DOCSLIB.ORG

University of Oklahoma Graduate College the Role Of

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

UNIVERSITY OF OKLAHOMA GRADUATE COLLEGE THE ROLE OF GAMMAPROTEOBACTERIA IN AEROBIC ALKANE DEGRADATION IN OILFIELD PRODUCTION WATER FROM THE BARNETT SHALE A THESIS SUBMITTED TO THE GRADUATE FACULTY in partial fulfillment of the requirements for the Degree of MASTER OF SCIENCE BY MEREDITH MICHELLE THORNTON Norman, Oklahoma 2017 THE ROLE OF GAMMAPROTEOBACTERIA IN AEROBIC ALKANE DEGRADATION IN OILFIELD PRODUCTION WATER FROM THE BARNETT SHALE A THESIS APPROVED FOR THE DEPARTMENT OF MICROBIOLOGY AND PLANT BIOLOGY BY ______________________________________ Dr. Joseph Suflita, Chair ______________________________________ Dr. Kathleen Duncan ______________________________________ Dr. Amy Callaghan © Copyright by MEREDITH MICHELLE THORNTON 2017 All Rights Reserved. I would like to dedicate this work to my family. To my loving parents, Tim and Donna, who have sacrificed so much for me and continue to provide for and support my wildest aspirations. To my sister, Mackenzie, who inspires me to set an example worthy of following. And to my future husband, Clifford Dillon DeGarmo, who motivates me to work harder, dream bigger, and pursue the best version of myself. Acknowledgements This work would not be possible without the guidance and unwavering support of my advisor, Dr. Kathleen Duncan. Throughout this process, she has been a role model for me in more than just the academic setting; she has inspired me through her kind nature, diligent work ethic, and optimistic outlook on life. She invested so much time and effort into shaping me into a scientist and I can never express how thankful and lucky I am to have been part of her legacy. I would also like to acknowledge Drs. Joseph Suflita and Amy Callaghan for their input in my thesis and time as a graduate student. Neither of them allowed me to settle for anything less than the best and I am grateful for the high standard to which they held me. Additionally, I would like to acknowledge Brian Harriman for his patience and help in teaching me many different laboratory methods. iv Table of Contents Acknowledgments.................................................................................................. iv Table of Contents.................................................................................................... v List of Tables.......................................................................................................... vii List of Figures......................................................................................................... ix Abstract................................................................................................................... xi Chapter 1: A review of selected topics in petroleum microbiology: biocorrosion, aerobic and anaerobic hydrocarbon degradation genetic systems, and aerobic hydrocarbonoclastic microorganisms Preface.................................................................................................................... 1 Abstract................................................................................................................... 5 Microbially influenced corrosion........................................................................... 6 Biocorrosion mitigation strategies.......................................................................... 12 Hydrocarbon degradation & petroleum biodegradation......................................... 13 Aerobic hydrocarbonoclastic microorganisms....................................................... 22 Chapter 2: The role of Gammaproteobacteria in aerobic alkane degradation in oilfield production water from the Barnett Shale Abstract................................................................................................................... 28 Introduction............................................................................................................ 29 Materials & Methods.............................................................................................. 36 Results.................................................................................................................... 52 Discussion............................................................................................................... 64 References.............................................................................................................. 80 Tables..................................................................................................................... 110 v Figures.................................................................................................................... 120 Appendix 1: Supplemental Tables and Figures for Chapter 2: The role of Gammaproteobacteria in aerobic alkane degradation in oilfield production water from the Barnett Shale Tables...................................................................................................................... 139 Figures.................................................................................................................... 144 Appendix 2: Isolation of the dominant cultivable aerobic heterotrophic bacteria from oil field production water produced from the Barnett Shale Abstract................................................................................................................... 153 Introduction............................................................................................................ 155 Materials & Methods.............................................................................................. 156 Results.................................................................................................................... 160 Discussion............................................................................................................... 162 Tables...................................................................................................................... 168 Figures.................................................................................................................... 171 vi List of Tables Chapter 2: The role of Gammaproteobacteria in aerobic alkane degradation in oilfield production water from the Barnett Shale Table 1 Hydrocarbon and heterotrophic substrates amendments used for production water enrichment.............................................................. 105 Table 2 Balanced stoichiometry for complete oxidation of various hydrocarbons...................................................................................... 106 Table 3 Environmental parameters of Barnett Shale production water................................................................................................... 107 Table 4 Organic extractions of Barnett Shale production water identifying putative polar metabolites, intermediates, and other compounds....... 108 Table 5 Summary of the dominant classes and corresponding genera of bacteria detected via 16S rRNA sequencing of original Barnett Shale production water....................................................................... 109 Table 6 Aerobic enrichment of Barnett Shale production water amended with hydrocarbon and heterotrophic substrates in Widdel’s medium 110 Table 7 Summary of 16S rRNA sequence libraries from the original Barnett Shale production water and after the third round of the initial and progressive enrichments amended with n-alkanes and n-fatty acid...... 111 Table 8 Evaluation of Halomonas A11A genome for genes involved in the aerobic degradation of alkanes and aromatics.................................... 112 Table 9 Range of hydrocarbons oxidized by Halomonas A11A..................... 113 Table 10 Comparison of oxygen consumed for n-pentane versus n-decane grown cells.......................................................................................... 114 Appendix 1: Supplemental Tables for Chapter 2: The role of Gammaproteobacteria in aerobic alkane degradation in oilfield production water from the Barnett Shale Table A1 Additional progressive aerobic enrichment amended with n- alkanes (C5-C10) and n-fatty acids (C5-C10) in Widdel’s medium.... 134 Table A2 Select metabolic pathways and genes of interest in the Halomonas A11A genome................................................................................... 136 Table A3 Molar calculations of hydrocarbon oxidation................................... 138 vii Appendix 2: Isolation of the dominant cultivable aerobic heterotrophic bacteria from oil field production water produced from the Barnett Shale Table A4 Chemical parameters of Barnett Shale production water collected in December 2014.......................................................................... 163 Table A5 Isolate identity based on partial 16S rRNA gene sequences.......... 164 Table A6 Hydrocarbon degradation screening by isolates obtained from Barnett Shale production water...................................................... 165 viii List of Figures Figure 1 Diagram of enrichment design..................................................... 115 Figure 2 16S sequence libraries representing the relative abundance (%) of different classes of bacteria in the initial and progressive rounds (“transfer”) of enrichment amended with n-alkanes (C5- C10) compared to the corresponding unamended transfer ........... 116 Figure 3 16S sequence libraries representing the relative abundance (%) of different classes of bacteria in the initial and progressive rounds (“transfer”) of enrichment amended with n-fatty
Recommended publications
  • The Hydrocarbon Biodegradation Potential of Faroe-Shetland Channel Bacterioplankton

