Final Screening Assessment of Micrococcus Luteus Strain ATCC 4698
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University of Cincinnati
UNIVERSITY OF CINCINNATI Date: February 22, 2007 I, _ Samuel Lee Hayes________________________________________, hereby submit this work as part of the requirements for the degree of: Doctor of Philosophy in: Biological Sciences It is entitled: Response of Mammalian Models to Exposure of Bacteria from the Genus Aeromonas Evaluated using Transcriptional Analysis and Conjectures on Disease Mechanisms This work and its defense approved by: Chair: _Brian K. Kinkle _Dennis W. Grogan _Richard D. Karp _Mario Medvedovic _Stephen J. Vesper Response of Mammalian Models to Exposure of Bacteria from the Genus Aeromonas Evaluated using Transcriptional Analysis and Conjectures on Disease Mechanisms A dissertation submitted to the Division of Graduate Studies and Research of the University of Cincinnati in partial fulfillment of the requirements for the degree of DOCTOR OF PHILOSOPHY in the Department of Biological Sciences of the College of Arts and Sciences 2007 by Samuel Lee Hayes B.S. Ohio University, 1978 M.S. University of Cincinnati, 1986 Committee Chair: Dr. Brian K. Kinkle Abstract The genus Aeromonas contains virulent bacteria implicated in waterborne disease, as well as avirulent strains. One of my research objectives was to identify and characterize host- pathogen relationships specific to Aeromonas spp. Aeromonas virulence was assessed using changes in host mRNA expression after infecting cell cultures and live animals. Messenger RNA extracts were hybridized to murine genomic microarrays. Initially, these model systems were infected with two virulent A. hydrophila strains, causing up-regulation of over 200 and 50 genes in animal and cell culture tissues, respectively. Twenty-six genes were common between the two model systems. The live animal model was used to define virulence for many Aeromonas spp. -
Kaistella Soli Sp. Nov., Isolated from Oil-Contaminated Soil
A001 Kaistella soli sp. nov., Isolated from Oil-contaminated Soil Dhiraj Kumar Chaudhary1, Ram Hari Dahal2, Dong-Uk Kim3, and Yongseok Hong1* 1Department of Environmental Engineering, Korea University Sejong Campus, 2Department of Microbiology, School of Medicine, Kyungpook National University, 3Department of Biological Science, College of Science and Engineering, Sangji University A light yellow-colored, rod-shaped bacterial strain DKR-2T was isolated from oil-contaminated experimental soil. The strain was Gram-stain-negative, catalase and oxidase positive, and grew at temperature 10–35°C, at pH 6.0– 9.0, and at 0–1.5% (w/v) NaCl concentration. The phylogenetic analysis and 16S rRNA gene sequence analysis suggested that the strain DKR-2T was affiliated to the genus Kaistella, with the closest species being Kaistella haifensis H38T (97.6% sequence similarity). The chemotaxonomic profiles revealed the presence of phosphatidylethanolamine as the principal polar lipids;iso-C15:0, antiso-C15:0, and summed feature 9 (iso-C17:1 9c and/or C16:0 10-methyl) as the main fatty acids; and menaquinone-6 as a major menaquinone. The DNA G + C content was 39.5%. In addition, the average nucleotide identity (ANIu) and in silico DNA–DNA hybridization (dDDH) relatedness values between strain DKR-2T and phylogenically closest members were below the threshold values for species delineation. The polyphasic taxonomic features illustrated in this study clearly implied that strain DKR-2T represents a novel species in the genus Kaistella, for which the name Kaistella soli sp. nov. is proposed with the type strain DKR-2T (= KACC 22070T = NBRC 114725T). [This study was supported by Creative Challenge Research Foundation Support Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education (NRF- 2020R1I1A1A01071920).] A002 Chitinibacter bivalviorum sp. -
