathways genetics, Multigene Family, Peptide Synthases, Polyketide Synthases, Aquatic Organisms metabolism, Biological Products metabolism, Secondary Metabolism

Abstract

Microbes produce a huge array of secondary metabolites endowed with important ecological functions. These molecules, which can be catalogued as natural products, have long been exploited in medical fields as antibiotics, anticancer and anti-infective agents. Recent years have seen considerable advances in elucidating natural-product biosynthesis and many drugs used today are natural products or natural-product derivatives. The major contribution to recent knowledge came from application of genomics to secondary metabolism and was facilitated by all relevant genes being organised in a contiguous DNA segment known as gene cluster. Clustering of genes regulating biosynthesis in bacteria is virtually universal. Modular gene clusters can be mixed and matched during evolution to generate structural diversity in natural products. Biosynthesis of many natural products requires the participation of complex molecular machines known as polyketide synthases and non-ribosomal peptide synthetases. Discovery of new evolutionary links between the polyketide synthase and fatty acid synthase pathways may help to understand the selective advantages that led to evolution of secondary-metabolite biosynthesis within bacteria. Secondary metabolites confer selective advantages, either as antibiotics or by providing a chemical language that allows communication among species, with other organisms and their environment. Herewith, we discuss these aspects focusing on the most clinically relevant bioactive molecules, the thiotemplated modular systems that include polyketide synthases, non-ribosomal peptide synthetases and fatty acid synthases. We begin by describing the evolutionary and physiological role of marine natural products, their structural/functional features, mechanisms of action and biosynthesis, then turn to genomic and metagenomic approaches, highlighting how the growing body of information on microbial natural products can be used to address fundamental problems in environmental evolution and biotechnology., (© 2015 Elsevier Ltd. All rights reserved.)

Published

2015

62. The common oceanographer: crowdsourcing the collection of oceanographic data.

Author

Lauro FM, Senstius SJ, Cullen J, Neches R, Jensen RM, Brown MV, Darling AE, Givskov M, McDougald D, Hoeke R, Ostrowski M, Philip GK, Paulsen IT, and Grzymski JJ

Subjects

Geographic Information Systems, Humans, Information Dissemination, Oceans and Seas, Ships, Workforce, Crowdsourcing statistics & numerical data, Models, Statistical, Oceanography, Social Participation

Abstract

Competing Interests: The authors have declared that no competing interests exist.

Published

2014

63. Population dynamics of an Acinetobacter baumannii clonal complex during colonization of patients.

Author

Wen H, Wang K, Liu Y, Tay M, Lauro FM, Huang H, Wu H, Liang H, Ding Y, Givskov M, Chen Y, and Yang L

Subjects

Acinetobacter baumannii genetics, DNA, Bacterial chemistry, DNA, Bacterial genetics, Genome, Bacterial, Genotype, Humans, Molecular Sequence Data, Population Dynamics, Sequence Analysis, DNA, Time Factors, Acinetobacter Infections microbiology, Acinetobacter baumannii classification, Acinetobacter baumannii growth & development

Abstract

Acinetobacter baumannii has emerged as one of the leading pathogens causing hospital-acquired infection. The success of A. baumannii as a pathogen has to a large extent been attributed to its capacity to remodel its genome. Several major epidemic clonal complexes of A. baumannii spread across different health care facilities around the world, each of which contains a subset of diversified strains. However, little is known about the population dynamics during colonization of A. baumannii within hosts. Here, whole-genome sequencing was used to analyze population dynamics of A. baumannii strains isolated from a group of patients at different time points as well as from different sites of a particular patient. Seven out of nine of the sampled A. baumannii strains belonged to the international clone II (CC92 clonal complex). While the A. baumannii strains were found to be stable in three patients, there was a change of A. baumannii strains in one patient. Comparative genomic analysis revealed that the accessory genome of these strains contained a large set of virulence-encoding genes and these virulence factors might play a role in determining population dynamics. Microscale genome modification has been revealed by analysis of single nucleotide polymorphisms (SNPs) between A. baumannii strains isolated from the same patient. Parallel evolutionary traits have been observed during genome diversification when A. baumannii colonize in different patients. Our study suggested that both antibiotic usage and host environment might impose selective forces that drive the rapid adaptive evolution in colonizing A. baumannii., (Copyright © 2014, American Society for Microbiology. All Rights Reserved.)

Published

2014

64. A trait based perspective on the biogeography of common and abundant marine bacterioplankton clades.

Author

Brown MV, Ostrowski M, Grzymski JJ, and Lauro FM

Subjects

Cyanobacteria classification, Oceans and Seas, Phylogeography, Plankton classification, Species Specificity, Water Movements, Adaptation, Biological genetics, Cyanobacteria genetics, Cyanobacteria physiology, Genetic Variation, Plankton genetics, Plankton physiology

Abstract

Marine microbial communities provide much of the energy upon which all higher trophic levels depend, particularly in open-ocean and oligotrophic systems, and play a pivotal role in biogeochemical cycling. How and why species are distributed in the global oceans, and whether net ecosystem function can be accurately predicted from community composition are fundamental questions for marine scientists. Many of the most abundant clades of marine bacteria, including the Prochlorococcus, Synechococcus, SAR11, SAR86 and Roseobacter, have a very broad, if not a cosmopolitan distribution. However this is not reflected in an underlying genetic identity. Rather, widespread distribution in these organisms is achieved by the existence of closely related but discrete ecotypes that display niche adaptations. Closely related ecotypes display specific nutritional or energy generating mechanisms and are adapted to different physical parameters including temperature, salinity, and hydrostatic pressure. Furthermore, biotic phenomena such as selective grazing and viral loss contribute to the success or failure of ecotypes allowing some to compete effectively in particular marine provinces but not in others. An additional layer of complexity is added by ocean currents and hydrodynamic specificity of water body masses that bound microbial dispersal and immigration. These vary in space and time with respect to intensity and direction, making the definition of large biogeographic provinces problematic. A deterministic theory aimed at understanding how all these factors shape microbial life in the oceans can only proceed through analysis of microbial traits, rather than pure phylogenetic assessments. Trait based approaches seek mechanistic explanations for the observed temporal and spatial patterns. This review will present successful recent advances in phylogenetic and trait based biogeographic analyses in some of the most abundant marine taxa., (Copyright © 2014. Published by Elsevier B.V.)

Published

2014

65. Ecotype diversity and conversion in Photobacterium profundum strains.

Author

Lauro FM, Eloe-Fadrosh EA, Richter TK, Vitulo N, Ferriera S, Johnson JH, and Bartlett DH

Subjects

Ecotype, Gene Expression Regulation, Bacterial, Genetic Variation, Genome, Bacterial, Photobacterium genetics

Abstract

Photobacterium profundum is a cosmopolitan marine bacterium capable of growth at low temperature and high hydrostatic pressure. Multiple strains of P. profundum have been isolated from different depths of the ocean and display remarkable differences in their physiological responses to pressure. The genome sequence of the deep-sea piezopsychrophilic strain Photobacterium profundum SS9 has provided some clues regarding the genetic features required for growth in the deep sea. The sequenced genome of Photobacterium profundum strain 3TCK, a non-piezophilic strain isolated from a shallow-water environment, is now available and its analysis expands the identification of unique genomic features that correlate to environmental differences and define the Hutchinsonian niche of each strain. These differences range from variations in gene content to specific gene sequences under positive selection. Genome plasticity between Photobacterium bathytypes was investigated when strain 3TCK-specific genes involved in photorepair were introduced to SS9, demonstrating that horizontal gene transfer can provide a mechanism for rapid colonisation of new environments.

Published

2014

66. Integrating metagenomic and amplicon databases to resolve the phylogenetic and ecological diversity of the Chlamydiae.