    The Hydrocarbon Biodegradation Potential of Faroe-Shetland Channel Bacterioplankton

    THE HYDROCARBON BIODEGRADATION POTENTIAL OF FAROE-SHETLAND CHANNEL BACTERIOPLANKTON Angelina G. Angelova Submitted for the degree of Doctor of Philosophy Heriot Watt University School of Engineering and Physical Sciences July 2017 The copyright in this thesis is owned by the author. Any quotation from the thesis or use of any of the information contained in it must acknowledge this thesis as the source of the quotation or information. ABSTRACT The Faroe-Shetland Channel (FSC) is an important gateway for dynamic water exchange between the North Atlantic Ocean and the Nordic Seas. In recent years it has also become a frontier for deep-water oil exploration and petroleum production, which has raised the risk of oil pollution to local ecosystems and adjacent waterways. In order to better understand the factors that influence the biodegradation of spilled petroleum, a prerequisite has been recognized to elucidate the complex dynamics of microbial communities and their relationships to their ecosystem. This research project was a pioneering attempt to investigate the FSC’s microbial community composition, its response and potential to degrade crude oil hydrocarbons under the prevailing regional temperature conditions. Three strategies were used to investigate this. Firstly, high throughput sequencing and 16S rRNA gene-based community profiling techniques were utilized to explore the spatiotemporal patterns of the FSC bacterioplankton. Monitoring proceeded over a period of 2 years and interrogated the multiple water masses flowing through the region producing 2 contrasting water cores: Atlantic (surface) and Nordic (subsurface). Results revealed microbial profiles more distinguishable based on water cores (rather than individual water masses) and seasonal variability patterns within each core.
  • Genome-Resolved Meta-Analysis of the Microbiome in Oil Reservoirs Worldwide

