DOCSLIB.ORG

Developing Methodologies for the Investigation of Free-Living Amoeba As a Tool for Pathogen Surveillance on Dairy Farms and Aquaculture

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Developing Methodologies for the Investigation of Free-Living Amoeba As a Tool for Pathogen Surveillance on Dairy Farms and Aquaculture Developing Methodologies for the Investigation of Free-living Amoeba as a Tool for Pathogen Surveillance on Dairy Farms and Aquaculture by John McLean A Thesis presented to The University of Guelph In partial fulfillment of requirements for the degree of Master of Science in Molecular and Cellular Biology Guelph, Ontario, Canada © John McLean, April, 2014 ABSTRACT DEVELOPING METHODOLOGIES FOR THE INVESTIGATION OF FREE-LIVING AMOEBA AS A TOOL FOR PATHOGEN SURVEILLANCE ON DAIRY FARMS AND FISHERIES John M. McLean Advisor: University of Guelph, 2014 Dr. Lucy Mutharia Free-living amoeba are phagocytic protozoans that act as environmental reservoirs, a protective niche, and a vehicle for transmission for amoeba-resistant bacterial pathogens. Many amoeba-resistant bacteria have been identified using only laboratory-adapted Acanthamoeba. We isolated resident amoeba from target environments of dairy farms and aquaculture settings to evaluate their use as a pathogen detection tool. Amoeba were only isolated from 3 of 23 (13%) environmental samples using established methods. A two-step sample decontamination protocol was developed and led to the isolation of 14 additional amoeba. An amoeba co-culture method was developed to assess the survival of 12 mycobacterial species within environmental and laboratory-adapted amoeba. Major strain differences were observed at the amoeba level which had drastic effects on the survival of different bacterial species within individual amoeba. Targeted isolation of resident bacteria from soils and feces using amoebal enrichment protocols were unsuccessful. However, the methodologies developed in this study provide a valid technical starting point for future studies. Acknowledgments First and foremost I would like to thank my advisor, Dr. Lucy Mutharia for her guidance and continued support throughout the course of this work. I am ever grateful for her willingness to provide direction and assistance at both the undergraduate and graduate level. I would also like to thank my committee members, Dr. R.M.W. Stevenson and Dr. Cezar Khursigara for their assistance and expertise during the course of my project, it would not have been possible without you. Many thanks must also be given to the members of the Mutharia and Stevenson labs, especially Tony Facciuolo and Melinda Raymond for being an ever present source of advice and direction. I must also thank Steve Lord and members of the lab of Dr. Dave Kelton for obtaining many of the environmental samples that made this work possible. Recognition must also go to my office mates Daniel Jeffery, Kate Murphy, Alison Berezuk and Michelle Daigneault as a constant source of both entertainment and advice. Finally I'd like to thank my family for their unwavering support throughout this process. iii Table of Contents List of Figures………………………………………………………………………………......vii List of Tables………………………………………………………………………………….....ix Chapter 1.0: Introduction….........……….....……………………………………………….......1 1.1 Free-living amoeba……………………………………………………………………........2 1.2 Cyst Resistance………………………………………………………………………........10 1.3 Amoeba-resistant Microbes………………………………………………………….........11 1.3.1 Pathogen Persistence…………………………………………………………….....17 1.3.2 Amoeba as a Bacterial Training Ground for Intracellular Pathogens.......................19 1.3.3 A Protective Environment.........................................................................................21 1.3.4 Pathogen Transmission.............................................................................................23 1.4 Research Rationale and Objectives......................................................................................25 Chapter 2.0: Materials and Methods.........................................................................................28 2.1. Bacterial Strains and Growth Conditions...........................................................................28 2.1.1 Preparation of NNA-E. coli Media...........................................................................30 2.1.2 Culture of Amoeba....................................................................................................30 2.1.3 Long-term Storage of Amoeba.................................................................................31 2.2 Development of Methodologies for Amoeba