Author

Lagkouvardos I, Weinmaier T, Lauro FM, Cavicchioli R, Rattei T, and Horn M

Subjects

Bacterial Proteins genetics, Databases, Genetic, Ecology, Environmental Microbiology, Metagenomics, RNA, Ribosomal, 16S genetics, Biodiversity, Chlamydiaceae classification, Chlamydiaceae genetics, Phylogeny

Abstract

In the era of metagenomics and amplicon sequencing, comprehensive analyses of available sequence data remain a challenge. Here we describe an approach exploiting metagenomic and amplicon data sets from public databases to elucidate phylogenetic diversity of defined microbial taxa. We investigated the phylum Chlamydiae whose known members are obligate intracellular bacteria that represent important pathogens of humans and animals, as well as symbionts of protists. Despite their medical relevance, our knowledge about chlamydial diversity is still scarce. Most of the nine known families are represented by only a few isolates, while previous clone library-based surveys suggested the existence of yet uncharacterized members of this phylum. Here we identified more than 22,000 high quality, non-redundant chlamydial 16S rRNA gene sequences in diverse databases, as well as 1900 putative chlamydial protein-encoding genes. Even when applying the most conservative approach, clustering of chlamydial 16S rRNA gene sequences into operational taxonomic units revealed an unexpectedly high species, genus and family-level diversity within the Chlamydiae, including 181 putative families. These in silico findings were verified experimentally in one Antarctic sample, which contained a high diversity of novel Chlamydiae. In our analysis, the Rhabdochlamydiaceae, whose known members infect arthropods, represents the most diverse and species-rich chlamydial family, followed by the protist-associated Parachlamydiaceae, and a putative new family (PCF8) with unknown host specificity. Available information on the origin of metagenomic samples indicated that marine environments contain the majority of the newly discovered chlamydial lineages, highlighting this environment as an important chlamydial reservoir.

Published

2014

67. High level of intergenera gene exchange shapes the evolution of haloarchaea in an isolated Antarctic lake.

Author

DeMaere MZ, Williams TJ, Allen MA, Brown MV, Gibson JA, Rich J, Lauro FM, Dyall-Smith M, Davenport KW, Woyke T, Kyrpides NC, Tringe SG, and Cavicchioli R

Subjects

Antarctic Regions, Metagenome, RNA, Archaeal genetics, RNA, Ribosomal, 16S genetics, Evolution, Molecular, Gene Transfer, Horizontal, Genome, Archaeal physiology, Halobacteriaceae genetics, Lakes microbiology, Water Microbiology

Abstract

Deep Lake in Antarctica is a globally isolated, hypersaline system that remains liquid at temperatures down to -20 °C. By analyzing metagenome data and genomes of four isolates we assessed genome variation and patterns of gene exchange to learn how the lake community evolved. The lake is completely and uniformly dominated by haloarchaea, comprising a hierarchically structured, low-complexity community that differs greatly to temperate and tropical hypersaline environments. The four Deep Lake isolates represent distinct genera (∼85% 16S rRNA gene similarity and ∼73% genome average nucleotide identity) with genomic characteristics indicative of niche adaptation, and collectively account for ∼72% of the cellular community. Network analysis revealed a remarkable level of intergenera gene exchange, including the sharing of long contiguous regions (up to 35 kb) of high identity (∼100%). Although the genomes of closely related Halobacterium, Haloquadratum, and Haloarcula (>90% average nucleotide identity) shared regions of high identity between species or strains, the four Deep Lake isolates were the only distantly related haloarchaea to share long high-identity regions. Moreover, the Deep Lake high-identity regions did not match to any other hypersaline environment metagenome data. The most abundant species, tADL, appears to play a central role in the exchange of insertion sequences, but not the exchange of high-identity regions. The genomic characteristics of the four haloarchaea are consistent with a lake ecosystem that sustains a high level of intergenera gene exchange while selecting for ecotypes that maintain sympatric speciation. The peculiarities of this polar system restrict which species can grow and provide a tempo and mode for accentuating gene exchange.

Published

2013

68. Metagenomic insights into strategies of carbon conservation and unusual sulfur biogeochemistry in a hypersaline Antarctic lake.

Author

Yau S, Lauro FM, Williams TJ, Demaere MZ, Brown MV, Rich J, Gibson JA, and Cavicchioli R

Subjects

Antarctic Regions, Bacteria classification, Bacteria genetics, Carbon analysis, Carbon-Sulfur Lyases genetics, Carbon-Sulfur Lyases metabolism, Eukaryota genetics, Eukaryota physiology, Genes, rRNA genetics, Nitrogen metabolism, Sulfides metabolism, Sulfur analysis, Bacteria metabolism, Carbon metabolism, Eukaryota metabolism, Lakes chemistry, Lakes microbiology, Metagenomics, Sulfur metabolism

Abstract

Organic Lake is a shallow, marine-derived hypersaline lake in the Vestfold Hills, Antarctica that has the highest reported concentration of dimethylsulfide (DMS) in a natural body of water. To determine the composition and functional potential of the microbial community and learn about the unusual sulfur chemistry in Organic Lake, shotgun metagenomics was performed on size-fractionated samples collected along a depth profile. Eucaryal phytoflagellates were the main photosynthetic organisms. Bacteria were dominated by the globally distributed heterotrophic taxa Marinobacter, Roseovarius and Psychroflexus. The dominance of heterotrophic degradation, coupled with low fixation potential, indicates possible net carbon loss. However, abundant marker genes for aerobic anoxygenic phototrophy, sulfur oxidation, rhodopsins and CO oxidation were also linked to the dominant heterotrophic bacteria, and indicate the use of photo- and lithoheterotrophy as mechanisms for conserving organic carbon. Similarly, a high genetic potential for the recycling of nitrogen compounds likely functions to retain fixed nitrogen in the lake. Dimethylsulfoniopropionate (DMSP) lyase genes were abundant, indicating that DMSP is a significant carbon and energy source. Unlike marine environments, DMSP demethylases were less abundant, indicating that DMSP cleavage is the likely source of high DMS concentration. DMSP cleavage, carbon mixotrophy (photoheterotrophy and lithoheterotrophy) and nitrogen remineralization by dominant Organic Lake bacteria are potentially important adaptations to nutrient constraints. In particular, carbon mixotrophy relieves the extent of carbon oxidation for energy production, allowing more carbon to be used for biosynthetic processes. The study sheds light on how the microbial community has adapted to this unique Antarctic lake environment.

Published

2013

69. Prevalent genome streamlining and latitudinal divergence of planktonic bacteria in the surface ocean.

Author

Swan BK, Tupper B, Sczyrba A, Lauro FM, Martinez-Garcia M, González JM, Luo H, Wright JJ, Landry ZC, Hanson NW, Thompson BP, Poulton NJ, Schwientek P, Acinas SG, Giovannoni SJ, Moran MA, Hallam SJ, Cavicchioli R, Woyke T, and Stepanauskas R

Subjects

Bacteria genetics, Geography, Oceans and Seas, Plankton genetics, Bacteria classification, Genome, Bacterial, Marine Biology, Plankton classification, Water Microbiology

Abstract

Planktonic bacteria dominate surface ocean biomass and influence global biogeochemical processes, but remain poorly characterized owing to difficulties in cultivation. Using large-scale single cell genomics, we obtained insight into the genome content and biogeography of many bacterial lineages inhabiting the surface ocean. We found that, compared with existing cultures, natural bacterioplankton have smaller genomes, fewer gene duplications, and are depleted in guanine and cytosine, noncoding nucleotides, and genes encoding transcription, signal transduction, and noncytoplasmic proteins. These findings provide strong evidence that genome streamlining and oligotrophy are prevalent features among diverse, free-living bacterioplankton, whereas existing laboratory cultures consist primarily of copiotrophs. The apparent ubiquity of metabolic specialization and mixotrophy, as predicted from single cell genomes, also may contribute to the difficulty in bacterioplankton cultivation. Using metagenome fragment recruitment against single cell genomes, we show that the global distribution of surface ocean bacterioplankton correlates with temperature and latitude and is not limited by dispersal at the time scales required for nucleotide substitution to exceed the current operational definition of bacterial species. Single cell genomes with highly similar small subunit rRNA gene sequences exhibited significant genomic and biogeographic variability, highlighting challenges in the interpretation of individual gene surveys and metagenome assemblies in environmental microbiology. Our study demonstrates the utility of single cell genomics for gaining an improved understanding of the composition and dynamics of natural microbial assemblages.

Published

2013

70. Complete Genome Sequence of the Deep-Sea Bacterium Psychromonas Strain CNPT3.

Author

Lauro FM, Stratton TK, Chastain RA, Ferriera S, Johnson J, Goldberg SM, Yayanos AA, and Bartlett DH

Abstract

Members of the genus Psychromonas are commonly found in polar and deep-sea environments. Here we present the genome of Psychromonas strain CNPT3. Historically, it was the first bacterium shown to piezoregulate the composition of its membrane lipids and to have a higher growth rate at 57 megapascals (MPa) than at 0.1 MPa.

