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In the name of God Department Of Microbiology Yasouj University of Medical Science Enterobacteriacae identification By: Dr. S. S. Khoramrooz, Ph.D. Department of Microbiology, Faculty of Medicine, Yasuj University of Medical Sciences, Yasuj, Iran 1 Characters of Enterobacteriaceae • All Enterobacteriaceae • Gram-negative rods • Ferment glucose with acid production • Reduce nitrates into nitrites • Oxidase negative • Facultative anaerobic • Motile except Shigella and Klebsiella • Non-capsulated except Klebsiella • Non-fastidious • Grow on bile containing media (MacConkey agar) 2 Classification of Enterobacteriaceae Enterobacteriaceae Lactose fermenters E. coli, Citrobacter, Klebsiella, Enterobacter Non-lactose fermenter Salmonella, Shigella Proteus, Yersinia There are several selective and differential media used to isolate distinguishes between LF & LNF The most important media are: MacConkey agar Eosin Methylene Blue (EMB) agar Salmonella Shigella (SS) agar In addition to Kiligler Iron agar (KIA) 3 Tests To Know • Case Study Tests • Indole • Methyl Red/Voges Proskauer • Citrate • H2S production in SIM • Urea hydrolysis • Motility • Lactose fermentation • Glucose fermentation & gas production • Decarboxylation of amino acis • Fermentation of sugars • Reaction on selective media 4 Growth of Enterobacteriaceae on MacConkey agar Colorless colonies Pink colonies Uninoculated plate Lactose non feremters Lactose feremters Salmonella, Shigella, E. coli, Citrobacter Proteus Klebsiella, Enterobacter 5 Kligler Iron Agar Lactose Fermentation Glucose fermentation Gas Production (H2 & CO2 ) H2S Production 6 Kligler Iron Agar (KIA) glucose lactose Ferrous sulfate pH indicator: phenol red • Proteins 7 8 Red/Red Alkaline /Alkaline K/K Lactose -/Glucose – Yellow/Yellow Acid/Acid A/A Lactose +/Glucose + Red/Yellow K/A Lactose -/Glucose + Alkaline/Acid Gas Red/Yellow Alkaline/Acid K/A Lactose -/Glucose + Gas + Red/Yellow Alkaline/Acid Alkaline/Acid H2S - K/A Lactose -/Glucose + Gas - Red/Black H2S - H2S + K/A Lactose -/Glucose + Gas + H2S + 9 Result Reaction on KIA Butt color Red Slant color Red Example H2S Negative Negative Yellow Yellow Yellow Red Red Yellow Positive black in butt Negative Result Alk/Alk/(No action on sugars) A/Alk/(Glucose fermented without H2S) A/Alk/+ (Glucose fermented with H2S) A/A/(three sugars are fermented) Non fermenter e.g. Pseudomonas LNF e.g. Shigella LNF e.g. Salmonella & Proteus LF e.g. E. coli, Klebsiella, Enterobacter10 11 IMViC Test • Indole, Methyl Red, Voges-Prosakaur, Citrate (IMViC) Tests: • The following four tests comprise a series of important determinations that are collectively called the IMViC series of reactions • The IMViC series of reactions allows for the differentiation of the various members of Enterobacteriaceae. 12 IMViC: Indole test Principle Certain microorganisms can metabolize tryptophan by tryptophanase The enzymatic degradation leads to the formation of pyruvic acid, indole and ammonia The presence of indole is detected by addition of Kovac's reagent. Tryptophane amino acids Tryptophanase Indole + Pyurvic acid + NH3 Kovac’s Reagent Red color in upper organic layer` 13 IMViC: Indole test Result: A bright pink color in the top layer indicates the presence of indole The absence of color means that indole was not produced i.e. indole is negative Negative test e.g. Klebsiella Positive test e.g. E. coli Special Features: Used in the differentiation of genera and species. e.g. E. coli (+) from Klebsiella (-). 14 IMViC test Methyl Red-Voges Proskauer (MR-VP) Tests Principle Acidic pathway Mixed acids pH less than 4.4 Methyl Red indicator Red color Glucose Or Neutral pathway Acety methyl carbinol (ACETOIN) solution A solution B MR positive VP positive E. coli Klebsiella 15 Pink color Butylene Glycol Pathway of Glucose Fermentation • In the butylene glycol pathway • pyruvic acid to acetoin and butylene glycol. • Acetoin and butylene glycol are detected by oxidation to diacteyl at an alkaline pH. • and the addition of -naphthol which forms a red-colored complex with diacetyl. • Important biochemical property used for the identification of Klebsiella, Enterobacter, and Serratia. 16 Voges-Proskauer Reaction • Acetoin and butylene glycol are detected by oxidation to diacteyl at an alkaline pH, and the addition of -naphthol which forms a red-colored complex with diacetyl. • The production of acetoin and butylene glycol by glucose fermentation is an important biochemical property used for the identification of Klebsiella, Enterobacter, and Serratia. 