Isolation.......................................................32 2.2.1 Determining Cyst Resistance....................................................................................32 2.2.2 Primary Amoeba Isolation from Dairy Farms and Aquaculture...............................33 2.2.3 Methods Developed for Amoeba Isolation from Dairy Farms and Aquaculture.....34 2.2.4 Conversion of Xenically Culturable Amoeba to Axenically Culturable Forms.......36 2.3 Amoebal Enrichment and Co-culture..................................................................................37 iv 2.3.1 Preparation of Amoebal Microplates........................................................................37 2.3.2 Screening of Amoeba-resistant Bacteria by the Co-culture Protocol.......................38 2.3.3 Isolation of Environmental Amoeba-resistant Bacteria............................................39 2.3.4 MAP isolation from Cow Feces................................................................................40 2.3.5 MAP Isolation from Cow Feces by Amoebal Enrichment......................................41 2.4 DNA methods......................................................................................................................42 2.4.1 PCR conditions.........................................................................................................44 2.5 Microscopy..........................................................................................................................45 2.5.1 Staining of Amoeba Trophozoites and Amoeba-resistant Bacteria..........................45 2.5.2 Transmission Electron Microscopy..........................................................................46 Chapter 3.0: Results.....................................................................................................................48 3.1 Developing Methodologies for the Isolation of Free-living Amoeba from Environmental Samples.......................................................................................................48 3.2 Molecular Identification of Free-living Amoeba.................................................................54 3.2.1 Diversity of Free-living Amoeba..............................................................................63 3.3 Axenic Culture of Free-living Amoeba...............................................................................67 3.4 Developing Methodologies for Identification of Amoeba-resistant Bacteria......................70 3.4.1 Identifying Amoeba-resistant Bacteria Resident in Free-living Amoeba.................75 3.4.2 Enriching for MAP from Feces................................................................................78 3.4.3 Persistence of MAP within Amoebal Cysts..............................................................82 Chapter 4.0: Discussion...............................................................................................................86 v 4.1 Conclusions..........................................................................................................................96 4.2 Future Direction....................................................................................................................97 5.0 REFERENCES.......................................................................................................................98 6.0 APPENDICES......................................................................................................................108 6.1 Appendix 1: Media and Buffers..........................................................................................109 6.2 Appendix 2: 18S rRNA Sequences....................................................................................114 vi List of Figures Figure 1.1 Locomotive form of an amoebal trophozoite................................................................3 Figure 1.2 Overview of phagocytosis of bacteria by free-living amoeba.......................................6 Figure 1.3 Cross-section of an Aca. polyphaga cyst showing cyst-wall structure..........................9 Figure 1.4 Mechanisms used by amoeba-resistant bacteria to resist phagocytic killing..............14 Figure 3.1 NNA-E. coli plate during primary amoeba isolation showing fungal overgrowth..........................................................................................................................50 Figure 3.2 Amoebal walk-out.......................................................................................................51 Figure 3.3 Schematic overview of the developed methods for primary amoeba isolation..........................................................................................................................................56 Figure 3.4 Morphology of different environmental amoeba isolated...........................................58 Figure 3.5 Representation of the amoebal 18S rRNA gene showing variable regions.................59 Figure 3.6 Agarose gel of amplified amoebal DNA using the JDP1/JDP2 primer set.................60 Figure 3.7 Agarose gel of amplified amoebal DNA using the P-FLA primer set........................61 Figure 3.8 Agarose gel of products