    Genome-Resolved Meta-Analysis of the Microbiome in Oil Reservoirs Worldwide

    microorganisms Article Genome-Resolved Meta-Analysis of the Microbiome in Oil Reservoirs Worldwide Kelly J. Hidalgo 1,2,* , Isabel N. Sierra-Garcia 3 , German Zafra 4 and Valéria M. de Oliveira 1 1 Microbial Resources Division, Research Center for Chemistry, Biology and Agriculture (CPQBA), University of Campinas–UNICAMP, Av. Alexandre Cazellato 999, 13148-218 Paulínia, Brazil; [email protected] 2 Graduate Program in Genetics and Molecular Biology, Institute of Biology, University of Campinas (UNICAMP), Rua Monteiro Lobato 255, Cidade Universitária, 13083-862 Campinas, Brazil 3 Biology Department & CESAM, University of Aveiro, Aveiro, Portugal, Campus de Santiago, Avenida João Jacinto de Magalhães, 3810-193 Aveiro, Portugal; [email protected] 4 Grupo de Investigación en Bioquímica y Microbiología (GIBIM), Escuela de Microbiología, Universidad Industrial de Santander, Cra 27 calle 9, 680002 Bucaramanga, Colombia; [email protected] * Correspondence: [email protected]; Tel.: +55-19981721510 Abstract: Microorganisms inhabiting subsurface petroleum reservoirs are key players in biochemical transformations. The interactions of microbial communities in these environments are highly complex and still poorly understood. This work aimed to assess publicly available metagenomes from oil reservoirs and implement a robust pipeline of genome-resolved metagenomics to decipher metabolic and taxonomic profiles of petroleum reservoirs worldwide. Analysis of 301.2 Gb of metagenomic information derived from heavily flooded petroleum reservoirs in China and Alaska to non-flooded petroleum reservoirs in Brazil enabled us to reconstruct 148 metagenome-assembled genomes (MAGs) of high and medium quality. At the phylum level, 74% of MAGs belonged to bacteria and 26% to archaea. The profiles of these MAGs were related to the physicochemical parameters and recovery management applied.
  • Motiliproteus Sediminis Gen. Nov., Sp. Nov., Isolated from Coastal Sediment

    Motiliproteus Sediminis Gen. Nov., Sp. Nov., Isolated from Coastal Sediment

    Antonie van Leeuwenhoek (2014) 106:615–621 DOI 10.1007/s10482-014-0232-2 ORIGINAL PAPER Motiliproteus sediminis gen. nov., sp. nov., isolated from coastal sediment Zong-Jie Wang • Zhi-Hong Xie • Chao Wang • Zong-Jun Du • Guan-Jun Chen Received: 3 April 2014 / Accepted: 4 July 2014 / Published online: 20 July 2014 Ó Springer International Publishing Switzerland 2014 Abstract A novel Gram-stain-negative, rod-to- demonstrated that the novel isolate was 93.3 % similar spiral-shaped, oxidase- and catalase- positive and to the type strain of Neptunomonas antarctica, 93.2 % facultatively aerobic bacterium, designated HS6T, was to Neptunomonas japonicum and 93.1 % to Marino- isolated from marine sediment of Yellow Sea, China. bacterium rhizophilum, the closest cultivated rela- It can reduce nitrate to nitrite and grow well in marine tives. The polar lipid profile of the novel strain broth 2216 (MB, Hope Biol-Technology Co., Ltd) consisted of phosphatidylethanolamine, phosphatidyl- with an optimal temperature for growth of 30–33 °C glycerol and some other unknown lipids. Major (range 12–45 °C) and in the presence of 2–3 % (w/v) cellular fatty acids were summed feature 3 (C16:1 NaCl (range 0.5–7 %, w/v). The pH range for growth x7c/iso-C15:0 2-OH), C18:1 x7c and C16:0 and the main was pH 6.2–9.0, with an optimum at 6.5–7.0. Phylo- respiratory quinone was Q-8. The DNA G?C content genetic analysis based on 16S rRNA gene sequences of strain HS6T was 61.2 mol %. Based on the phylogenetic, physiological and biochemical charac- teristics, strain HS6T represents a novel genus and The GenBank accession number for the 16S rRNA gene T species and the name Motiliproteus sediminis gen.
  • Mangrove Bacterial Diversity and the Impact of Oil Contamination Revealed by Pyrosequencing: Bacterial Proxies for Oil Pollution

