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Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, nonfermentative bacilli Author: Dr. M.M. Henton and Dr. J.A. Picard Licensed under a Creative Commons Attribution license. TABLE OF CONTENTS INTRODUCTION ...........................................................................................................................................3 Table 9.1: Identifying characteristics of several genera of non-fermentative bacilli ......................3 Table 9.2: Reactions of some Gram-negative, glucose non-fermenting bacteria..........................4 Bordetella and Alcaligenes spp. ................................................................................................................4 Table 9.3: Differential characteristics of the genus Bordetella and other morphologically and physiologically similar genera ........................................................................................................6 Table 9.4: Differential characteristics for Gram-negative, non-fermentative bacteria with phenotypic characteristics similar to those of Bordetella and Alcaligenes species .......................6 Table 9.5: Differential characteristics of B. bronchiseptica, B. avium, Alcaligenes spp., and CDC groups IVc and Oligella. All are motile (except B. parapertussis), oxidase (except B. avium and B. parapertussis) – and catalase-positive, and grow on MacConkey agar) .................7 Riemerella Anatipestifer .............................................................................................................................7 Moraxella spp. ..............................................................................................................................................7 Table 9.6: Summary of the disease and sites of isolation of some the Moraxella species ...........8 Table 9.7: Differentiation of the Moraxella/Brahamnella species ..................................................8 Pseudomonas spp. and other related genera ..........................................................................................9 Table 9.8: Pathogenicity and the normal habitat of Pseudomonas/Burkholderia species of veterinary importance.....................................................................................................................9 1|Page Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli Table 9.9: Main characteristics of the pathogenic Pseudomonas/Burkholderia species .............10 Table 9.10: Identification of common members of the Pseudomonaceae (all are motile) ...........12 Shewenella .................................................................................................................................................13 Table 9.11: Identification of Shewenella species (all are Gram-negative curved or straight rods, catalase and oxidase positive, motile and grow in 3% NaCl. Negative for arginine dehydrolase, lysine or ornithine decarboxylase and indole production) ......................................14 Flavobacterium and related bacteria ......................................................................................................14 APPENDIX 1 ...............................................................................................................................................15 2|Page Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli INTRODUCTION Many Gram-negative bacteria fall into this group and include: Alcaligenes spp., Acinetobacter spp., Bordetella spp, Branhamella spp., Flavobacterium spp., Francisella tularensis, Moraxella spp., Neisseria spp., Pseudomonas spp., and Burkholderia spp. Very few isolates are clinically significant, with most being isolated as normal commensal flora or as sample contaminants. Bacteria that are potentially pathogenic include Bordetella bronchiseptica, Pseudomonas aeruginosa, Burkholderia mallei, Burkholderia pseudomallei and Moraxella bovis. These bacteria are particularly difficult to identify as they show few biochemical reactions, and commercial tests such as the API 20 NE are recommended. Although dealt with in a separate chapter, note that Brucella spp. are similar to this group. Bacteria of veterinary significance will be discussed under their respective headings. Tables 9.1, 9.2 and 9.3 list the characteristics of some of these bacteria. As they are a diverse and difficult group to identify, an identification key is included to assist in grouping them. Table 9.1: Identifying characteristics of several genera of non-fermentative bacilli Genus Metabolism Motility Oxidase Growth on MacConkey agar Acinetobacter Oxidative or nonsaccharolytic Non-motile