Published

2013

71. Draft Genome Sequence of the Deep-Sea Bacterium Shewanella benthica Strain KT99.

Author

Lauro FM, Chastain RA, Ferriera S, Johnson J, Yayanos AA, and Bartlett DH

Abstract

We report the draft genome sequence of the obligately piezophilic Shewanella benthica strain KT99 isolated from the abyssal South Pacific Ocean. Strain KT99 is the first piezophilic isolate from the Tonga-Kermadec trench, and its genome provides many clues on high-pressure adaptation and the evolution of deep-sea piezophilic bacteria.

Published

2013

72. Key microbial drivers in Antarctic aquatic environments.

Author

Wilkins D, Yau S, Williams TJ, Allen MA, Brown MV, DeMaere MZ, Lauro FM, and Cavicchioli R

Subjects

Antarctic Regions, Biodiversity, Biomass, Carbon Dioxide metabolism, Metagenome, Water Microbiology

Abstract

Antarctica is arguably the world's most important continent for influencing the Earth's climate and ocean ecosystem function. The unique physico-chemical properties of the Southern Ocean enable high levels of microbial primary production to occur. This not only forms the base of a significant fraction of the global oceanic food web, but leads to the sequestration of anthropogenic CO2 and its transport to marine sediments, thereby removing it from the atmosphere; the Southern Ocean accounts for ~ 30% of global ocean uptake of CO2 despite representing ~ 10% of the total surface area of the global ocean. The Antarctic continent itself harbors some liquid water, including a remarkably diverse range of surface and subglacial lakes. Being one of the remaining natural frontiers, Antarctica delivers the paradox of needing to be protected from disturbance while requiring scientific endeavor to discover what is indigenous and learn how best to protect it. Moreover, like many natural environments on Earth, in Antarctica, microorganisms dominate the genetic pool and biomass of the colonizable niches and play the key roles in maintaining proper ecosystem function. This review puts into perspective insight that has been and can be gained about Antarctica's aquatic microbiota using molecular biology, and in particular, metagenomic approaches., (© 2012 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.)

Published

2013

73. Biogeographic partitioning of Southern Ocean microorganisms revealed by metagenomics.

Author

Wilkins D, Lauro FM, Williams TJ, Demaere MZ, Brown MV, Hoffman JM, Andrews-Pfannkoch C, McQuaid JB, Riddle MJ, Rintoul SR, and Cavicchioli R

Subjects

Amino Acids, Branched-Chain genetics, Bacteria metabolism, Cyanobacteria classification, Cyanobacteria genetics, Eukaryota genetics, Eukaryota metabolism, Eukaryota physiology, Oceans and Seas, Phylogeny, RNA, Ribosomal, 16S genetics, Seawater chemistry, Bacteria classification, Bacteria genetics, Biodiversity, Metagenomics, Seawater microbiology, Water Microbiology

Abstract

We performed a metagenomic survey (6.6 Gbp of 454 sequence data) of Southern Ocean (SO) microorganisms during the austral summer of 2007-2008, examining the genomic signatures of communities across a latitudinal transect from Hobart (44°S) to the Mertz Glacier, Antarctica (67°S). Operational taxonomic units (OTUs) of the SAR11 and SAR116 clades and the cyanobacterial genera Prochlorococcus and Synechococcus were strongly overrepresented north of the Polar Front (PF). Conversely, OTUs of the Gammaproteobacterial Sulfur Oxidizer-EOSA-1 (GSO-EOSA-1) complex, the phyla Bacteroidetes and Verrucomicrobia and order Rhodobacterales were characteristic of waters south of the PF. Functions enriched south of the PF included a range of transporters, sulfur reduction and histidine degradation to glutamate, while branched-chain amino acid transport, nucleic acid biosynthesis and methionine salvage were overrepresented north of the PF. The taxonomic and functional characteristics suggested a shift of primary production from cyanobacteria in the north to eukaryotic phytoplankton in the south, and reflected the different trophic statuses of the two regions. The study provides a new level of understanding about SO microbial communities, describing the contrasting taxonomic and functional characteristics of microbial assemblages either side of the PF., (© 2012 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2013

74. Advection shapes Southern Ocean microbial assemblages independent of distance and environment effects.

Author

Wilkins D, van Sebille E, Rintoul SR, Lauro FM, and Cavicchioli R

Subjects

Sequence Analysis, DNA, Microbial Consortia genetics, Oceans and Seas, Water Microbiology, Water Movements

Abstract

Although environmental selection and spatial separation have been shown to shape the distribution and abundance of marine microorganisms, the effects of advection (physical transport) have not been directly tested. Here we examine 25 samples covering all major water masses of the Southern Ocean to determine the effects of advection on microbial biogeography. Even when environmental factors and spatial separation are controlled for, there is a positive correlation between advection distance and taxonomic dissimilarity, indicating that an 'advection effect' has a role in shaping marine microbial community composition. This effect is likely due to the advection of cells increasing the probability that upstream microorganisms will colonize downstream sites. Our study shows that in addition to distance and environmental selection, advection shapes the composition of marine microbial communities.

Published

2013

75. A metaproteomic assessment of winter and summer bacterioplankton from Antarctic Peninsula coastal surface waters.

Author

Williams TJ, Long E, Evans F, Demaere MZ, Lauro FM, Raftery MJ, Ducklow H, Grzymski JJ, Murray AE, and Cavicchioli R

Subjects

Ammonia metabolism, Antarctic Regions, Bacteria metabolism, Crenarchaeota metabolism, Heterotrophic Processes, Nitrification, Oceans and Seas, Phylogeny, Plankton classification, Plankton metabolism, Water metabolism, Bacteria classification, Crenarchaeota classification, Proteome analysis, Seasons, Seawater microbiology

Abstract

A metaproteomic survey of surface coastal waters near Palmer Station on the Antarctic Peninsula, West Antarctica, was performed, revealing marked differences in the functional capacity of summer and winter communities of bacterioplankton. Proteins from Flavobacteria were more abundant in the summer metaproteome, whereas winter was characterized by proteins from ammonia-oxidizing Marine Group I Crenarchaeota. Proteins prevalent in both seasons were from SAR11 and Rhodobacterales clades of Alphaproteobacteria, as well as many lineages of Gammaproteobacteria. The metaproteome data were used to elucidate the main metabolic and energy generation pathways and transport processes occurring at the microbial level in each season. In summer, autotrophic carbon assimilation appears to be driven by oxygenic photoautotrophy, consistent with high light availability and intensity. In contrast, during the dark polar winter, the metaproteome supported the occurrence of chemolithoautotrophy via the 3-hydroxypropionate/4-hydroxybutyrate cycle and the reverse tricarboxylic acid cycle of ammonia-oxidizing archaea and nitrite-oxidizing bacteria, respectively. Proteins involved in nitrification were also detected in the metaproteome. Taurine appears to be an important source of carbon and nitrogen for heterotrophs (especially SAR11), with transporters and enzymes for taurine uptake and degradation abundant in the metaproteome. Divergent heterotrophic strategies for Alphaproteobacteria and Flavobacteria were indicated by the metaproteome data, with Alphaproteobacteria capturing (by high-affinity transport) and processing labile solutes, and Flavobacteria expressing outer membrane receptors for particle adhesion to facilitate the exploitation of non-labile substrates. TonB-dependent receptors from Gammaproteobacteria and Flavobacteria (particularly in summer) were abundant, indicating that scavenging of substrates was likely an important strategy for these clades of Southern Ocean bacteria. This study provides the first insight into differences in functional processes occurring between summer and winter microbial communities in coastal Antarctic waters, and particularly highlights the important role that 'dark' carbon fixation has in winter.