    Mangrove Bacterial Diversity and the Impact of Oil Contamination Revealed by Pyrosequencing: Bacterial Proxies for Oil Pollution

    Mangrove Bacterial Diversity and the Impact of Oil Contamination Revealed by Pyrosequencing: Bacterial Proxies for Oil Pollution Henrique Fragoso dos Santos1, Juliano Carvalho Cury1, Fla´via Lima do Carmo1, Adriana Lopes dos Santos1,2, James Tiedje2, Jan Dirk van Elsas3, Alexandre Soares Rosado1, Raquel Silva Peixoto1* 1 Laboratory of Molecular Microbial Ecology, Departamento of General Microbiology, Institute of Microbiology Paulo de Go´es, Federal University of Rio de Janeiro, Rio de Janeiro, Rio de Janeiro, Brazil, 2 Center for Microbial Ecology, Michigan State University, East Lansing, Michigan, United States of America, 3 Department of Microbial Ecology, University of Groningen, Groningen, The Netherlands Abstract Background: Mangroves are transitional coastal ecosystems in tropical and sub-tropical regions and represent biologically important and productive ecosystems. Despite their great ecological and economic importance, mangroves are often situated in areas of high anthropogenic influence, being exposed to pollutants, such as those released by oil spills. Methodology/Principal Findings: A microcosm experiment was conducted, which simulated an oil spill in previously pristine mangrove sediment. The effect of the oil spill on the extant microbial community was studied using direct pyrosequencing. Extensive bacterial diversity was observed in the pristine mangrove sediment, even after oil contamination. The number of different OTUs only detected in contaminated samples was significantly higher than the number of OTUs only detected in non-contaminated samples. The phylum Proteobacteria, in particular the classes Gammaproteobacteria and Deltaproteobacteria, were prevalent before and after the simulated oil spill. On the other hand, the order Chromatiales and the genus Haliea decreased upon exposure to 2 and 5% oil, these are proposed as sensitive indicators of oil contamination.
  • Molecular Identification and Physiological Characterization of Halophilic and Alkaliphilic Bacteria Belonging to the Genus Halomonas

    Molecular Identification and Physiological Characterization of Halophilic and Alkaliphilic Bacteria Belonging to the Genus Halomonas

    Molecular Identification and Physiological Characterization of Halophilic and Alkaliphilic Bacteria Belonging to the Genus Halomonas By Abdolkader Abosamaha Mohammed (BSc, Agricultural Sciences, Sebha University, Libya) (MSc, Environmental Engineering, University of Newcastle Upon Tyne, Uk) A Thesis Submitted for Degree of Doctor of Philosophy Department of Molecular Biology and Biotechnology The University of Sheffield 2013 Abstract Alkaline saline lakes are unusual extreme environments formed in closed drainage basins. Qabar - oun and Um - Alma lakes are alkaline saline lakes in the Libyan Sahara. There were only a few reports (Ajali et al., 1984) on their microbial diversity before the current work was undertaken. Five Gram-negative bacterial strains, belonging to the family of Halomonadaceae, were isolated from the lakes by subjecting the isolates to high salinity medium, and identified using 16S rRNA gene sequencing as Halomonas pacifica, Halomonas sp, Halomonas salifodinae, Halomonas elongata and Halomonas campisalis. Two of the Halomonas species isolated (H. pacifica and H. campisalis) were chosen for further study on the basis of novelty (H. pacifica) and on dual stress tolerance (high pH and high salinity) shown by H. campisalis. Both species showed optimum growth at 0.5 M NaCl, but H. campisalis alone was able to grow in the absence of NaCl. H. pacifica grew better than H. campisalis at high salinities in excess of 1 M NaCl and was clearly a moderately halophile. H. pacifica showed optimum growth at pH 7 to 8, but in contrast H. campisalis could grow well at pH values up to 10. 13C - NMR spectroscopy was used to determine and identify the compatible solutes accumulated by H.
  • Tratamiento Biológico Aerobio Para Aguas Residuales Con Elevada Conductividad Y Concentración De Fenoles

    Tratamiento Biológico Aerobio Para Aguas Residuales Con Elevada Conductividad Y Concentración De Fenoles