Negative Good growth except for some strains of A. lwoffii Alcaligenes Oxidative Motile by means of peritrichous flagella Positive Good growth Nonsaccharolytic Motile by peritrichous flagella Positive Good growth Oxidative Variable. Those species motile aro peritrichous flagella are B. bronchiseptica, B. avium, and B. hinzii) Most are positive except B. parapertussis is negative and B. avium is variable. B. parapertussis and B. bronchiseptica Bordetella Flavobacterium Oxidative (some strains are slow fermenters) Non-motile Positive Poor or negative Moraxella Oxidative or nonsaccharolytic Non-motile Positive Scant or negative 3|Page Additional characteristics Special growth factors are not required. Acid production from glucose is weak (A. baumannii) or lacking (A. lwoffii). Cells appear coccoid in Gram-stained preparations. Most strains are penicillin resistant. Obligate aerobe. Glucose may be oxidized slowly (5 days); xylose is oxidized rapidly (24 hours) Strict aerobe, although some strains utilize nitrate instead of oxygen as the final electron acceptor. B. bronchiseptica rapidly splits urea (within 4 hours) Supplemental nitrogen and Bcomplex vitamins required for growth of many strains. Yellow pigment often produced. No denitrification of nitrates. Growth optimal at 30°C. All species are resistant to polymyxin B. Most species are weak indole positive (F. odoratum is indole negative). Most strains are fastidious in growth requirements, some requiring serum supplement. Strict aerobes. May appear as coccobacilli on Gram’s stain. Highly susceptible to penicillin. Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli Pigment Penicillin susceptibility Gelatinase Indole Urease Nitrate reduction Oxidase Catalase Motility Growth on MacConkey agar Haemolysis Acid from glucose Table 9.2: Reactions of some Gram-negative, glucose non-fermenting bacteria Alcaligenes faecalis A. xylosidans A. denitrificans A. piechaudii Acinetobacter calcoaceticus A. lwoffii Branhamella catarrhalis v - - + + + + + + + + + + + + + + + + + + + v - - - R R v R - + - + - + - - v - - R - - + - - + + + (+) - - - v S - Moraxella caviae - - - + + + - - - S - M. cuniculi M. bovis M. ovis Neisseria canis N. flavescens N. sicca N. lactamica N. denitrificans N. mucosa N. weaveri N. elongata Flavobacterium meningosepticum F. indologenes F. odoratum F. multovorum Weeksella zoohelcum CDC group EF-4 O O O O - (w) () v v - v v - + (+) + + + + + + + + - + + + + + + + + + + + (+) + + + - - (+) + - S S S S S S S S S S (S) Yellow Yellow v (Yellow) Yellow v(Yellow) v(Yellow) - O () + - + + - - + + R v(Yellow) O O (O) v () () v() - v + + v - + + + + + + + + + + v + (-) + + + - + + - (+) + + - R R R S * Yellow v(Yellow) Yellow Yellow/tan O =oxidative, - = unreactive, (O)= most strains oxidative, + = positive reaction, (+) = most strains positive, (-) = most strains negative, v = variable, S = susceptible, R = resistant, * = data unavailable, = beta-haemolysis, = alpha-haemolysis, () = most strains. BORDETELLA AND ALCALIGENES SPP. These are small, motile, non-fermentative, Gram-negative rods that are catalase- and oxidase positive. Bordetella bronchiseptica is the cause of respiratory disease in mammals and B. avium the cause of turkey coryza and respiratory disease in poultry. Alcaligenes species are saprophytes present in the intestinal tracts of vertebrates. They may be opportunistic invaders and are difficult to distinguish from Bordetella. Bordetella parapertussis has been reported in sheep in Europe, and B. hinzii is not known to be pathogenic. 4|Page Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli Specimens Specimens for bacterial isolation include nasal swabs, tracheal washings and pneumonic lungs. If nasal swabs are to be taken from animals where the nasal orifice is small, flexible swabs designed for human infants should be used. Direct microscopy As Bordetella is a small Gram-negative cocco-bacillus, smears made directly from specimens are not very useful. Isolation They can all be isolated on blood agar. A selective medium described by Smith and Baskerville (See Appendix 1) can be used for contaminated lung samples. Bordetella bronchiseptica and B. avium forms blue, convex, smooth colonies 1 – 2 mm in diameter after 48 – 72 hours of incubation at 37°C. Escherichia coli and Klebsiella species form yellow colonies and Alcaligenes and Pseudomonas species green colonies. For isolates from dogs and rabbits, the medium should be prepared without gentamicin. After 24 hours of incubation on sheep and horse blood agar, B. bronchiseptica forms small, convex, smooth colonies that may be beta-haemolytic. The colonies of B .avium are similar, but non-haemolytic. Phase