Load more

Recommended publications
  • Reverse Blot Hybridization Assay
    Detection of Waterborne Pathogens by Polymerase Chain Reaction- Reverse Blot Hybridization Assay Yeonim Choi The Graduate School Yonsei University Department of Biomedical Laboratory Science Detection of Waterborne Pathogens by Polymerase Chain Reaction- Reverse Blot Hybridization Assay A Dissertation Submitted to the Department of Biomedical Laboratory Science and the Graduate School of Yonsei University in partial fulfillment of the requirements for the degree of Doctor of Philosophy Yeonim Choi July 2011 G This certifies that the dissertation of Yeonim Choi is approved. ๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤ Thesis Supervisor : Hyeyoung Lee ๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤ Ok Doo Awh : Thesis Committee Member ๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤ Tae Ue Kim : Thesis Committee Member ๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤ Jong Bae Kim : Thesis Committee Member ๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤๤ Yong Serk Park : Thesis Committee Member The Graduate School Yonsei University July 2011 G G Dedicated to my family and my friends, who have encouraged me. G G CONTENTS LIST OF FIGURES AND TABLES ------------------------------------------------ iv ABBREVIATIONS ------------------------------------------------------------------- ix ABSTRACT IN ENGLISH ----------------------------------------------------------- x I. INTRODUCTION ------------------------------------------------------------- 1 II. MATERIALS AND METHODS -------------------------------------------- 9 1. Development of PCR-REBA targeting waterborne pathogens -------- 9 Bacterial reference strains and cultivation ------------------------------- 9 Genomic DNA extraction
    [Show full text]
  • Pocket Guide to Clinical Microbiology
    4TH EDITION Pocket Guide to Clinical Microbiology Christopher D. Doern 4TH EDITION POCKET GUIDE TO Clinical Microbiology 4TH EDITION POCKET GUIDE TO Clinical Microbiology Christopher D. Doern, PhD, D(ABMM) Assistant Professor, Pathology Director of Clinical Microbiology Virginia Commonwealth University Health System Medical College of Virginia Campus Washington, DC Copyright © 2018 Amer i can Society for Microbiology. All rights re served. No part of this publi ca tion may be re pro duced or trans mit ted in whole or in part or re used in any form or by any means, elec tronic or me chan i cal, in clud ing pho to copy ing and re cord ing, or by any in for ma tion stor age and re trieval sys tem, with out per mis sion in writ ing from the pub lish er. Disclaimer: To the best of the pub lish er’s knowl edge, this pub li ca tion pro­ vi des in for ma tion con cern ing the sub ject mat ter cov ered that is ac cu rate as of the date of pub li ca tion. The pub lisher is not pro vid ing le gal, med i cal, or other pro fes sional ser vices. Any ref er ence herein to any spe cific com mer cial prod ucts, pro ce dures, or ser vices by trade name, trade mark, man u fac turer, or oth er wise does not con sti tute or im ply en dorse ment, rec om men da tion, or fa vored sta tus by the Ameri can Society for Microbiology (ASM).
    [Show full text]
  • Detection, Survival and Infectious Potential of Mycobacterium Tuberculosis in the Environment: a Review of the Evidence and Epidemiological Implications
    REVIEW TUBERCULOSIS Detection, survival and infectious potential of Mycobacterium tuberculosis in the environment: a review of the evidence and epidemiological implications Leonardo Martinez1, Renu Verma1, Julio Croda2,3, C. Robert Horsburgh Jr4,5, Katharine S. Walter1, Nicholas Degner1, Keren Middelkoop6,7, Anastasia Koch8, Sabine Hermans6,9, Digby F. Warner 8,10, Robin Wood6, Frank Cobelens9 and Jason R. Andrews1 Affiliations: 1Division of Infectious Diseases and Geographic Medicine, School of Medicine, Stanford University, Stanford, CA, USA. 2Oswaldo Cruz Foundation, Campo Grande and Salvador, Brazil. 3School of Medicine, Federal University of Mato Grosso do Sul, Campo Grande, Brazil. 