    PROGRAMA DE DOCTORADO EN INGENIERÍA Y PRODUCCIÓN INDUSTRIAL Tratamiento biológico aerobio para aguas residuales con elevada conductividad y concentración de fenoles TESIS DOCTORAL Presentada por: Eva Ferrer Polonio Dirigida por: Dr. José Antonio Mendoza Roca Dra. Alicia Iborra Clar Valencia Mayo 2017 AGRADECIMIENTOS La sabiduría popular, a la cual recurro muchas veces, dice: “Es de bien nacido ser agradecido”… pues sigamos su consejo, aquí van los míos. En primer lugar quiero agradecer a mis directores la confianza depositada en mí y a Depuración de Aguas del Mediterráneo, especialmente a Laura Pastor y Silvia Doñate, la dedicación e ilusión puestas en el proyecto. Durante el desarrollo de esta Tesis Doctoral he tenido la inmensa suerte de contar con un grupo de personas de las que he aprendido muchísimo y que de forma desinteresada han colaborado en este trabajo, enriqueciéndolo enormemente. Gracias al Dr. Jaime Primo Millo, del Instituto Agroforestal Mediterráneo de la Universitat Politècnica de València, por el asesoramiento recibido y por permitirme utilizar los equipos de cromatografía de sus instalaciones. También quiero dar un agradecimiento especial a una de las personas de su equipo de investigación, ya que sin su ayuda, tiempo y enseñanzas en los primeros análisis realizados con esta técnica, no me hubiera sido posible llevar a cabo esta tarea con tanta facilidad…gracias Dra. Nuria Cabedo Escrig. Otra de las personas con las que he tenido la suerte de colaborar ha sido la Dra. Blanca Pérez Úz, del Departamento de Microbiología III de la Facultad de Ciencias Biológicas de la Universidad Complutense de Madrid. Blanca, aunque no nos conocemos personalmente, tu profesionalidad y dedicación han permitido superar las barreras de la distancia…gracias.
  • (12) United States Patent (10) Patent No.: US 9,334,531 B2 Li Et Al

    (12) United States Patent (10) Patent No.: US 9,334,531 B2 Li Et Al

    USOO933.4531B2 (12) United States Patent (10) Patent No.: US 9,334,531 B2 Li et al. (45) Date of Patent: *May 10, 2016 (54) NUCLECACIDAMPLIFICATION (56) References Cited U.S. PATENT DOCUMENTS (71) Applicant: LIFE TECHNOLOGIES 5,223,414 A 6/1993 Zarling et al. CORPORATION, Carlsbad, CA (US) 5,616,478 A 4/1997 Chetverin et al. 5,670,325 A 9/1997 Lapidus et al. (72) Inventors: Chieh-Yuan Li, El Cerrito, CA (US); 5,928,870 A 7/1999 Lapidus et al. David Ruff, San Francisco, CA (US); 5,958,698 A 9, 1999 Chetverinet al. Shiaw-Min Chen, Fremont, CA (US); 6,001,568 A 12/1999 Chetverinet al. 6,033,881 A 3/2000 Himmler et al. Jennifer O'Neil, Wakefield, MA (US); 6,074,853. A 6/2000 Pati et al. Rachel Kasinskas, Amesbury, MA (US); 6,306,590 B1 10/2001 Mehta et al. Jonathan Rothberg, Guilford, CT (US); 6.432,360 B1 8, 2002 Church Bin Li, Palo Alto, CA (US); Kai Qin 6,440,706 B1 8/2002 Vogelstein et al. Lao, Pleasanton, CA (US) 6,511,803 B1 1/2003 Church et al. 6,929,915 B2 8, 2005 Benkovic et al. (73) Assignee: Life Technologies Corporation, 7,270,981 B2 9, 2007 Armes et al. 7,282,337 B1 10/2007 Harris Carlsbad, CA (US) 7,399,590 B2 7/2008 Piepenburg et al. 7.432,055 B2 * 10/2008 Pemov et al. ................ 435/6.11 (*) Notice: Subject to any disclaimer, the term of this 7,435,561 B2 10/2008 Piepenburg et al.
  • Complete Thesis