Microbiota of Human Precolostrum and Its Potential Role As a Source Of
www.nature.com/scientificreports OPEN Microbiota of human precolostrum and its potential role as a source of bacteria to the infant mouth Received: 24 October 2018 Lorena Ruiz1,2, Rodrigo Bacigalupe3, Cristina García-Carral2,4, Alba Boix-Amoros3, Accepted: 2 April 2019 Héctor Argüello5, Camilla Beatriz Silva2,6, Maria de los Angeles Checa7, Alex Mira3 & Published: xx xx xxxx Juan M. Rodríguez 2 Human milk represents a source of bacteria for the initial establishment of the oral (and gut) microbiomes in the breastfed infant, however, the origin of bacteria in human milk remains largely unknown. While some evidence points towards a possible endogenous enteromammary route, other authors have suggested that bacteria in human milk are contaminants from the skin or the breastfed infant mouth. In this work 16S rRNA sequencing and bacterial culturing and isolation was performed to analyze the microbiota on maternal precolostrum samples, collected from pregnant women before delivery, and on oral samples collected from the corresponding infants. The structure of both ecosystems demonstrated a high proportion of taxa consistently shared among ecosystems, Streptococcus spp. and Staphylococcus spp. being the most abundant. Whole genome sequencing on those isolates that, belonging to the same species, were isolated from both the maternal and infant samples in the same mother-infant pair, evidenced that in 8 out of 10 pairs both isolates were >99.9% identical at nucleotide level. The presence of typical oral bacteria in precolostrum before contact with the newborn indicates that they are not a contamination from the infant, and suggests that at least some oral bacteria reach the infant’s mouth through breastfeeding. -
Laboratory Exercises in Microbiology: Discovering the Unseen World Through Hands-On Investigation
City University of New York (CUNY) CUNY Academic Works Open Educational Resources Queensborough Community College 2016 Laboratory Exercises in Microbiology: Discovering the Unseen World Through Hands-On Investigation Joan Petersen CUNY Queensborough Community College Susan McLaughlin CUNY Queensborough Community College How does access to this work benefit ou?y Let us know! More information about this work at: https://academicworks.cuny.edu/qb_oers/16 Discover additional works at: https://academicworks.cuny.edu This work is made publicly available by the City University of New York (CUNY). Contact: [email protected] Laboratory Exercises in Microbiology: Discovering the Unseen World through Hands-On Investigation By Dr. Susan McLaughlin & Dr. Joan Petersen Queensborough Community College Laboratory Exercises in Microbiology: Discovering the Unseen World through Hands-On Investigation Table of Contents Preface………………………………………………………………………………………i Acknowledgments…………………………………………………………………………..ii Microbiology Lab Safety Instructions…………………………………………………...... iii Lab 1. Introduction to Microscopy and Diversity of Cell Types……………………......... 1 Lab 2. Introduction to Aseptic Techniques and Growth Media………………………...... 19 Lab 3. Preparation of Bacterial Smears and Introduction to Staining…………………...... 37 Lab 4. Acid fast and Endospore Staining……………………………………………......... 49 Lab 5. Metabolic Activities of Bacteria…………………………………………….…....... 59 Lab 6. Dichotomous Keys……………………………………………………………......... 77 Lab 7. The Effect of Physical Factors on Microbial Growth……………………………... 85 Lab 8. Chemical Control of Microbial Growth—Disinfectants and Antibiotics…………. 99 Lab 9. The Microbiology of Milk and Food………………………………………………. 111 Lab 10. The Eukaryotes………………………………………………………………........ 123 Lab 11. Clinical Microbiology I; Anaerobic pathogens; Vectors of Infectious Disease….. 141 Lab 12. Clinical Microbiology II—Immunology and the Biolog System………………… 153 Lab 13. Putting it all Together: Case Studies in Microbiology…………………………… 163 Appendix I. -