Published

2012

76. Global biogeography of SAR11 marine bacteria.

Author

Brown MV, Lauro FM, DeMaere MZ, Muir L, Wilkins D, Thomas T, Riddle MJ, Fuhrman JA, Andrews-Pfannkoch C, Hoffman JM, McQuaid JB, Allen A, Rintoul SR, and Cavicchioli R

Subjects

Antarctic Regions, Climate, Genome, Bacterial genetics, Marine Biology, Metagenome genetics, Phylogeny, Phylogeography, Sequence Alignment, Temperature, Alphaproteobacteria genetics, Genome, Bacterial radiation effects, Metagenome radiation effects, Models, Biological, Seawater microbiology

Abstract

The ubiquitous SAR11 bacterial clade is the most abundant type of organism in the world's oceans, but the reasons for its success are not fully elucidated. We analysed 128 surface marine metagenomes, including 37 new Antarctic metagenomes. The large size of the data set enabled internal transcribed spacer (ITS) regions to be obtained from the Southern polar region, enabling the first global characterization of the distribution of SAR11, from waters spanning temperatures -2 to 30°C. Our data show a stable co-occurrence of phylotypes within both 'tropical' (>20°C) and 'polar' (<10°C) biomes, highlighting ecological niche differentiation between major SAR11 subgroups. All phylotypes display transitions in abundance that are strongly correlated with temperature and latitude. By assembling SAR11 genomes from Antarctic metagenome data, we identified specific genes, biases in gene functions and signatures of positive selection in the genomes of the polar SAR11-genomic signatures of adaptive radiation. Our data demonstrate the importance of adaptive radiation in the organism's ability to proliferate throughout the world's oceans, and describe genomic traits characteristic of different phylotypes in specific marine biomes.

Published

2012

77. Simple high-throughput annotation pipeline (SHAP).

Author

DeMaere MZ, Lauro FM, Thomas T, Yau S, and Cavicchioli R

Subjects

Humans, Information Storage and Retrieval, Internet, Molecular Sequence Annotation methods, Sequence Analysis, DNA, Software

Abstract

Summary: SHAP (simple high-throughput annotation pipeline) is a lightweight and scalable sequence annotation pipeline capable of supporting research efforts that generate or utilize large volumes of DNA sequence data. The software provides Grid capable analysis, relational storage and Web-based full-text searching of annotation results. Implemented in Java, SHAP recognizes the limited resources of many smaller research groups., Availability: Source code is freely available under GPLv3 at https://sourceforge.net/projects/shap., Contact: matt.demaere@unsw.edu.au; r.cavicchioli@unsw.edu.au.

Published

2011

78. The RNA polymerase subunits E/F from the Antarctic archaeon Methanococcoides burtonii bind to specific species of mRNA.

Author

De Francisci D, Campanaro S, Kornfeld G, Siddiqui KS, Williams TJ, Ertan H, Treu L, Pilak O, Lauro FM, Harrop SJ, Curmi PM, and Cavicchioli R

Subjects

Antarctic Regions, Archaeal Proteins genetics, Archaeal Proteins metabolism, Methanosarcinaceae metabolism, Protein Binding, Protein Biosynthesis, RNA, Messenger genetics, Recombinant Proteins metabolism, DNA-Directed RNA Polymerases metabolism, Methanosarcinaceae enzymology, Methanosarcinaceae genetics, RNA, Messenger metabolism

Abstract

RNA polymerase in Archaea is composed of 11 or 12 subunits - 9 or 10 that form the core, and a heterodimer formed from subunits E and F that associates with the core and can interact with general transcription factors and facilitate transcription. While the ability of the heterodimer to bind RNA has been demonstrated, it has not been determined whether it can recognize specific RNA targets. In this study we used a recombinant archaeal MbRpoE/F to capture cellular mRNA in vitro and a microarray to determine which transcripts it specifically binds. Only transcripts for 117 genes (4% of the total) representing 48 regions of the genome were bound by MbRpoE/F. The transcripts represented important genes in a number of functional classes: methanogenesis, cofactor biosynthesis, nucleotide metabolism, transcription, translation, import/export. The arrangement and characteristics (e.g. codon and amino acid usage) of genes relative to the putative origin of replication indicate that MbRpoE/F preferentially binds to mRNA of genes whose expression may be important for cellular fitness. We also compared the biophysical properties of RpoE/F from M. burtonii and Methanocaldococcus jannaschii, demonstrating a 50°C difference in their apparent melting temperatures. By using MbRpoE/F to capture and characterize cellular RNA we have identified a previously unknown functional property of the MbRpoE/F heterodimer., (© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2011

79. Defining the response of a microorganism to temperatures that span its complete growth temperature range (-2°C to 28°C) using multiplex quantitative proteomics.

Author

Williams TJ, Lauro FM, Ertan H, Burg DW, Poljak A, Raftery MJ, and Cavicchioli R

Subjects

Adaptation, Physiological genetics, Antarctic Regions, Gene Expression Profiling, Methanosarcinaceae genetics, Methanosarcinaceae growth & development, Methanosarcinaceae metabolism, Methanosarcinaceae physiology, Proteomics, Temperature

Abstract

The growth of all microorganisms is limited to a specific temperature range. However, it has not previously been determined to what extent global protein profiles change in response to temperatures that incrementally span the complete growth temperature range of a microorganism. As a result it has remained unclear to what extent cellular processes (inferred from protein abundance profiles) are affected by growth temperature and which, in particular, constrain growth at upper and lower temperature limits. To evaluate this, 8-plex iTRAQ proteomics was performed on the Antarctic microorganism, Methanococcoides burtonii. Methanococcoides burtonii was chosen due to its importance as a model psychrophilic (cold-adapted) member of the Archaea, and the fact that proteomic methods, including subcellular fractionation procedures, have been well developed. Differential abundance patterns were obtained for cells grown at seven different growth temperatures (-2°C, 1°C, 4°C, 10°C, 16°C, 23°C, 28°C) and a principal component analysis (PCA) was performed to identify trends in protein abundances. The multiplex analysis enabled three largely distinct physiological states to be described: cold stress (-2°C), cold adaptation (1°C, 4°C, 10°C and 16°C), and heat stress (23°C and 28°C). A particular feature of the thermal extremes was the synthesis of heat- and cold-specific stress proteins, reflecting the important, yet distinct ways in which temperature-induced stress manifests in the cell. This is the first quantitative proteomic investigation to simultaneously assess the response of a microorganism to numerous growth temperatures, including the upper and lower growth temperatures limits, and has revealed a new level of understanding about cellular adaptive responses., (© 2011 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2011

80. Temperature-dependent global gene expression in the Antarctic archaeon Methanococcoides burtonii.

Author

Campanaro S, Williams TJ, Burg DW, De Francisci D, Treu L, Lauro FM, and Cavicchioli R

Subjects

Adaptation, Physiological genetics, Antarctic Regions, Archaeal Proteins genetics, Gene Expression Profiling, Operon, Proteomics, Gene Expression Regulation, Archaeal, Methanosarcinaceae genetics, Methanosarcinaceae metabolism, Temperature

Abstract

Methanococcoides burtonii is a member of the Archaea that was isolated from Ace Lake in Antarctica and is a valuable model for studying cold adaptation. Low temperature transcriptional regulation of global gene expression, and the arrangement of transcriptional units in cold-adapted archaea has not been studied. We developed a microarray for determining which genes are expressed in operons, and which are differentially expressed at low (4°C) or high (23°C) temperature. Approximately 55% of genes were found to be arranged in operons that range in length from 2 to 23 genes, and mRNA abundance tended to increase with operon length. Analysing microarray data previously obtained by others for Halobacterium salinarum revealed a similar correlation between operon length and mRNA abundance, suggesting that operons may play a similar role more broadly in the Archaea. More than 500 genes were differentially expressed at levels up to ≈ 24-fold. A notable feature was the upregulation of genes involved in maintaining RNA in a state suitable for translation in the cold. Comparison between microarray experiments and results previously obtained using proteomics indicates that transcriptional regulation (rather than translation) is primarily responsible for controlling gene expression in M. burtonii. In addition, certain genes (e.g. involved in ribosome structure and methanogenesis) appear to be regulated post-transcriptionally. This is one of few experimental studies describing the genome-wide distribution and regulation of operons in archaea., (© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2011

81. An integrative study of a meromictic lake ecosystem in Antarctica.

Author

Lauro FM, DeMaere MZ, Yau S, Brown MV, Ng C, Wilkins D, Raftery MJ, Gibson JA, Andrews-Pfannkoch C, Lewis M, Hoffman JM, Thomas T, and Cavicchioli R