modulation occurs in both species and is thought to be due to loss of a capsule-like structure on subculture. Phase I colonies are convex and shiny, phase II are larger circular and convex with a smooth surface and phase III are large, flat, and granular with irregular edges. The colonies on MacConkey agar are small, pale with a pinkish hue and amber discolouration of the underlying medium. Bordetella colonies tend to be small after 24 hours, enlarging greatly at 48 hours, whereas Pseudomonas and Alcaligenes colonies are large from the start. Biochemical identification Differential characteristics for these genera are in Tables 9.3, 9.4 and 9.5. All will grow on MacConkey agar, are catalase- and oxidase-positive and produce an alkaline slant with an alkaline or no reaction in the butt of a TSI slant. Bordetella bronchiseptica, B. avium and Alcaligenes species are motile. The API rapid NFT will identify Bordetella bronchiseptica and Alcaligenes. Bordetella avium is not listed, but will assimilate adipate but not caprate, while A. faecalis assimilates caprate but not adipate. The API20E system will also identify Bordetella species. However, the CDC group may also be confused with Bordetella and Alcaligenes. Haemagglutination test Bordetella bronchiseptica possesses a haemagglutinin that will haemagglutinate washed sheep red blood cells. A young 24-hour culture should be used, as older cultures tend to lose their haemagglutinating 5|Page Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli ability. Two colonies of a suspected B. bronchiseptica culture are suspended in a drop of physiological saline on a slide. An equal volume of a 3% suspension of washed sheep red cells is added and mixed. To check for auto-agglutination, controls should include a suspension of colonies without red blood cells and a suspension of red blood cells alone. B. bronchiseptica will auto-agglutinate the red cells within 1-2 minutes. Serology Tube agglutination, micro-agglutination and ELISA procedures have been developed for B. avium and B. bronchiseptica. Detection of dermo-necrotic toxin of Bordetella bronchiseptica Bordetella bronchiseptica produces an intracellular, heat-labile toxin that is lethal when injected intraperitoneally into mice, and produces necrosis when inoculated intradermally into guinea pigs. Table 9.3: Differential characteristics of the genus Bordetella and other morphologically and physiologically similar genera Characteristics Strictly parasitic Saprophytic Localise on respiratory cilia Strictly aerobic Growth requirements: Thiamine Nicotinamide X and/or V factor Ferments carbohydrates Nitrate reduction Litmus milk/ alkaline Oxidation of amino acids Tetrazolium reduction Bordetella + + + Alcaligenes + + Brucella + (+) Haemophilus + - Riemerella + (+) + d + + + d + + - + + + d + + + + + d Table 9.4: Differential characteristics for Gram-negative, non-fermentative bacteria with phenotypic characteristics similar to those of Bordetella and Alcaligenes species Bacterial genera Bordetella Alcaligenes Pseudomonas/ Burkholderia Flavobacterium Moraxella Eikenella Acinetobacter Glucose oxidation d Oxidase + + + + Growth on MacConkey + + + + Rods/ cocci R R Type of flagella peritrichous peritrichous Motility d + d + +* R polar d d + + + + (+) + - d d d - R C R C - * Burkholderia mallei is non-motile 6|Page Catalase Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli Table 9.5: Differential characteristics of B. bronchiseptica, B. avium, Alcaligenes spp., and CDC groups IVc and Oligella. All are motile (except B. parapertussis), oxidase (except B. avium and B. parapertussis) – and catalase-positive, and grow on MacConkey agar) Bacteria genera B. bronchiseptica B. avium B. parapertussis B. hinzii A. faecalis A. xylosoxydans A. denitrificans A. piechaudii CDC group IVc-2 O. ureolytica Urease + + d + + Nitrate reduction + + + + + Oxidation of Glucose + - Simmon’s citrate Malonate + + + + + + d - + + + + + + + + RIEMERELLA ANATIPESTIFER Riemerella anatipestifer (previously designated Pasteurella anatipestifer) causes septicaemia and respiratory disease in poultry, especially ducks. It is catalase- and oxidase-positive, and does not grow on MacConkey agar. It prefers microaerophilic conditions. It is variable for urease, negative for nitrate and is usually gelatine positive. Acid production from sugars is normally negative, except glucose and maltose that are positive. Its biochemical reactions are listed in Table 9.3. MORAXELLA SPP. Moraxella are short, plump Gram-negative rods (1–1,5 x 1,5-2,5 µm) found characteristically in pairs. Some strains approach a completely coccoid shape. They are strict aerobes, oxidative-, oxidase- and