Micrococcus Luteus (Schroeter 1872) Cohn 1872, and Desig- Nation of the Neotype Strain M
INTERNATIONAL JOURNAL of SYSTEMATIC BACTERIOLOGY Vol. 22, No. 4 October 1972, p. 218-223 Printed in U.S.A. Copyright 0 1972 International Association of Microbiological Societies Taxonomic Status of Micrococcus luteus (Schroeter 1872) Cohn 1872, and Desig- nation of the Neotype Strain M. KOCUR, ZDENA PkCOVA, and T. MARTINEC Czechoslovak Collection of Microorganisms, J. E. PurkynE University, Brno, Czechoslovakia An amended description of Micrococcus luteus (Schroeter 1872) Cohn 1872, at present a broad-based species characterized primarily on negative charact er- istics, is proposed on the basis of a taxonomic analysis of 30 strains. CCM 169 (= ATCC 4698) is designated a's the neotype strain of M. luteus. A large number of species of aerobic, diameter and arranged in tetrads and in catalase-positive, yellow-pigmented micrococci irregular clumps of tetrads. Strains CCM 248, have been described, but their incomplete 337, 1674, and 2494 formed packets and characterization has hindered their classifica- irregular clusters of packets. These strains also tion. Some of them are known as Micrococcus produced the largest cells (1.5 to 1.8 pm) of all luteus, M. flaws, M. lysodeikticus, Sarcina of those studied. None of the strains was motile lutea, and S. flava. At present only two of these or produced spores. are generally accepted: M. luteus and M. varians Cultural characteristics. Colonies of all of the (13, 21). strains were circular, convex, and smooth, with Although M. luteus is the type species of the either a glistening or a dull surface. Tetrad- and genus Micrococcus, it is not sufficiently de- packet-forming strains produced matted colo- fined. -
Kocuria (Micrococcus) and Cultivation Methods for Their Detection – Part 1
Kvasny Prum. 10 64 / 2018 (1) Brewing Microbiology – Kocuria (Micrococcus) and Cultivation Methods for their Detection – Part 1 DOI: 10.18832/kp201804 Brewing Microbiology – Kocuria (Micrococcus) and Cultivation Methods for their Detection – Part 1 Mikrobiologie pivovarské výroby – bakterie Kocuria (Micrococcus) a kultivační metody pro jejich detekci – 1. část Dagmar MATOULKOVÁ, Petra KUBIZNIAKOVÁ Mikrobiologické oddělení, Výzkumný ústav pivovarský a sladařský, a.s., / Department of Microbiology, Research Institute of Brewing and Malting, PLC, Lípová 15, 120 44 Prague, e-mail: [email protected], [email protected] Recenzovaný článek / Reviewed Paper Matoulková, D., Kubizniaková, P., 2018: Brewing microbiology – Kocuria (Micrococcus) and cultivation methods for their detection – Part 1. Kvasny Prum. 64(1): 10–13 Signifi cant brewery species of micrococcus were reclassifi ed to the genus Kocuria: Kocuria kristinae (previously Micrococcus kristinae) and Kocuria varians (previously Micrococcus varians). Bacteria of genus Kocuria belong to less risky microbial contaminants of beer and brewery plant. Species Kocuria kristinae may exceptionally cause beer spoilage. Signifi cant is their misplacement for pediococci. Here we present an overview of basic morphological and physiological properties of Kocuria (Micrococcus) species and describe their harmfulness in the brewing process. Matoulková, D., Kubizniaková, P., 2018: Mikrobiologie pivovarské výroby – bakterie Kocuria (Micrococcus) a kultivační metody pro jejich detekci – 1. část. Kvasny Prum. 64(1): 10–13 Pivovarsky významné druhy mikrokoků byly reklasifi kovány do rodu Kocuria: Kocuria kristinae (dříve Micrococcus kristinae) a Kocuria varians (dříve Micrococcus varians). Bakterie rodu Kocuria patří k méně rizikovým mikrobiálním kontaminacím piva a pivovarského pro- vozu. Výjimečně může být druh Kocuria kristinae původcem kažení piva. Význam těchto bakterií spočívá zejména v možnosti záměny s pediokoky. -