Subjects

Antarctic Regions, Chlorobi growth & development, Chlorobi virology, Fresh Water chemistry, Microbial Interactions, Models, Biological, Open Reading Frames, Phylogeny, Proteome analysis, Seasons, Chlorobi metabolism, Ecosystem, Fresh Water microbiology, Fresh Water virology, Viruses growth & development

Abstract

In nature, the complexity and structure of microbial communities varies widely, ranging from a few species to thousands of species, and from highly structured to highly unstructured communities. Here, we describe the identity and functional capacity of microbial populations within distinct layers of a pristine, marine-derived, meromictic (stratified) lake (Ace Lake) in Antarctica. Nine million open reading frames were analyzed, representing microbial samples taken from six depths of the lake size fractionated on sequential 3.0, 0.8 and 0.1 μm filters, and including metaproteome data from matching 0.1 μm filters. We determine how the interactions of members of this highly structured and moderately complex community define the biogeochemical fluxes throughout the entire lake. Our view is that the health of this delicate ecosystem is dictated by the effects of the polar light cycle on the dominant role of green sulfur bacteria in primary production and nutrient cycling, and the influence of viruses/phage and phage resistance on the cooperation between members of the microbial community right throughout the lake. To test our assertions, and develop a framework applicable to other microbially driven ecosystems, we developed a mathematical model that describes how cooperation within a microbial system is impacted by periodic fluctuations in environmental parameters on key populations of microorganisms. Our study reveals a mutualistic structure within the microbial community throughout the lake that has arisen as the result of mechanistic interactions between the physico-chemical parameters and the selection of individual members of the community. By exhaustively describing and modelling interactions in Ace Lake, we have developed an approach that may be applicable to learning how environmental perturbations affect the microbial dynamics in more complex aquatic systems.

Published

2011

82. Virophage control of antarctic algal host-virus dynamics.

Author

Yau S, Lauro FM, DeMaere MZ, Brown MV, Thomas T, Raftery MJ, Andrews-Pfannkoch C, Lewis M, Hoffman JM, Gibson JA, and Cavicchioli R

Subjects

Antarctic Regions, Base Sequence, Genetic Variation, Molecular Sequence Data, Phycodnaviridae classification, Phylogeny, Stramenopiles, Fresh Water virology, Genome, Viral genetics, Metagenome genetics, Phycodnaviridae genetics, Phycodnaviridae physiology

Abstract

Viruses are abundant ubiquitous members of microbial communities and in the marine environment affect population structure and nutrient cycling by infecting and lysing primary producers. Antarctic lakes are microbially dominated ecosystems supporting truncated food webs in which viruses exert a major influence on the microbial loop. Here we report the discovery of a virophage (relative of the recently described Sputnik virophage) that preys on phycodnaviruses that infect prasinophytes (phototrophic algae). By performing metaproteogenomic analysis on samples from Organic Lake, a hypersaline meromictic lake in Antarctica, complete virophage and near-complete phycodnavirus genomes were obtained. By introducing the virophage as an additional predator of a predator-prey dynamic model we determined that the virophage stimulates secondary production through the microbial loop by reducing overall mortality of the host and increasing the frequency of blooms during polar summer light periods. Virophages remained abundant in the lake 2 y later and were represented by populations with a high level of major capsid protein sequence variation (25-100% identity). Virophage signatures were also found in neighboring Ace Lake (in abundance) and in two tropical lakes (hypersaline and fresh), an estuary, and an ocean upwelling site. These findings indicate that virophages regulate host-virus interactions, influence overall carbon flux in Organic Lake, and play previously unrecognized roles in diverse aquatic ecosystems.

Published

2011

83. Cold adaptation in the marine bacterium, Sphingopyxis alaskensis, assessed using quantitative proteomics.

Author

Ting L, Williams TJ, Cowley MJ, Lauro FM, Guilhaus M, Raftery MJ, and Cavicchioli R

Subjects

Amino Acids metabolism, Bacterial Proteins metabolism, Cell Membrane physiology, Cell Wall physiology, Fatty Acids metabolism, Gene Expression Regulation, Bacterial, Homeostasis, Iron metabolism, Protein Folding, Seawater chemistry, Seawater microbiology, Sphingomonadaceae isolation & purification, Sphingomonadaceae metabolism, Adaptation, Physiological, Cold Temperature, Proteome metabolism, Sphingomonadaceae physiology

Abstract

The cold marine environment constitutes a large proportion of the Earth's biosphere. Sphingopyxis alaskensis was isolated as a numerically abundant bacterium from several cold marine locations, and has been extensively studied as a model marine bacterium. Recently, a metabolic labelling platform was developed to comprehensively identify and quantify proteins from S. alaskensis. The approach incorporated data normalization and statistical validation for the purpose of generating highly confident quantitative proteomics data. Using this approach, we determined quantitative differences between cells grown at 10°C (low temperature) and 30°C (high temperature). Cold adaptation was linked to specific aspects of gene expression: a dedicated protein-folding system using GroESL, DnaK, DnaJ, GrpE, SecB, ClpB and PPIase; polyhydroxyalkanoate-associated storage materials; a link between enzymes in fatty acid metabolism and energy generation; de novo synthesis of polyunsaturated fatty acids in the membrane and cell wall; inorganic phosphate ion transport by a phosphate import PstB homologue; TonB-dependent receptor and bacterioferritin in iron homeostasis; histidine, tryptophan and proline amino acid metabolism; and a large number of proteins without annotated functions. This study provides a new level of understanding on how important marine bacteria can adapt to compete effectively in cold marine environments. This study is also a benchmark for comparative proteomic analyses with other important marine bacteria and other cold-adapted organisms., (© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2010

84. Metaproteogenomic analysis of a dominant green sulfur bacterium from Ace Lake, Antarctica.

Author

Ng C, DeMaere MZ, Williams TJ, Lauro FM, Raftery M, Gibson JA, Andrews-Pfannkoch C, Lewis M, Hoffman JM, Thomas T, and Cavicchioli R

Subjects

Antarctic Regions, Bacterial Proteins genetics, Bacterial Proteins metabolism, Chlorobi isolation & purification, Molecular Sequence Data, Chlorobi genetics, Chlorobi metabolism, Fresh Water microbiology, Metagenomics, Proteomics, Sulfur metabolism

Abstract

Green sulfur bacteria (GSB) (Chlorobiaceae) are primary producers that are important in global carbon and sulfur cycling in natural environments. An almost complete genome sequence for a single, dominant GSB species ('C-Ace') was assembled from shotgun sequence data of an environmental sample taken from the O(2)-H(2)S interface of the water column of Ace Lake, Antarctica. Approximately 34 Mb of DNA sequence data were assembled into nine scaffolds totaling 1.79 Mb, representing approximately 19-fold coverage for the C-Ace composite genome. A high level ( approximately 31%) of metaproteomic coverage was achieved using matched biomass. The metaproteogenomic approach provided unique insight into the protein complement required for dominating the microbial community under cold, nutrient-limited, oxygen-limited and extremely varied annual light conditions. C-Ace shows physiological traits that promote its ability to compete very effectively with other GSB and gain dominance (for example, specific bacteriochlorophylls, mechanisms of cold adaptation) as well as a syntrophic relationship with sulfate-reducing bacteria that provides a mechanism for the exchange of sulfur compounds. As a result we are able to propose an explanation of the active biological processes promoted by cold-adapted GSB and the adaptive strategies they use to thrive under the severe physiochemical conditions prevailing in polar environments.

Published

2010

85. Analyzing the hydrophobic proteome of the antarctic archaeon Methanococcoides burtonii using differential solubility fractionation.