4Dept of Medicine, Boston University School of Medicine, Boston, MA, USA. 5Dept of Epidemiology, Biostatistics and Global Health, Boston University School of Public Health, Boston, MA, USA. 6The Desmond Tutu HIV Centre, Institute for Infectious Disease and Molecular Medicine, Faculty of Health Sciences, University of Cape Town, Cape Town, South Africa. 7Dept of Medicine, University of Cape Town, Cape Town, South Africa. 8SAMRC/NHLS/UCT Molecular Mycobacteriology Research Unit, Dept of Pathology and Institute of Infectious Diseases and Molecular Medicine, Faculty of Health Sciences, University of Cape Town, Cape Town, South Africa. 9Dept of Global Health, Amsterdam Institute for Global Health and Development, Academic Medical Center, Amsterdam, The Netherlands. 10Wellcome Center for Infectious Diseases Research in Africa, Institute of Infectious Diseases
    [Show full text]
  • Antimicrobial Resistance EMERGING INFECTIOUS DISEASES Pages 681-814 Peer-Reviewed Journal Tracking and Analyzing Disease Trends Pages 681–814
    Vol 13, No 5, May 2007 Vol ® May 2007 Antimicrobial Resistance EMERGING INFECTIOUS DISEASES Pages 681-814 Pages Peer-Reviewed Journal Tracking and Analyzing Disease Trends pages 681–814 EDITOR-IN-CHIEF D. Peter Drotman EDITORIAL STAFF EDITORIAL BOARD Managing Senior Editor Dennis Alexander, Addlestone Surrey, United Kingdom Polyxeni Potter, Atlanta, Georgia, USA Barry J. Beaty, Ft. Collins, Colorado, USA Associate Editors Martin J. Blaser, New York, New York, USA Paul Arguin, Atlanta, Georgia, USA David Brandling-Bennet, Washington, D.C., USA Charles Ben Beard, Ft. Collins, Colorado, USA Donald S. Burke, Baltimore, Maryland, USA David Bell, Atlanta, Georgia, USA Arturo Casadevall, New York, New York, USA Jay C. Butler, Anchorage, Alaska, USA Kenneth C. Castro, Atlanta, Georgia, USA Charles H. Calisher, Ft. Collins, Colorado, USA Thomas Cleary, Houston, Texas, USA Stephanie James, Bethesda, Maryland, USA Anne DeGroot, Providence, Rhode Island, USA Brian W.J. Mahy, Atlanta, Georgia, USA Vincent Deubel, Shanghai, China Paul V. Effler, Honolulu, Hawaii, USA Nina Marano, Atlanta, Georgia, USA Ed Eitzen, Washington, D.C., USA Martin I. Meltzer, Atlanta, Georgia, USA Duane J. Gubler, Honolulu, Hawaii, USA David Morens, Bethesda, Maryland, USA Richard L. Guerrant, Charlottesville, Virginia, USA J. Glenn Morris, Baltimore, Maryland, USA Scott Halstead, Arlington, Virginia, USA Marguerite Pappaioanou, St. Paul, Minnesota, USA David L. Heymann, Geneva, Switzerland Tanja Popovic, Atlanta, Georgia, USA Daniel B. Jernigan, Atlanta, Georgia, USA Patricia M. Quinlisk, Des Moines, Iowa, USA Charles King, Cleveland, Ohio, USA Jocelyn A. Rankin, Atlanta, Georgia, USA Keith Klugman, Atlanta, Georgia, USA Didier Raoult, Marseilles, France Takeshi Kurata, Tokyo, Japan Pierre Rollin, Atlanta, Georgia, USA S.K.
    [Show full text]
  • APPENDIX a Media and Reagents
    APPENDIX A Media and Reagents Pauline K. w. Yu, M.S. The use of appropriate and dependable media is integral to the isolation and identification of microorganisms. Unfortunately, comparative data docu­ menting the relative efficacy or value of media designed for similar purposes are often lacking. Moreover, one cannot presume identity in composition of a given generic product which is manufactured by several companies because each may supplement the generic products with components, often of a proprietary nature and not specified in the product's labeling. Finally, the actual production of similar products may vary among manufacturers to a sufficient extent to affect their performance. For all of these reasons, therefore, product selection for the laboratory should not be strictly based on cost considerations and should certainly not be based on promotional materials. Evaluations that have been published in the scientific literature should be consulted when available. Alternatively, the prospective buyer should consult a recognized authority in the field. It is seldom necessary for the laboratory to prepare media using basic components since these are usually available combined in dehydrated form from commercial sources; however, knowledge of a medium's basic compo­ nents is helpful in understanding how the medium works and what might be wrong when it does not work. Hence, the components have been listed for each medium included in this chapter. All dehydrated media must be prepared exactly according to the manu­ facturers' directions. Any deviation from these directions may adversely affect or significantly alter a medium's performance. Containers of media should be dated on receipt and when opened, and the media should never be used beyond expiration dates specified by the manufacturers or recom­ mended by quality control programs.