Breast Milk Microbiota: a Review of the Factors That Influence Composition
Published in "Journal of Infection 81(1): 17–47, 2020" which should be cited to refer to this work. ✩ Breast milk microbiota: A review of the factors that influence composition ∗ Petra Zimmermann a,b,c,d, , Nigel Curtis b,c,d a Department of Paediatrics, Fribourg Hospital HFR and Faculty of Science and Medicine, University of Fribourg, Switzerland b Department of Paediatrics, The University of Melbourne, Parkville, Australia c Infectious Diseases Research Group, Murdoch Children’s Research Institute, Parkville, Australia d Infectious Diseases Unit, The Royal Children’s Hospital Melbourne, Parkville, Australia s u m m a r y Breastfeeding is associated with considerable health benefits for infants. Aside from essential nutrients, immune cells and bioactive components, breast milk also contains a diverse range of microbes, which are important for maintaining mammary and infant health. In this review, we summarise studies that have Keywords: investigated the composition of the breast milk microbiota and factors that might influence it. Microbiome We identified 44 studies investigating 3105 breast milk samples from 2655 women. Several studies Diversity reported that the bacterial diversity is higher in breast milk than infant or maternal faeces. The maxi- Delivery mum number of each bacterial taxonomic level detected per study was 58 phyla, 133 classes, 263 orders, Caesarean 596 families, 590 genera, 1300 species and 3563 operational taxonomic units. Furthermore, fungal, ar- GBS chaeal, eukaryotic and viral DNA was also detected. The most frequently found genera were Staphylococ- Antibiotics cus, Streptococcus Lactobacillus, Pseudomonas, Bifidobacterium, Corynebacterium, Enterococcus, Acinetobacter, BMI Rothia, Cutibacterium, Veillonella and Bacteroides. There was some evidence that gestational age, delivery Probiotics mode, biological sex, parity, intrapartum antibiotics, lactation stage, diet, BMI, composition of breast milk, Smoking Diet HIV infection, geographic location and collection/feeding method influence the composition of the breast milk microbiota. -
An Update on the Genus Aeromonas: Taxonomy, Epidemiology, and Pathogenicity
microorganisms Review An Update on the Genus Aeromonas: Taxonomy, Epidemiology, and Pathogenicity Ana Fernández-Bravo and Maria José Figueras * Unit of Microbiology, Department of Basic Health Sciences, Faculty of Medicine and Health Sciences, IISPV, University Rovira i Virgili, 43201 Reus, Spain; [email protected] * Correspondence: mariajose.fi[email protected]; Tel.: +34-97-775-9321; Fax: +34-97-775-9322 Received: 31 October 2019; Accepted: 14 January 2020; Published: 17 January 2020 Abstract: The genus Aeromonas belongs to the Aeromonadaceae family and comprises a group of Gram-negative bacteria widely distributed in aquatic environments, with some species able to cause disease in humans, fish, and other aquatic animals. However, bacteria of this genus are isolated from many other habitats, environments, and food products. The taxonomy of this genus is complex when phenotypic identification methods are used because such methods might not correctly identify all the species. On the other hand, molecular methods have proven very reliable, such as using the sequences of concatenated housekeeping genes like gyrB and rpoD or comparing the genomes with the type strains using a genomic index, such as the average nucleotide identity (ANI) or in silico DNA–DNA hybridization (isDDH). So far, 36 species have been described in the genus Aeromonas of which at least 19 are considered emerging pathogens to humans, causing a broad spectrum of infections. Having said that, when classifying 1852 strains that have been reported in various recent clinical cases, 95.4% were identified as only four species: Aeromonas caviae (37.26%), Aeromonas dhakensis (23.49%), Aeromonas veronii (21.54%), and Aeromonas hydrophila (13.07%). -