Author

Burg DW, Lauro FM, Williams TJ, Raftery MJ, Guilhaus M, and Cavicchioli R

Subjects

Mass Spectrometry, Signal Transduction, Solubility, Archaeal Proteins metabolism, Methanosarcinaceae metabolism, Proteome

Abstract

Proteomic studies have proven useful for studying the Antarctic archaeon Methanococcoides burtonii; however, little has been learned about the hydrophobic and membrane proteins, despite knowledge of their biological importance. In this study, new methods were developed to analyze and maximize the coverage of the hydrophobic proteome. Central to the analysis was a differential solubility fractionation (DSF) procedure using n-octyl-beta-D-glucopyranoside. The study achieved a significant increase (330) in the total number of known expressed proteins. From 612 identified, 185 were predicted to contain transmembrane domains or be associated with the membrane and 190 to be hydrophobic. The DSF procedure increased the efficacy of identifying membrane proteins by up to 169% and was economical, requiring far fewer runs (12% of machine time) to analyze the proteome compared to procedures without DSF. The analysis of peptide spectral counts enabled the assessment of growth temperature specific proteins. This semiquantitative analysis was particularly useful for identifying low abundance proteins unable to be quantified using labeling strategies. The proteogenomic analysis of the newly identified proteins revealed many cellular processes not previously associated with adaptation of the cell. This DSF-based approach is likely to benefit proteomic analyses of hydrophobic proteins for a broad range of biological systems.

Published

2010

86. Insights into piezophily from genetic studies on the deep-sea bacterium, Photobacterium profundum SS9.

Author

El-Hajj ZW, Allcock D, Tryfona T, Lauro FM, Sawyer L, Bartlett DH, and Ferguson GP

Subjects

Adaptation, Physiological, Bacterial Proteins genetics, Bacterial Proteins metabolism, Cell Membrane metabolism, Cold Temperature, DNA, Bacterial genetics, DNA, Bacterial metabolism, Genes, Bacterial, Models, Biological, Photobacterium growth & development, Hydrostatic Pressure, Photobacterium genetics, Photobacterium physiology, Seawater microbiology

Abstract

The deep-sea bacterium, Photobacterium profundum SS9, has been adopted as a model organism to understand the molecular basis of cold-adapted high-pressure-loving (piezophilic) growth. Despite growing optimally at 28 MPa (15 degrees C), P. profundum SS9 can grow over a wide range of pressures and temperatures. The ability to grow at atmospheric pressure has enabled a limited set of genetic tools to be developed, which has provided genetic insights into the mechanism of piezophilic growth in P. profundum SS9. This review focuses on how genetic studies have uncovered the importance of processes affecting the DNA and the bacterial cell envelope in the piezophilic growth of P. profundum SS9. In addition, a method was developed to assess quantitative piezophilic colony growth of P. profundum SS9 on solid agar. Future studies, using this methodology, could provide novel insights into the molecular basis of piezophilic, surface-attached growth.

Published

2010

87. Microbial community structure in the North Pacific ocean.

Author

Brown MV, Philip GK, Bunge JA, Smith MC, Bissett A, Lauro FM, Fuhrman JA, and Donachie SP

Subjects

Archaea genetics, Bacteria genetics, Cluster Analysis, DNA Primers genetics, DNA, Ribosomal genetics, DNA, Ribosomal isolation & purification, Eukaryota genetics, Genes, rRNA genetics, Hawaii, Pacific Ocean, Polymerase Chain Reaction methods, Archaea classification, Bacteria classification, Biodiversity, Eukaryota classification, Seawater microbiology

Abstract

We report a ribosomal tag pyrosequencing study of the phylogenetic diversity of Archaea, Bacteria and Eucarya over a depth profile at the Hawaii Ocean Time-Series Station, ALOHA. The V9 region of the SSU rRNA gene was amplified from samples representing the epi- (10 m), meso- (800 m) and bathy- (4400 m) pelagia. The primers used are expected to amplify representatives of approximately 80% of known phylogenetic diversity across all three domains. Comparisons of unique sequences revealed a remarkably low degree of overlap between communities at each depth. The 444 147 sequence tags analyzed represented 62 975 unique sequences. Of these, 3707 (5.9%) occurred at two depths, and only 298 (0.5%) were observed at all three depths. At this level of phylogenetic resolution, Bacteria diversity decreased with depth but was still equivalent to that reported elsewhere for different soil types. Archaea diversity was highest in the two deeper samples. Eucarya observations and richness estimates are almost one order of magnitude higher than any previous marine microbial Eucarya richness estimates. The associations of many Eucarya sequences with putative parasitic organisms may have significant impacts on our understanding of the mechanisms controlling host population density and diversity, and point to a more significant role for microbial Eucarya in carbon flux through the microbial loop. We posit that the majority of sequences detected from the deep sea that have closest matches to sequences from non-pelagic sources are indeed native to the marine environment, and are possibly responsible for key metabolic processes in global biogeochemical cycles.

Published

2009

88. Mining cyanobacterial genomes for genes encoding complex biosynthetic pathways.

Author

Kalaitzis JA, Lauro FM, and Neilan BA

Subjects

Genes, Biological Products biosynthesis, Biological Products genetics, Biological Products metabolism, Biosynthetic Pathways genetics, Cyanobacteria genetics, Cyanobacteria metabolism

Published

2009

89. Importance of proteins controlling initiation of DNA replication in the growth of the high-pressure-loving bacterium Photobacterium profundum SS9.

Author

El-Hajj ZW, Tryfona T, Allcock DJ, Hasan F, Lauro FM, Sawyer L, Bartlett DH, and Ferguson GP

Subjects

Bacterial Proteins genetics, Cold Temperature, Escherichia coli genetics, Escherichia coli metabolism, Genes, Bacterial, Lipopolysaccharides metabolism, Mutation, Photobacterium genetics, Photobacterium metabolism, Plasmids metabolism, Bacterial Proteins metabolism, DNA Replication physiology, Gene Expression Regulation, Bacterial physiology, Photobacterium growth & development

Abstract

The molecular mechanism(s) by which deep-sea bacteria grow optimally under high hydrostatic pressure at low temperatures is poorly understood. To gain further insight into the mechanism(s), a previous study screened transposon mutant libraries of the deep-sea bacterium Photobacterium profundum SS9 and identified mutants which exhibited alterations in growth at high pressure relative to that of the parent strain. Two of these mutants, FL23 (PBPRA3229::mini-Tn10) and FL28 (PBPRA1039::mini-Tn10), were found to have high-pressure sensitivity and enhanced-growth phenotypes, respectively. The PBPRA3229 and PBPRA1039 genes encode proteins which are highly similar to Escherichia coli DiaA, a positive regulator, and SeqA, a negative regulator, respectively, of the initiation of DNA replication. In this study, we investigated the hypothesis that PBPRA3229 and PBPRA1039 encode DiaA and SeqA homologs, respectively. Consistent with this, we determined that the plasmid-carried PBPRA3229 and PBPRA1039 genes restored synchrony to the initiation of DNA replication in E. coli mutants lacking DiaA and SeqA, respectively. Additionally, PBPRA3229 restored the cold sensitivity phenotype of an E. coli dnaA(Cs) diaA double mutant whereas PBPRA1039 suppressed the cold sensitivity phenotype of an E. coli dnaA(Cs) single mutant. Taken together, these findings show that the genes disrupted in FL23 and FL28 encode DiaA and SeqA homologs, respectively. Consequently, our findings add support to a model whereby high pressure affects the initiation of DNA replication in P. profundum SS9 and either the presence of a positive regulator (DiaA) or the removal of a negative regulator (SeqA) promotes growth under these conditions.

Published

2009

90. The genomic basis of trophic strategy in marine bacteria.

Author

Lauro FM, McDougald D, Thomas T, Williams TJ, Egan S, Rice S, DeMaere MZ, Ting L, Ertan H, Johnson J, Ferriera S, Lapidus A, Anderson I, Kyrpides N, Munk AC, Detter C, Han CS, Brown MV, Robb FT, Kjelleberg S, and Cavicchioli R

Subjects

Ecosystem, Marine Biology, Models, Biological, Molecular Sequence Data, Photobacterium genetics, Photobacterium growth & development, Sphingomonadaceae genetics, Sphingomonadaceae growth & development, Bacteria genetics, Bacteria growth & development, Genome, Bacterial

Abstract

Many marine bacteria have evolved to grow optimally at either high (copiotrophic) or low (oligotrophic) nutrient concentrations, enabling different species to colonize distinct trophic habitats in the oceans. Here, we compare the genome sequences of two bacteria, Photobacterium angustum S14 and Sphingopyxis alaskensis RB2256, that serve as useful model organisms for copiotrophic and oligotrophic modes of life and specifically relate the genomic features to trophic strategy for these organisms and define their molecular mechanisms of adaptation. We developed a model for predicting trophic lifestyle from genome sequence data and tested >400,000 proteins representing >500 million nucleotides of sequence data from 126 genome sequences with metagenome data of whole environmental samples. When applied to available oceanic metagenome data (e.g., the Global Ocean Survey data) the model demonstrated that oligotrophs, and not the more readily isolatable copiotrophs, dominate the ocean's free-living microbial populations. Using our model, it is now possible to define the types of bacteria that specific ocean niches are capable of sustaining.