    Complete Thesis

    University of Groningen Omega transaminases: discovery, characterization and engineering Palacio, Cyntia Marcela IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite from it. Please check the document version below. Document Version Publisher's PDF, also known as Version of record Publication date: 2019 Link to publication in University of Groningen/UMCG research database Citation for published version (APA): Palacio, C. M. (2019). Omega transaminases: discovery, characterization and engineering. Rijksuniversiteit Groningen. Copyright Other than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons). The publication may also be distributed here under the terms of Article 25fa of the Dutch Copyright Act, indicated by the “Taverne” license. More information can be found on the University of Groningen website: https://www.rug.nl/library/open-access/self-archiving-pure/taverne- amendment. Take-down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Downloaded from the University of Groningen/UMCG research database (Pure): http://www.rug.nl/research/portal. For technical reasons the number of authors shown on this cover page is limited to 10 maximum. Download date: 01-10-2021 Omega transaminases: discovery, characterization and engineering Cyntia Marcela Palacio 2019 Cover design by Cyntia Palacio and Joris Goudsmits, adapted from a decorative mosaic artwork on the railway underpass on Moesstraat, Groningen.
  • Ecological Drivers of Bacterial Community Assembly in Synthetic Phycospheres

    Ecological Drivers of Bacterial Community Assembly in Synthetic Phycospheres

    Ecological drivers of bacterial community assembly in synthetic phycospheres He Fua, Mario Uchimiyaa,b, Jeff Gorec, and Mary Ann Morana,1 aDepartment of Marine Sciences, University of Georgia, Athens, GA 30602; bComplex Carbohydrate Research Center, University of Georgia, Athens, GA 30602; and cDepartment of Physics, Massachusetts Institute of Technology, Cambridge, MA 02139 Edited by Edward F. DeLong, University of Hawaii at Manoa, Honolulu, HI, and approved January 6, 2020 (received for review October 3, 2019) In the nutrient-rich region surrounding marine phytoplankton The ecological mechanisms that influence the assembly of cells, heterotrophic bacterioplankton transform a major fraction of phycosphere microbiomes are not well understood, however, in recently fixed carbon through the uptake and catabolism of part because of the micrometer scale at which bacterial commu- phytoplankton metabolites. We sought to understand the rules by nities congregate. It remains unclear whether simple rules exist which marine bacterial communities assemble in these nutrient- that could predict the composition of these communities. enhanced phycospheres, specifically addressing the role of host Phycospheres are short-lived in the ocean, constrained by the resources in driving community coalescence. Synthetic systems with 1- to 2-d average life span of phytoplankton cells (20, 21). The varying combinations of known exometabolites of marine phyto- phycosphere bacterial communities must therefore form and dis- plankton were inoculated with seawater bacterial assemblages, and perse rapidly within a highly dynamic metabolite landscape (14). communities were transferred daily to mimic the average duration We hypothesized a simple rule for assembly in metabolically di- of natural phycospheres. We found that bacterial community verse phycospheres in which communities congregate as the sum assembly was predictable from linear combinations of the taxa of discrete metabolite guilds (22).
  • Comparative Analysis of the Core Proteomes Among The

    Comparative Analysis of the Core Proteomes Among The

    Diversity 2020, 12, 289 1 of 25 Article Comparative Analysis of the Core Proteomes among the Pseudomonas Major Evolutionary Groups Reveals Species‐Specific Adaptations for Pseudomonas aeruginosa and Pseudomonas chlororaphis Marios Nikolaidis 1, Dimitris Mossialos 2, Stephen G. Oliver 3 and Grigorios D. Amoutzias 1,* 1 Bioinformatics Laboratory, Department of Biochemistry and Biotechnology, University of Thessaly, 41500 Larissa, Greece; [email protected] 2 Microbial Biotechnology‐Molecular Bacteriology‐Virology Laboratory, Department of Biochemistry and Biotechnology, University of Thessaly, 41500 Larissa, Greece; [email protected] 3 Cambridge Systems Biology Centre & Department of Biochemistry, University of Cambridge, Cambridge CB2 1GA, UK; [email protected] * Correspondence: [email protected]; Tel.: +30‐2410‐565289; Fax: +30‐2410‐565290 Received: 22 June 2020; Accepted: 22 July 2020; Published: 24 July 2020 Abstract: The Pseudomonas genus includes many species living in diverse environments and hosts. It is important to understand which are the major evolutionary groups and what are the genomic/proteomic components they have in common or are unique. Towards this goal, we analyzed 494 complete Pseudomonas proteomes and identified 297 core‐orthologues. The subsequent phylogenomic analysis revealed two well‐defined species (Pseudomonas aeruginosa and Pseudomonas chlororaphis) and four wider phylogenetic groups (Pseudomonas fluorescens, Pseudomonas stutzeri, Pseudomonas syringae, Pseudomonas putida) with a sufficient number of proteomes. As expected, the genus‐level core proteome was highly enriched for proteins involved in metabolism, translation, and transcription. In addition, between 39–70% of the core proteins in each group had a significant presence in each of all the other groups. Group‐specific core proteins were also identified, with P.
  • Halomonas Maura Sp. Nov., a Novel Moderately Halophilic, Exopolysaccharide-Producing Bacterium