Micrococcus Luteus - Survival in Amber C.L
View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by DigitalCommons@CalPoly Micrococcus luteus - Survival in Amber C.L. Greenblatt , J. Baum , B.Y. Klein , S. Nachshon , V. Koltunov and R.J. Cano Abstract Introduction A growing body of evidence now supports the isolation of There is an accumulating body of data reporting the microorganisms from ancient materials. However, ques persistence of bacteria in what are considered extreme and tions about the stringency of extraction methods and the oligotrophic environments [15, 24, 37]. However, the genetic relatedness of isolated organisms to their closest mechanisms used by these bacteria to survive in such living relatives continue to challenge the authenticity of conditions are poorly understood. One extreme niche that these ancient life forms. Previous studies have success has consistently yielded such bacteria is amber, from fully isolated a number of spore-forming bacteria from which single isolates and assemblages of multiple bacterial organic and inorganic deposits of considerable age whose species have been characterized [3, 8, 10, 17]. Amber is the survival is explained by their ability to enter suspended fossilized remains of organic tree resins. As volatile terp animation for extended periods of time. However, de enoids in these resins evaporate and dissipate under nat spite a number of putative reports, the isolation of non ural forest conditions they leave the nonvolatile fractions spore-forming bacteria and an explanation for their to become fossilized through progressive oxidation and survival have remained enigmatic. Here we describe the polymerization. During the early stages of solidification isolation of non-spore-forming cocci from a 120-million microorganisms, and occasionally larger organisms such year-old block of amber, which by genetic, morphologi as insects [3], can become entrapped in the resins [31]. -
Identification of 129 Micrococcaceae Strains Isolated from Food of Animal Origin C
Identification of 129 Micrococcaceae strains isolated from food of animal origin C. Delarras, C. Guichaoua and M.-P. Caprais Code words: Staphylococcus- nitrofurantoin- aurease- ID 32 STAPH Tab. 1: List of 26 biochemical tests in the ID 32 STAPH-system - numerical identification Reaction/ Test Reaction/ Test substrate substrate 129 strains of Micrococcaceae novobiocin (5 11g/ml), 13 to 44% Urease URE Cellobiose (F) GEL were isolated from food of animal were identified with negative dis Aginin dihydrolase ADH Acetoin (production) VP origin (minced meat, cakes with cordant tests using this mi Ornithin decarboxylase ODC Nitrat (reduction) NIT confectioner's custard) on Baird cromethod. 44% produced no ac Esculin (hydrolysis) ESC B Galactosidase B GAL Glucose (F) GLU Arginin arylamidase ArgA Parker medium. etoin, 35 % had no urease and Fructose (F) FRU Alkaline phosphatase PAL 15 % no arginine dihydrolase. Maltose (F) MAL Pyrrolidonyl Arylamidase PyrA 120 were Staphylococcus and 9 Mannose (F) MNE Novobiocin (Resistance) NOVO Lactose (F) LAC Sucrose (F) SAC Micrococcus, according to the 10 48 Staphylococcus strains (40 %) Trehalose (F) TRE N-Acetyl Glucosamine (F) NAG 32 STAPH-System (1989). The re were identified as human coagula Mannitol (F) MAN Turanose (F) TUR sults were analyzed using a com se negative Staphylococcus spe Raffinose (F) RAF Arabinose (F) ARA Ribose (F) RIB B Glucoronidase B GUR puter program. cies (strains: 39; species: 9) or as animal species (strains: 4; spe (F) ~ Fermentation 60% of these 120 Staphylococcus cies: 1). 5 were Staphylococcus strains of animal origin were co sp S. epidermidis and S. warneri - similar colonies, but without reading of the biochemical tests agulase positive S. -