Published

2009

91. The genome sequence of the psychrophilic archaeon, Methanococcoides burtonii: the role of genome evolution in cold adaptation.

Author

Allen MA, Lauro FM, Williams TJ, Burg D, Siddiqui KS, De Francisci D, Chong KW, Pilak O, Chew HH, De Maere MZ, Ting L, Katrib M, Ng C, Sowers KR, Galperin MY, Anderson IJ, Ivanova N, Dalin E, Martinez M, Lapidus A, Hauser L, Land M, Thomas T, and Cavicchioli R

Subjects

Adaptation, Biological, Cold Temperature, DNA, Archaeal chemistry, Evolution, Molecular, Genes, Archaeal, Molecular Sequence Data, DNA, Archaeal genetics, Genome, Archaeal, Methanosarcinaceae genetics, Sequence Analysis, DNA

Abstract

Psychrophilic archaea are abundant and perform critical roles throughout the Earth's expansive cold biosphere. Here we report the first complete genome sequence for a psychrophilic methanogenic archaeon, Methanococcoides burtonii. The genome sequence was manually annotated including the use of a five-tiered evidence rating (ER) system that ranked annotations from ER1 (gene product experimentally characterized from the parent organism) to ER5 (hypothetical gene product) to provide a rapid means of assessing the certainty of gene function predictions. The genome is characterized by a higher level of aberrant sequence composition (51%) than any other archaeon. In comparison to hyper/thermophilic archaea, which are subject to selection of synonymous codon usage, M. burtonii has evolved cold adaptation through a genomic capacity to accommodate highly skewed amino-acid content, while retaining codon usage in common with its mesophilic Methanosarcina cousins. Polysaccharide biosynthesis genes comprise at least 3.3% of protein coding genes in the genome, and Cell wall, membrane, envelope biogenesis COG genes are overrepresented. Likewise, signal transduction (COG category T) genes are overrepresented and M. burtonii has a high 'IQ' (a measure of adaptive potential) compared to many methanogens. Numerous genes in these two overrepresented COG categories appear to have been acquired from epsilon- and delta-Proteobacteria, as do specific genes involved in central metabolism such as a novel B form of aconitase. Transposases also distinguish M. burtonii from other archaea, and their genomic characteristics indicate they have an important role in evolving the M. burtonii genome. Our study reveals a capacity for this model psychrophile to evolve through genome plasticity (including nucleotide skew, horizontal gene transfer and transposase activity) that enables adaptation to the cold, and to the biological and physical changes that have occurred over the last several thousand years as it adapted from a marine to an Antarctic lake environment.

Published

2009

92. The deep-sea bacterium Photobacterium profundum SS9 utilizes separate flagellar systems for swimming and swarming under high-pressure conditions.

Author

Eloe EA, Lauro FM, Vogel RF, and Bartlett DH

Subjects

Escherichia coli physiology, Flagella genetics, Gene Deletion, Gene Expression Profiling, Gene Expression Regulation, Bacterial, Gene Order, Genes, Bacterial, Multigene Family, Photobacterium genetics, Flagella physiology, Hydrostatic Pressure, Locomotion, Photobacterium physiology

Abstract

Motility is a critical function needed for nutrient acquisition, biofilm formation, and the avoidance of harmful chemicals and predators. Flagellar motility is one of the most pressure-sensitive cellular processes in mesophilic bacteria; therefore, it is ecologically relevant to determine how deep-sea microbes have adapted their motility systems for functionality at depth. In this study, the motility of the deep-sea piezophilic bacterium Photobacterium profundum SS9 was investigated and compared with that of the related shallow-water piezosensitive strain Photobacterium profundum 3TCK, as well as that of the well-studied piezosensitive bacterium Escherichia coli. The SS9 genome contains two flagellar gene clusters: a polar flagellum gene cluster (PF) and a putative lateral flagellum gene cluster (LF). In-frame deletions were constructed in the two flagellin genes located within the PF cluster (flaA and flaC), the one flagellin gene located within the LF cluster (flaB), a component of a putative sodium-driven flagellar motor (motA2), and a component of a putative proton-driven flagellar motor (motA1). SS9 PF flaA, flaC, and motA2 mutants were defective in motility under all conditions tested. In contrast, the flaB and motA1 mutants were defective only under conditions of high pressure and high viscosity. flaB and motA1 gene expression was strongly induced by elevated pressure plus increased viscosity. Direct swimming velocity measurements were obtained using a high-pressure microscopic chamber, where increases in pressure resulted in a striking decrease in swimming velocity for E. coli and a gradual reduction for 3TCK which proceeded up to 120 MPa, while SS9 increased swimming velocity at 30 MPa and maintained motility up to a maximum pressure of 150 MPa. Our results indicate that P. profundum SS9 possesses two distinct flagellar systems, both of which have acquired dramatic adaptations for optimal functionality under high-pressure conditions.

Published

2008

93. An assessment of actinobacterial diversity in the marine environment.

Author

Jensen PR and Lauro FM

Subjects

Actinobacteria isolation & purification, DNA, Bacterial genetics, DNA, Ribosomal genetics, Databases, Nucleic Acid, Genome, Bacterial, Phylogeny, RNA, Ribosomal, 16S genetics, Actinobacteria classification, Actinobacteria genetics, Biodiversity, Seawater microbiology

Abstract

The 16S rRNA gene sequence diversity within the Phylum Actinobacteria was assessed from four sources: PCR-generated V6 sequence tags derived from seawater samples, metagenomic data from the Global Ocean Sampling (GOS) expedition, marine-derived sequences maintained in the Ribosomal Database Project (RDP), and select cultured strains for which sequence data is not yet available in the RDP. This meta-analysis revealed remarkable levels of phylogenetic diversity and confirms the existence of major, deeply rooted, and as of yet uncharacterized lineages within the phylum. A dramatic incongruence among cultured strains and those detected using culture-independent techniques was also revealed. Redundancy among the actinobacteria detected using culture-independent techniques suggests that greater sequence coverage or improved DNA extraction efficiencies may be required to detect the rare phylotypes that can be readily cultured from marine samples. Conversely, new strategies need to be developed for the cultivation of frequently observed but yet to be cultured marine actinobacteria.

Published

2008

94. Large-scale transposon mutagenesis of Photobacterium profundum SS9 reveals new genetic loci important for growth at low temperature and high pressure.

Author

Lauro FM, Tran K, Vezzi A, Vitulo N, Valle G, and Bartlett DH

Subjects

Atmospheric Pressure, Biological Transport, Cell Membrane metabolism, Chromosomes, Bacterial genetics, Cold Temperature, Gene Expression Regulation, Bacterial, Genetic Complementation Test, Models, Genetic, Molecular Sequence Data, Mutagenesis, Polymerase Chain Reaction, Sequence Analysis, DNA, Signal Transduction genetics, Temperature, Adaptation, Physiological genetics, Genes, Bacterial, Photobacterium genetics, Photobacterium growth & development, Retroelements genetics

Abstract

Microorganisms adapted to piezopsychrophilic growth dominate the majority of the biosphere that is at relatively constant low temperatures and high pressures, but the genetic bases for the adaptations are largely unknown. Here we report the use of transposon mutagenesis with the deep-sea bacterium Photobacterium profundum strain SS9 to isolate dozens of mutant strains whose growth is impaired at low temperature and/or whose growth is altered as a function of hydrostatic pressure. In many cases the gene mutation-growth phenotype relationship was verified by complementation analysis. The largest fraction of loci associated with temperature sensitivity were involved in the biosynthesis of the cell envelope, in particular the biosynthesis of extracellular polysaccharide. The largest fraction of loci associated with pressure sensitivity were involved in chromosomal structure and function. Genes for ribosome assembly and function were found to be important for both low-temperature and high-pressure growth. Likewise, both adaptation to temperature and adaptation to pressure were affected by mutations in a number of sensory and regulatory loci, suggesting the importance of signal transduction mechanisms in adaptation to either physical parameter. These analyses were the first global analyses of genes conditionally required for low-temperature or high-pressure growth in a deep-sea microorganism.