catalase-positive, non-motile and do not attack carbohydrates. Although they grow on non-enriched media, their growth is enhanced by the addition of blood or serum. The optimal temperature for growth is 33 – 35°C. Most Psychrobacter phenylpyruvica strains will grow on MacConkey agar, but M. bovis and M. lacunata will not. A summary of the differential characteristics is included in Table 9.7. LABORATORY DIAGNOSIS Moraxella bovis Specimens 7|Page Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli A swab of the lachrymal secretions is taken from the deep canthus of the eye. Ideally BTA plates should be inoculated immediately after collection. If this is not possible, each swab is placed in about 1– 2 ml of sterile distilled water, to prevent desiccation, and the specimens taken to the laboratory within two hours after collection. Table 9.6: Summary of the disease and sites of isolation of some the Moraxella species Species Host Cattle Horses Many animal species M. lacunata Humans Psychrobacter phenylpyruvica Disease Conjunctiva or nasopharynx of cattle older than 2 years M. bovis M. ovis Natural habitat Sheep Sheep & cattle Pigs Goats Infectious bovine keratoconjunctivitis Conjunctivitis Opportunistic pathogen: septicaemia, abortions Mucous membranes of animals Conjunctivitis Not pathogenic Mucous membranes Urogenital tract Urogenital tract Intestinal tract Pathogenicity for animals is unknown Table 9.7: Differentiation of the Moraxella/Brahamnella species Characteristic Beta-haemolysis (blood) Growth on MacConkey agar Oxidase Catalase Nitrate reduction Urease DNAse Peptonisation of milk Gelatinase or Loeffler serum slope M. bovis + (not equine strains) + (+) + (+) B. ovis M. lacunata Other Moraxella P. phenylpyruvica + - - - + + + (+) + - + + + - (+) + + (+) + + d + + d d (-) + - - Direct microscopy Gram-stained smears show Gram-negative short, plump diplobacilli. A fluorescent antibody technique will demonstrate and identify M. bovis if sufficient bacterial cells are present. Isolation Inoculate BTA and incubate at 35°C for 48–72 hours. The inoculation of the MacConkey plate is useful to gauge the degree of contamination by other Gram-negative bacteria, as M. bovis does not grow on this agar. Colony identification 8|Page Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli After 48 hours of incubation, small greyish-white colonies, surrounded by a narrow zone of betahaemolysis are seen. They look similar to streptococci. New isolates are often pilated and erode the agar, sinking into it. Colonial growth autoagglutinates when suspended in saline. Some colonies become nonhaemolytic. Equine strains of M. bovis are non-haemolytic. So is M. lacunata and P. phenylpyruvica. Some strains of P. phenylpyruvica will grow on MacConkey agar. Moraxella bovis colonies enlarge markedly after 3 days of growth. Biochemical reactions Non-fermentative, non-motile, indole-negative and all are sensitive to penicillin. M. bovis will slowly pit a Loeffler serum slope and will grow on 5% saline medium. Litmus or Crossley milk inoculated with M. bovis becomes alkaline (blue) = peptonisation, with three zones: a blue upperlayer, a soft blue curd in the centre and the bottom white. This helps distinguish it from other related species. Moraxella species have been differentiated by the analysis of cellular fatty acid. Animal inoculation The inoculation of virulent, haemolytic and pilated strains of M. bovis intraperitoneally into guinea-pigs or mice results in a fatal infection. PSEUDOMONAS SPP. AND OTHER RELATED GENERA A meaningful number of taxonomic changes have recently been made. This group includes Pseudomonas, Burkholderia, Stenotrophomas, Shewenella and others. Pseudomonas spp. are medium sized (0,5–1,0 x 1,5–5μm), Gram-negative rods. They are strict aerobes, oxidative, catalase- and oxidasepositive, and motile by one or several polar flagella. Burkholderia mallei is the only one that is non-motile. Many produce soluble pigments and most will grow on MacConkey agar. Diseases caused by Pseudomonas species in animals are shown in Table 9.8 and main differential characteristics are in Tables 9.9 and 9.10. Table 9.8: Pathogenicity and the normal habitat of Pseudomonas/Burkholderia species of veterinary importance Agent Natural habitat B. mallei nasopharynx of carrier horses B. pseudomallei soil & water P. aeruginosa (Bacillus of green pus) soil & water 9|Page Disease in animals Glanders or farcy in horses Acute septicaemic disease in man. Melioidosis or pseudoglanders in most mammals. Septicemic disease, affects also the joints and lymph nodes Opportunistic pathogen: Cattle: mastitis, endometritis, abscesses, enteritis & arthritis. Sheep & goats: mastitis, pneumonia, “green wool”. Horses: metritis, respiratory infections & Notes Zoonosis. Must use a biosafety cabinet when handling this bacterium. Zoonosis. Must use a biosafety cabinet when handling this bacterium. Polymicrobial resistance common Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli mastitis. Dogs & cats: otitis externa, cystitis, endocarditis, dermatitis, wound infections & conjunctivitis. Reptiles: necrotic stomatitis & other necrotic lesions. S. maltophilia, B. cepacia, P. putida, P. fluorescens, P. stutzeri, Shewanella soil & water Rare opportunistic pathogens. P. fluorescens causes food spoilage and lesions in reptiles & fish Sample contaminants Table 9.9: Main characteristics of the pathogenic Pseudomonas/Burkholderia species Characteristic P. aeruginosa Pigment produced ++ Odour Growth on MacConkey Growth at 5°C Growth at 42°C Oxidation of: Glucose Lactose Arginine dehydrolase Reduction of nitrate to nitrite Reduction of nitrate to N2 gas Motility “fruity’ grape-like + + B. pseudomallei but colonies become orange to cream Putrid, becoming earthy + + B. mallei but colonies are yellow to brown - B. cepacia + + + + + + (+) + + - + + + d v + - d + + - + Yellow Sweet + d LABORATORY DIAGNOSIS Specimens Swabs or tissue samples, taken from various sites with lesions, for culture and antimicrobial sensitivity test. Direct microscopy Seen as a medium sized Gram-negative rod in exudate smears. Not characteristic. A fluorescent antibody test can be used to detect B. mallei and B. pseudomallei Isolation Pseudomonas is non-fastidious and will grow on most bacteriological media. The growth of B. mallei is enhanced by 1% glycerol. A selective medium for B. mallei can be made by adding 1 000 units of polymyxin B, 1250 units of bacitracin and 0,25mg actidione to 100 ml of trypticase soy broth. Incubate aerobically at 37°C for 24-48 hours. Some of the saprophytic Pseudomonas species such as P. 10 | P a g e Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli fluorescens will grow poorly if not at all at 37°C, and they need to be incubated at room temperature. Pseudomonas will grow in a candle jar, but prefer normal atmosphere. Colony morphology P. aeruginosa. Large greyish-blue spreading colonies (3 – 4mm) on BTA. It has a characteristic grape-like odour due to aminoacetophenone. Most strains will produce beta-haemolysis on BTA. The bacterium is non-lactose fermenting and produces various shades of blue to green pigments (pyocyanin) on MacConkey agar. Red colonies are seen on brilliant green and XLD agars, no H2S is produced. B. pseudomallei. Colony growth varies from smooth to mucoid to rough with a dull wrinkled corrugated surface. Aged colonies develop a yellow-tinge. The growth has a characteristic musty odour. Partial and later complete haemolysis is seen on sheep BTA. It is lactose-positive on MacConkey agar (B. mallei is negative) but doesn’t grow on deoxylate or Salmonella-Shigella agar. 11 | P a g e Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli Table 9.10: Identification of common members of the Pseudomonaceae (all are motile) Chryseomonas luteola RNA GROUP III Conamonas acidovoras* C. terrigena C. testosteroni Flavimonas oryzihabitans RNA GROUP I Fluorescent group Pseudomonas aeruginosa* P. fluorescens P. putida Stutzeri group P. stutzeri P. mendocina CDC group Vb3 Alcaligenes group P. alcaligenes P. pseudoalcaligenes P. species group I RNA GROUP II Pseudomallei group Burkholderia pseudomallei B. mallei§ B. cepacia B. gladioli B. picketti RNA GROUP IV Diminuta group P. dimuta P. vesicularis P. paucimobilis Shewenella putrifaciens RNA GROUP IV Xanthomonas maltophilia Oxidase - Pyoverdin - Glucose + Maltose + Lactose - Mannitol + Arginine v Lysine - Nitrite v Nitrate - Urea v ONPG + DNase - Aesculin + Polymixin S + + + - - + + - + - - + + + - - v - - NA NA - v S S S + + + V - + + - + V V - - - S + + + + + + V V - + - + + - V - - V v - - - S S + + + - + + + + + - V + + + - + + + V V V - - - - S S S + + + - - V - - - V V - V + + - V - - - - s S S + - + + + + + - + + v - - - R W + - + + + + v + v + + v - + - V V v v V + + V + - - v - R R R + + + + - V + + V + V + - - - - + - - V + - V + + + - V S S S - - + ++ + - - + v - - + + + S * Acetamide positive § non-motile 12 | P a g e Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli B. mallei. Growth is slower than that of P. aeruginosa, with smaller colonies at 24-48 hours (1 – 2mm in diameter). Initially the colonies are smooth and white to cream, as they age they become yellow. B. mallei cannot grow on MacConkey agar. The opportunist, B. cepacia may be confused with both B. mallei and B. pseudomallei. Immunological tests Melioidosis: Complement-fixation and indirect haemagglutination tests can be used to detect antibodies to B. pseudomallei. Diagnosis is however, based upon isolation and identification of the bacterium. Glanders: Complement-fixation, indirect haemagglutination and counter immunoelectrophoresis tests are used in the diagnosis of glanders. False positive reactions may be obtained in areas that are endemic for melioidosis, due to cross reactivity. The mallein test that demonstrates hypersensitivity to B. mallei infection is used to detect carrier horses. Mallein is a glycoprotein extracted from the bacterium. Either subcutaneous injection or instillation into the conjunctival sac will result in a localised swelling in positive animals. Animal inoculation The Shwartzman phenomenon is seen in male guinea-pigs inoculated intraperitoneally with infective material containing either B. pseudomallei or B. mallei. A localised peritonitis and purulent inflammation of the testes develop in 2 – 3 days. Antimicrobial sensitivity tests These need to be carried out with most members of this group, but especially P. aeruginosa as multiple drug resistance occurs. Resistance is less common to the aminoglycoside group. SHEWENELLA Members of this genus are marine bacteria. Only S. putrefaciens and S. algae are important as opportunists in animals. Both are positive for H2S production on TSI agar, which is diagnostic. Shewenella algae can grow at 42°C and is haemolytic after 2 days, and S. putrefaciens cannot grow at 42°C and is not known to be haemolytic. The identification of Shewenella species is in Table 9.11. 13 | P a g e Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli (+) D D (+) - + D D D D D - + + + - S. woodyi + + + + + + + + - S. pealeana 25-35 + (+) + + + + S. oneidensis 25-35 + + + (+) (+) + + + S. gelidimarina 25-35 S. frigidimarina - S. hanedai - S. benthica S. amazonensis - S. baltica S. putrefaciens Luminescence Optimal growth temp 4°C in 24h 35°C 40°C Nitrate Gelatinase Lipase Haemolysis H2S Growth in 0% NaCl Growth in 6% NaCl Utilization of D-Galactose D-Fructose Sucrose Maltose Lactose Succinate Fumarate Citrate S. algae Characteristic Table 9.11: Identification of Shewenella species (all are Gram-negative curved or straight rods, catalase and oxidase positive, motile and grow in 3% NaCl. Negative for arginine dehydrolase, lysine or ornithine decarboxylase and indole production) - - + - - - - - 4-15 25 20-22 15-17 25-35 25-30 25 + + + - + + + + + + + + + + + + + - - + + + + + D + (+) + + + d + + + - + + + - + + + - + + + - + + + (+) + (+) - + + + + + + - + - - + - Flavobacterium and related bacteria These bacteria are common specimen contaminants that rarely cause disease. The natural habitats of these bacteria are soil, plants, foodstuffs and water sources. Their taxonomy has not yet been fully resolved. They are usually penicillin and polymixin B resistant and most species produce yellow pigments. They are divided into different groups: Group A: Saccharolytic, indole positive. Includes F. meningosepticum, F. group IIb and F. breve. CDC groups IIe, IIh and IIi are similar, but produce no pigment. Group B: Asaccharolytic, indole negative. Includes F. odoratum. Group C: Saccharolytic, indole negative. Includes F. thalpophilum, F. mizutaii, Sphingobacterium multivorum and S. spiritivorum. Group D: Asacchyrolytic, indole positive. Weeksella. Since species that are isolated in a clinical setting, i.e. F. meningosepticum, F. group IIb and F. odoratum, can be resistant to a number of antibiotics i.e. beta-lactams, tetracyclines, amphenicols and aminoglycosides, it is essential that antimicrobial susceptibility tests be done. As there are usually 14 | P a g e Applied Veterinary Bacteriology and Mycology: Identification of aerobic and facultative anaerobic bacteria Chapter 9: Miscellaneous Gram-negative, non-fermentative bacilli errors in disk diffusion tests for this group MIC testing is recommended. These bacteria are often susceptible to the macrolides, potentiated sulphonamides and fluoroquinolones. APPENDIX 1 Smith-Baskerville Medium for Bordetella bronchiseptica (Smith and Baskerville 1979) Bacto Peptone 20g Sodium chloride 5g Agar 15g Distilled water 857ml The basal medium is autoclaved at 121°C for 15 minutes and then cooled to 55°C. The following supplementary solutions are mixed together and added to the cooled agar medium. Antimicrobial supplement: Gentamicin 0,5ug/ml Penicillin 20ug/ml Furaltadone 29ug/ml Carbohydrate supplement: Glucose (10%) 100ml Lactose (10%) 100ml Bromothymol blue solution (filter sterilised) 2% Stock solution Bromothymol blue 1g 0,1 N NaOH 25ml Distilled water 475ml Dilute to 0,2% solution 40ml 15 | P a g e