    [Show full text]
  • Mycobacteria in Northern Tanzania: Exposure and Risk of Disease Among Agropastoralists and Programmatic Challenges in Investigation of Re-Treatment Cases
    0\FREDFWHULDLQQRUWKHUQ7DQ]DQLD ([SRVXUHDQGULVNRIGLVHDVHDPRQJDJURSDVWRUDOLVWVDQG SURJUDPPDWLFFKDOOHQJHVLQLQYHVWLJDWLRQRIUHWUHDWPHQWFDVHV $QGUHZ0DUWLQ.LODOH Dissertation for the degree of philosophiae doctor (PhD) at the University of Bergen Dissertation date: © Copyright: Andrew Martin Kilale, 2015 The material in this publication is protected by copyright law Title: Mycobacteria in northern Tanzania: Exposure and risk of disease among agropastoralists and programmatic challenges in investigation of re-treatment cases Author: Andrew Martin Kilale Print: AiT Bjerch AS / University of Bergen ii Dedication To the memory of my beloved Father, the late Martin Meza and my Mother, Twingilage Mwandawila Sanga iii Acknowledgements I thank His Almighty God for blessing me with this opportunity and keeping me strong throughout the period of my studies. My heartfelt acknowledgement goes to the University of Bergen, Centre for International Health for providing me the opportunity for this training. I wish to express my deepest sincere gratitude to my supervisors Prof. Sven Gudmund Hinderaker and Dr. Bernard James Ngowi for their tireless efforts, encouragement, support and always being available for the guidance. My special thanks goes to Dr. Godfrey Sayoki Mfinanga the Director at Muhimbili Medical Research Centre and Afrique One Consortium Deputy Director whose love and dedication to health research appointed me to join the consortium as a PhD student. My compliment goes to my family, my wife Elina, my son Audphas, and my daughters Irene and Doris for their intimate love, endless support, encouragement, prayers and endurance during my absence have been essential. I would like to express my earnest thanks to my employer, the National Institute for Medical Research and Welcome Trust through Afrique One Consortium for their financial support for research and my studies.
    [Show full text]
  • Computational Identification of the Proteins Associated with Quorum
    fmicb-10-03011 January 22, 2020 Time: 12:51 # 1 ORIGINAL RESEARCH published: 22 January 2020 doi: 10.3389/fmicb.2019.03011 Computational Identification of the Proteins Associated With Quorum Sensing and Biofilm Formation in Mycobacterium tuberculosis Shubhada R. Hegde* Institute of Bioinformatics and Applied Biotechnology, Bengaluru, India With prolonged therapy and increased instances of drug resistance, tuberculosis is viewed as a serious infectious disease causing high mortality. Emerging concepts in Mycobacterium tuberculosis pathogenicity include biofilm formation, which endows bacterial survival in the host for a long time. To tackle chronic tuberculosis infection, a detailed understanding of the bacterial survival mechanisms is crucial. Using comparative genomics and literature mining, 115 M. tuberculosis proteins were shortlisted for their likely association with biofilm formation or quorum sensing. These include essential genes such as secA2, lpqY-sugABC, Rv1176c, and Rv0195, many of which are also known virulence factors. Furthermore, the functional relationship among these proteins was established by considering known protein-protein interactions, Edited by: regulatory interactions, and gene expression correlation data/information. Graph Rachel Susan Poretsky, centrality and motif analyses predicted the importance of proteins, such as Rv0081, University of Illinois at Chicago, United States DevR, RegX3, Rv0097, and Rv1996 in M. tuberculosis biofilm formation. Analysis Reviewed by: of conservation across other biofilm-forming bacteria suggests that most of these Seyed Ehtesham Hasnain, genes are conserved in mycobacteria. As the processes, such as quorum sensing, Jamia Hamdard University, India Nasreen Zafar Ehtesham, leading to biofilm formation involve diverse pathways and interactions between National Institute of Pathology, India proteins, these system-wide studies provide a novel perspective toward understanding *Correspondence: mycobacterial persistence.