Published

2008

95. Prokaryotic lifestyles in deep sea habitats.

Author

Lauro FM and Bartlett DH

Subjects

Oceans and Seas, Genome physiology, Prokaryotic Cells physiology, Seawater microbiology, Water Microbiology

Abstract

Gradients of physicochemical factors influence the growth and survival of life in deep-sea environments. Insights into the characteristics of deep marine prokaryotes has greatly benefited from recent progress in whole genome and metagenome sequence analyses. Here we review the current state-of-the-art of deep-sea microbial genomics. Ongoing and future genome-enabled studies will allow for a better understanding of deep-sea evolution, physiology, biochemistry, community structure and nutrient cycling.

Published

2008

96. The unique 16S rRNA genes of piezophiles reflect both phylogeny and adaptation.

Author

Lauro FM, Chastain RA, Blankenship LE, Yayanos AA, and Bartlett DH

Subjects

Base Sequence, Cold Temperature, Genes, rRNA genetics, Molecular Sequence Data, Sequence Analysis, DNA, Adaptation, Physiological, Gammaproteobacteria classification, Gammaproteobacteria genetics, Gammaproteobacteria isolation & purification, Gram-Positive Bacteria classification, Gram-Positive Bacteria genetics, Gram-Positive Bacteria isolation & purification, Hydrostatic Pressure, Phylogeny, RNA, Ribosomal, 16S genetics, Seawater microbiology

Abstract

In the ocean's most extreme depths, pressures of 70 to 110 megapascals prevent the growth of all but the most hyperpiezophilic (pressure-loving) organisms. The physiological adaptations required for growth under these conditions are considered to be substantial. Efforts to determine specific adaptations permitting growth at extreme pressures have thus far focused on relatively few gamma-proteobacteria, in part due to the technical difficulties of obtaining piezophilic bacteria in pure culture. Here, we present the molecular phylogenies of several new piezophiles of widely differing geographic origins. Included are results from an analysis of the first deep-trench bacterial isolates recovered from the southern hemisphere (9.9-km depth) and of the first gram-positive piezophilic strains. These new data allowed both phylogenetic and structural 16S rRNA comparisons among deep-ocean trench piezophiles and closely related strains not adapted to high pressure. Our results suggest that (i) the Circumpolar Deep Water acts as repository for hyperpiezophiles and drives their dissemination to deep trenches in the Pacific Ocean and (ii) the occurrence of elongated helices in the 16S rRNA genes increases with the extent of adaptation to growth at elevated pressure. These helix changes are believed to improve ribosome function under deep-sea conditions.

Published

2007

97. Piezophilic adaptation: a genomic point of view.

Author

Simonato F, Campanaro S, Lauro FM, Vezzi A, D'Angelo M, Vitulo N, Valle G, and Bartlett DH

Subjects

Biotechnology, DNA Damage, Genome, Bacterial genetics, Hydrostatic Pressure, Photobacterium physiology, Water Microbiology, Acclimatization genetics, Bacterial Physiological Phenomena, Photobacterium genetics, Seawater microbiology

Abstract

Two-thirds of Earth's surface is covered by oceans, yet the study of this massive integrated living system is still in its infancy. Various environmental variables, such as high salinity, low and changeable nutrient availability and depth-correlated gradients of light, temperature, nutrients and pressure shape the diversity, physiology and ecology of marine species. As oceans present an average depth of 3800 m, deep-sea ecosystems represent the most common marine ecological niche. One of the key environment variables that influences the life and evolution of deep-sea organisms is high pressure. This extreme widespread condition requires specific adaptations, the nature of which remains largely unknown. Recent advances in genomic approaches, such as in sequencing technologies and global expression profiling, are rapidly increasing the data available to understand microbial evolution, biochemistry, physiology and diversity. This review summarises the analysis of the results published so far about microbial high pressure adaptation from a genomic point of view. Understanding high pressure adaptation mechanisms is not just a scientific exercise but has important biotechnological implications. For example, hydrostatic pressure is a reality for food science and technology, both for food preparation and preservation. An understanding of the effects of pressure on biomolecules will expand its use in the medical, industrial and biotechnological fields.

Published

2006

98. A Sanger/pyrosequencing hybrid approach for the generation of high-quality draft assemblies of marine microbial genomes.

Author

Goldberg SM, Johnson J, Busam D, Feldblyum T, Ferriera S, Friedman R, Halpern A, Khouri H, Kravitz SA, Lauro FM, Li K, Rogers YH, Strausberg R, Sutton G, Tallon L, Thomas T, Venter E, Frazier M, and Venter JC

Subjects

Biotechnology trends, Computational Biology methods, Contig Mapping, Biotechnology methods, Genes, Bacterial, Genome, Bacterial, Sequence Analysis, DNA methods

Abstract

Since its introduction a decade ago, whole-genome shotgun sequencing (WGS) has been the main approach for producing cost-effective and high-quality genome sequence data. Until now, the Sanger sequencing technology that has served as a platform for WGS has not been truly challenged by emerging technologies. The recent introduction of the pyrosequencing-based 454 sequencing platform (454 Life Sciences, Branford, CT) offers a very promising sequencing technology alternative for incorporation in WGS. In this study, we evaluated the utility and cost-effectiveness of a hybrid sequencing approach using 3730xl Sanger data and 454 data to generate higher-quality lower-cost assemblies of microbial genomes compared to current Sanger sequencing strategies alone.

Published

2006

99. Laterally transferred elements and high pressure adaptation in Photobacterium profundum strains.

Author

Campanaro S, Vezzi A, Vitulo N, Lauro FM, D'Angelo M, Simonato F, Cestaro A, Malacrida G, Bertoloni G, Valle G, and Bartlett DH

Subjects

Atmospheric Pressure, Codon, DNA Primers chemistry, Gene Expression Regulation, Genes, Bacterial, Genome, Image Processing, Computer-Assisted, Models, Biological, Oceans and Seas, Oligonucleotide Array Sequence Analysis, Open Reading Frames, Phylogeny, Pressure, RNA, Messenger metabolism, RNA, Ribosomal genetics, Seawater, Temperature, Transcription, Genetic, Gene Expression Regulation, Bacterial, Genome, Bacterial, Photobacterium genetics

Abstract

Background: Oceans cover approximately 70% of the Earth's surface with an average depth of 3800 m and a pressure of 38 MPa, thus a large part of the biosphere is occupied by high pressure environments. Piezophilic (pressure-loving) organisms are adapted to deep-sea life and grow optimally at pressures higher than 0.1 MPa. To better understand high pressure adaptation from a genomic point of view three different Photobacterium profundum strains were compared. Using the sequenced piezophile P. profundum strain SS9 as a reference, microarray technology was used to identify the genomic regions missing in two other strains: a pressure adapted strain (named DSJ4) and a pressure-sensitive strain (named 3TCK). Finally, the transcriptome of SS9 grown under different pressure (28 MPa; 45 MPa) and temperature (4 degrees C; 16 degrees C) conditions was analyzed taking into consideration the differentially expressed genes belonging to the flexible gene pool., Results: These studies indicated the presence of a large flexible gene pool in SS9 characterized by various horizontally acquired elements. This was verified by extensive analysis of GC content, codon usage and genomic signature of the SS9 genome. 171 open reading frames (ORFs) were found to be specifically absent or highly divergent in the piezosensitive strain, but present in the two piezophilic strains. Among these genes, six were found to also be up-regulated by high pressure., Conclusion: These data provide information on horizontal gene flow in the deep sea, provide additional details of P. profundum genome expression patterns and suggest genes which could perform critical functions for abyssal survival, including perhaps high pressure growth.

Published

2005

100. Conjugal vectors for cloning, expression, and insertional mutagenesis in gram-negative bacteria.

Author

Lauro FM, Eloe EA, Liverani N, Bertoloni G, and Bartlett DH

Subjects

Photobacterium genetics, Photobacterium metabolism, Recombinant Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Cloning, Molecular methods, Conjugation, Genetic genetics, Genetic Vectors genetics, Gram-Negative Bacteria genetics, Gram-Negative Bacteria metabolism, Mutagenesis, Insertional methods

Published

2005