Kocuria Spp. in Foods: Biotechnological Uses and Risks for Food Safety
Review Article APPLIED FOOD BIOTECHNOLOGY, 2021, 8 (2):79-88 pISSN: 2345-5357 Journal homepage: www.journals.sbmu.ac.ir/afb eISSN: 2423-4214 Kocuria spp. in Foods: Biotechnological Uses and Risks for Food Safety Gustavo Luis de Paiva Anciens Ramos1, Hilana Ceotto Vigoder2, Janaina dos Santos Nascimento2* 1- Department of Bromatology, Universidade Federal Fluminense (UFF), Brazil. 2- Department of Microbiology, Instituto Federal de Educação, Ciência e Tecnologia do Rio de Janeiro (IFRJ), Brazil. Article Information Abstract Article history: Background and Objective: Bacteria of the Genus Kocuria are found in several Received 4 June 2020 environments and their isolation from foods has recently increased due to more Revised 17 Aug 2020 precise identification protocols using molecular and instrumental techniques. This Accepted 30 Sep 2020 review describes biotechnological properties and food-linked aspects of these bacteria, which are closely associated with clinical cases. Keywords: ▪ Kocuria spp. Results and Conclusion: Kocuria spp. are capable of production of various enzymes, ▪ Gram-positive cocci being potentially used in environmental treatment processes and clinics and ▪ Biotechnological potential production of antimicrobial substances. Furthermore, these bacteria show desirable ▪ Biofilm enzymatic activities in foods such as production of catalases and proteases. Beneficial ▪ Antimicrobial resistance interactions with other microorganisms have been reported on increased production of enzymes and volatile compounds in foods. However, there are concerns about the *Corresponding author: Janaina dos Santos Nascimento, bacteria, including their biofilm production, which generates technological and safety Department of Microbiology, problems. The bacterial resistance to antimicrobials is another concern since isolates Instituto Federal de Educação, of this genus are often resistant or multi-resistant to antimicrobials, which increases Ciência e Tecnologia do Rio de the risk of gene transfer to pathogens of foods. -
Data of Read Analyses for All 20 Fecal Samples of the Egyptian Mongoose
Supplementary Table S1 – Data of read analyses for all 20 fecal samples of the Egyptian mongoose Number of Good's No-target Chimeric reads ID at ID Total reads Low-quality amplicons Min length Average length Max length Valid reads coverage of amplicons amplicons the species library (%) level 383 2083 33 0 281 1302 1407.0 1442 1769 1722 99.72 466 2373 50 1 212 1310 1409.2 1478 2110 1882 99.53 467 1856 53 3 187 1308 1404.2 1453 1613 1555 99.19 516 2397 36 0 147 1316 1412.2 1476 2214 2161 99.10 460 2657 297 0 246 1302 1416.4 1485 2114 1169 98.77 463 2023 34 0 189 1339 1411.4 1561 1800 1677 99.44 471 2290 41 0 359 1325 1430.1 1490 1890 1833 97.57 502 2565 31 0 227 1315 1411.4 1481 2307 2240 99.31 509 2664 62 0 325 1316 1414.5 1463 2277 2073 99.56 674 2130 34 0 197 1311 1436.3 1463 1899 1095 99.21 396 2246 38 0 106 1332 1407.0 1462 2102 1953 99.05 399 2317 45 1 47 1323 1420.0 1465 2224 2120 98.65 462 2349 47 0 394 1312 1417.5 1478 1908 1794 99.27 501 2246 22 0 253 1328 1442.9 1491 1971 1949 99.04 519 2062 51 0 297 1323 1414.5 1534 1714 1632 99.71 636 2402 35 0 100 1313 1409.7 1478 2267 2206 99.07 388 2454 78 1 78 1326 1406.6 1464 2297 1929 99.26 504 2312 29 0 284 1335 1409.3 1446 1999 1945 99.60 505 2702 45 0 48 1331 1415.2 1475 2609 2497 99.46 508 2380 30 1 210 1329 1436.5 1478 2139 2133 99.02 1 Supplementary Table S2 – PERMANOVA test results of the microbial community of Egyptian mongoose comparison between female and male and between non-adult and adult.