    [Show full text]
  • BD Industry Catalog
    PRODUCT CATALOG INDUSTRIAL MICROBIOLOGY BD Diagnostics Diagnostic Systems Table of Contents Table of Contents 1. Dehydrated Culture Media and Ingredients 5. Stains & Reagents 1.1 Dehydrated Culture Media and Ingredients .................................................................3 5.1 Gram Stains (Kits) ......................................................................................................75 1.1.1 Dehydrated Culture Media ......................................................................................... 3 5.2 Stains and Indicators ..................................................................................................75 5 1.1.2 Additives ...................................................................................................................31 5.3. Reagents and Enzymes ..............................................................................................75 1.2 Media and Ingredients ...............................................................................................34 1 6. Identification and Quality Control Products 1.2.1 Enrichments and Enzymes .........................................................................................34 6.1 BBL™ Crystal™ Identification Systems ..........................................................................79 1.2.2 Meat Peptones and Media ........................................................................................35 6.2 BBL™ Dryslide™ ..........................................................................................................80
    [Show full text]
  • Glossery of Tb Terms Acid-Fast Bacilli- (Afb)
    GLOSSERY OF TB TERMS ACID-FAST BACILLI - (AFB) Bacteria which retain certain dyes even when washed with an acid solution. Only rarely are acid-fast bacteria which are seen on smear not mycobacteria. A presumptive diagnosis of tuberculosis is often made on the basis of a positive “AFB smear;” however, the diagnosis is not confirmed until a culture is grown and identified as M. tuberculosis . ACQUIRED DRUG RESISTANCE - Resistance to one or more antituberculous drugs which develops while a patient is on therapy, usually the result of erratic compliance on the part of the patient. ADVERSE REACTIONS - Any undesirable effect of a medication. All drugs may cause such reactions, so that periodic monitoring of tuberculous patients under treatment is necessary to detect any that do occur, even though their occurrence may be common. ALVEOLI - The small air sacs in the lungs which lie at the end of the bronchial tree. The site of gas exchange in the lungs, and the site where tuberculous infection usually begins. ANEMIA - A condition in which there is a decreased volume of red cells in the blood. There are many causes for anemia, including chronic infections such as untreated tuberculosis. ANOREXIA - Loss of appetite. Symptom frequently seen in many illnesses, including tuberculosis. ATTENUATED - Refers to the weakened ability of an infectious agent to cause disease . For example, BCG is an attenuated strain of Mycobacterium bovis . BACTERICIDAL - Capable of killing bacteria. Isoniazid and rifampin are the two most potent bactericidal antituberculous drugs. BACTERIOLOGICAL SPECIMEN - Refers to any body fluid, secretion, or tissue sent to the laboratory where smears and cultures for tubercle bacilli will be performed.
    [Show full text]
  • 7. Smooth Tubercle Bacilli Neglected Opportunistic Tropical Pathogens
    Scien ce et Environnement 30 (2016) 110 -121 110 ISSN 2409 -6245 , http://www.scienceetenvironnement.dj Smooth Tubercle B acilli: Neglected O pportunistic Tropical Pathogens Djaltou Aboubaker Osman 1, 2 ‡, Feriel Bouzid 1, 3 ‡, Stéphane Canaan 3, Michel D rancourt 1* 1. Aix-Marseille Université, URMITE, UMR CNRS 7278, IRD 198, Inserm 1095, Marseille, France. 2. Institut de Recherche Médicinale (IRM), Centre d’Étu des et de Recherche de Djibouti (CERD). 3. Centre National de la Recherche Scientifique (CNRS) - Aix-Marseille Université - Enzymologie Interfaciale et Phy siologie de la Lipolyse UMR7282. Marseille, France. *Corresponding author: Professor Michel DRANCOURT, Unité de Recherche sur les Maladies Infectieuses et Tropicales Emergentes, Faculté de Médecine, 27, Boulevard Jean Moulin, 13385 Mars eille Cedex 5, France. Tel: +33 4 91 32 43 75; Fax: +33 4 91 38 77 72 Email: [email protected] Abstract Smooth tubercle bacilli (STB) including ‘‘Mycobacterium canettii’’ are members of the Mycobacterium tuberculosis complex (MTBC) which cause non-contagious tuberculosis in human. This group compr ise s less than one hundred isolates characterized by smooth colonies and cordless organisms. Most STB isolates have been obtained from patients expo sed to the Republic of Djibouti but seven isolates, including the three seminal ones obtained by Georges Canetti between 1968 and 1970, were recovered from patients in France, Madagascar, Sub-Sahara East Africa and French Polynesia. STB form a genetically heterogeneous group of MT BC organisms with large 4.48 ± 0.05 Mb genomes which may link Mycobacterium kansasii to MTBC organisms. Lack of inter-human transmission suggested a yet unknown environmental reservoir .