    Halomonas Maura Sp. Nov., a Novel Moderately Halophilic, Exopolysaccharide-Producing Bacterium

    International Journal of Systematic and Evolutionary Microbiology (2001), 51, 1625–1632 Printed in Great Britain Halomonas maura sp. nov., a novel moderately halophilic, exopolysaccharide-producing bacterium Microbial Samir Bouchotroch, Emilia Quesada, Ana del Moral, Inmaculada Llamas Exopolysaccharides Research Group, Department of and Victoria Be! jar Microbiology, Faculty of Pharmacy, Campus Universitario de Cartuja, Author for correspondence: Emilia Quesada. Tel: j34 958 243871. Fax: j34 958 246235. University of Granada, e-mail: equesada!platon.ugr.es 18071 Granada, Spain Four moderately halophilic, exopolysaccharide-producing bacterial strains isolated from soil samples collected from a saltern at Asilah (Morocco) are reported. These four strains were initially considered to belong to the genus Halomonas. Their DNA GMC contents varied between 622 and 641 mol%. DNA–DNA hybridization revealed a considerable degree of DNA–DNA similarity amongst all four strains (755–808%). Nevertheless, similarity with the reference strains of phylogenetically close relatives was lower than 40%. 16S rRNA gene sequences were compared with those of other species of Halomonas and other Gram-negative bacteria and they were sufficiently distinct phylogenetically from other recognized Halomonas species to warrant their designation as a novel species. The name Halomonas maura sp. nov. is therefore proposed, with strain S-31T (l CECT 5298T l DSM 13445T) as the type strain. The fatty acid composition of strain S-31T revealed the presence of 18:1ω7c,16:1ω7c/2-OH i15:0 and 16:0 as the major components. Growth rate analysis showed that strain S-31T had specific cationic requirements for NaM and Mg2M. Keywords: exopolysaccharides, moderately halophilic bacteria, Halomonas INTRODUCTION In the course of our studies into hypersaline environ- ments, a group of Halomonas eurihalina strains were The family Halomonadaceae includes the genera isolated that synthesized large quantities of exopoly- Halomonas, Chromohalobacter and Zymobacter.
  • An Astrobiological Study of an Alkaline-Saline Hydrothermal Environment, Relevant to Understanding the Habitability of Mars

    An Astrobiological Study of an Alkaline-Saline Hydrothermal Environment, Relevant to Understanding the Habitability of Mars

    An astrobiological study of an alkaline-saline hydrothermal environment, relevant to understanding the habitability of Mars A thesis submitted for the Degree of Doctor of Philosophy By Lottie Elizabeth Davis Department of Earth Sciences University College London March 2012 1 I, Lottie Elizabeth Davis confirm that the work presented in this thesis is my own. Where information has been derived from other sources, I confirm that this has been indicated in the thesis. 2 Declaration Abstract The on going exploration of planets such as Mars is producing a wealth of data which is being used to shape a better understanding of potentially habitable environments beyond the Earth. On Mars, the relatively recent identification of minerals which indicate the presence of neutral/alkaline aqueous activity has increased the number of potentially habitable environments which require characterisation and exploration. The study of terrestrial analogue environments enables us to develop a better understanding of where life can exist, what types of organisms can exist and what evidence of that life may be preserved. The study of analogue environments is necessary not only in relation to the possibility of identifying extinct/extant indigenous life on Mars, but also for understanding the potential for contamination. As well as gaining an insight into the habitability of an environment, it is also essential to understand how to identify such environments using the instruments available to missions to Mars. It is important to be aware of instrument limitations to ensure that evidence of a particular environment is not overlooked. This work focuses upon studying the bacterial and archaeal diversity of Lake Magadi, a hypersaline and alkaline soda lake, and its associated hydrothermal springs.