    [Show full text]
  • Lsr2: an H-NS Functional Analog and Global Regulator of Mycobacterium Tuberculosis
    Lsr2: an H-NS functional analog and global regulator of Mycobacterium tuberculosis by Blair Richard George Gordon A thesis submitted in conformity with the requirements for the degree of Doctor of Philosophy Department of Molecular Genetics University of Toronto © Copyright by Blair Gordon 2013 i Lsr2: an H-NS functional analog and global regulator of Mycobacterium tuberculosis Blair Gordon Doctor of Philosophy Department of Molecular Genetics University of Toronto 2012 Abstract Mycobacterium tuberculosis (M. tb), the etiological agent of tuberculosis (TB), continues to be one of the leading global health challenges causing ~2 million deaths annually. In the majority of infected individuals, the bacteria establish a latent, asymptomatic infection capable of persisting for decades with 5-10% of infected individuals developing active disease in their lifetime. Currently it is estimated that one-third of the world’s population is latently infected, representing a large reservoir for disease reactivation and subsequent spread. Latent TB infection is a paucibacillary disease in which a small heterogeneous population of bacilli is present in the body. M. tb persisters, which are characterized by reduced or altered metabolic activity and enhanced drug tolerance, are thought to be the major contributor towards latent infection and disease relapse following chemotherapy; however, the molecular mechanisms governing persisters formation remain poorly understood. My thesis concerns the characterization of the highly conserved DNA binding protein Lsr2 of mycobacteria. Previous biochemical study of Lsr2 revealed it exhibits DNA-bridging activity analogous to H-NS, an important nucleoid associated protein found in the proteobacteria. ii Here I show using in vivo complementation assays that Lsr2 is functionally equivalent to H-NS, even though these proteins share no sequence similarity.
    [Show full text]
  • APUTS) Reporting Terminology and Codes Microbiology (V1.0
    AUSTRALIAN PATHOLOGY UNITS AND TERMINOLOGY (APUTS) Reporting Terminology and Codes Microbiology (v1.0) 1 12/02/2013 APUTS Report Information Model - Urine Microbiology Page 1 of 1 Specimen Type Specimen Macro Time Glucose Bilirubin Ketones Specific Gravity pH Chemistry Protein Urobilinogen Nitrites Haemoglobin Leucocyte Esterases White blood cell count Red blood cells Cells Epithelial cells Bacteria Microscopy Parasites Microorganisms Yeasts Casts Crystals Other elements Antibacterial Activity No growth Mixed growth Urine MCS No significant growth Klebsiella sp. Bacteria ESBL Klebsiella pneumoniae Identification Virus Fungi Growth of >10^8 org/L 10^7 to 10^8 organism/L of mixed Range or number Colony Count growth of 3 organisms 19090-0 Culture Organism 1 630-4 LOINC >10^8 organisms/L LOINC Significant growth e.g. Ampicillin 18864-9 LOINC Antibiotics Susceptibility Method Released/suppressed None Organism 2 Organism 3 Organism 4 None Consistent with UTI Probable contamination Growth unlikely to be significant Comment Please submit a repeat specimen for testing if clinically indicated Catheter comments Sterile pyuria Notification to infection control and public health departments PUTS Urine Microbiology Information Model v1.mmap - 12/02/2013 - Mindjet 12/02/2013 APUTS Report Terminology and Codes - Microbiology - Urine Page 1 of 3 RCPA Pathology Units and Terminology Standardisation Project - Terminology for Reporting Pathology: Microbiology : Urine Microbiology Report v1 LOINC LOINC LOINC LOINC LOINC LOINC LOINC Urine Microbiology Report
    [Show full text]