17 IMViC test: MRVP test Method Inoculate the tested organism into MRVP broth Incubate the tubes at 37°C for 24 hours • For methyl red: Add 6-8 drops of methyl red reagent. • For Voges-Proskauer: Add 12 drops of solution A (-naphthol), mix, 4 drops of Solution B (40% KOH), mix 18 IMViC test: MR/VP test Results Methyl Red test Voges-Proskauer test Pink: Positive VP (Klebsiella) Red: Positive MR (E. coli) Yellow or orange: Negative MR (Klebsiella) No pink: Negative VP (E. coli) 19 Citrate Utilization Test Principle: Citrate Pyruvate Na2CO3 CO2 + Na + H2O Alkaline,↑pH Simmone’s Citrate media Contains Citrate as a sole of C source Positive test Blue colour Bromothymol blue Positive test: Klebsiella, Enterobacter, Citrobacter Negative test: E. coli 20 Citrate Utilization Test Method Streak a Simmon's Citrate agar slant with the organism Incubate at 37°C for 24 hours. 21 Citrate Utilization Test Result Examine for growth (+) Growth on the medium is accompanied by a rise in pH to change the medium from its initial green color to deep blue Positive Klebsiella, Enterobacter Negative E. coli 22 Principle Urease Test Urea agar contains urea and phenol red Urease is an enzyme that catalyzes the conversion of urea to CO2 and NH3 Ammonia combines with water to produce ammonium hydroxide, a strong base which ↑ pH of the medium. ↑ in the pH causes phenol red r to turn a deep pink. This is indicative of a positive reaction for urease Urea Urease CO2 + NH3 H2O NH4 OH ↑ in pH Phenol Red Method Streak a urea agar tube with the organism incubate at 37°C for 24 h Pink Positive test 23 Urease Test Result • If color of medium turns from yellow to pink indicates positive test. • Proteus give positive reaction after 4 h while Kelebsiella and Enterobacter gave positive results after 24 h Positive test Negative test 24 From Motility + left to right: – + 25 SIM Sulfide, Indole, Motility 7/16/2015 S. S. Khoramrooz 26 Phenylalanine Deaminase Reaction • Enterobacteriaceae utilize amino acids in a variety of ways including deamination. • Phenylalanine is an amino acid that forms the keto acid phenylpyruvic acid when deaminated. • Phenylpyruvic acid is detected by addition of ferric chloride that forms an intensely dark olive-green colored complex when binding to phenylpyruvic acid. • The deamination of phenylalanine is an important biochemical property of Proteus, Morganella, and Providencia. 28 Amino Acid Decarboxylation • Enterobacteriaceae contain decarboxylases with substrate specificity for amino acids, and are detected using Moeller decarboxylase broth overlayed with mineral oil for anaerobiosis. • Moeller broth contains glucose for fermentation, peptone and beef extract, an amino acid, pyridoxal, and the pH indicator bromcresol purple. 29 Amino Acid Decarboxylation • If an Enterobacteriaceae contains amino acid decarboxylase, amines produced by decarboxylase action cause an alkaline pH, and bromcresol purple turns purple. • Lysine, ornithine, and arginine are utilized. • A base broth without amino acid is included in which glucose fermentation acidifies the broth, turning the bromcresol purple yellow. 30 Amino Acid Decarboxylation1 Lysine → Cadaverine Ornithine → Putrescine Arginine → Citrulline → Ornithine → Putrescine 1Conversion of arginine to citrulline is a dihydrolase reaction 31 Amino Acid Decarboxylation • Decarboxylation patterns are essential for the genus identification of Klebsiella, Enterobacter, Escherichia, and Salmonella. • Decarboxylation patterns are also essential for the species identification of Enterobacter aerogenes, Enterobacter cloacae, Proteus mirabilis, and Shigella sonnei. 32 Amino Acid Decarboxylation Lys Orn Arg Klebsiella + – – Enterobacter +/– + +/– Escherichia + +/– –/+ Salmonella + + + 33 Amino Acid Decarboxylation Lys Orn Arg E. aerogenes + + – E. cloacae – + + P. mirabilis – + – P. vulgaris – – – Shigella D – + – Shigella A-C – – – 34 IPViC Reactions for Initial Grouping of the Enterobacteriaceae • Indole • Phenylalanine deaminase • Voges-Proskauer • Citrate 35 Initial Grouping of the Enterobacteriaceae (VP=Voges Proskauer, PDA=Phenylalanine Deaminase) GENERA VP PDA Klebsiella POSITIVE NEGATIVE Enterobacter POSITIVE NEGATIVE Serratia POSITIVE NEGATIVE Hafnia POSITIVE NEGATIVE Pantoea POSITIVE NEGATIVE 36 Initial Grouping of the Enterobacteriaceae GENERA VP PDA Proteus NEGATIVE POSITIVE Morganella NEGATIVE POSITIVE Providencia NEGATIVE POSITIVE 1 1 Proteus mirabilis: 50% of strains VP positive 37 Initial Grouping of the Enterobacteriaceae GENERA Escherichia Shigella Edwardsiella Salmonella Citrobacter Yersinia VP NEGATIVE NEGATIVE NEGATIVE NEGATIVE NEGATIVE NEGATIVE PDA NEGATIVE NEGATIVE NEGATIVE NEGATIVE NEGATIVE NEGATIVE 38 Initial Grouping of the Enterobacteriaceae1 GENERA INDOLE CITRATE Escherichia POSITIVE NEGATIVE Shigella POSITIVE2 Yersinia POSITIVE3 Edwardsiella POSTIVE NEGATIVE NEGATIVE NEGATIVE 1 VP negative, PDA negative 2 Shigella groups A, B, and C variably positive for indole production (25-50%), group D Shigella negative. 3 Yersinia enterocolitica 50% positive 39 Initial Grouping of the Enterobacteriaceae1 GENERA Salmonella Citrobacter INDOLE NEGATIVE NEGATIVE CITRATE 2 POSITIVE POSITIVE 1 VP negative, PDA negative 2 Salmonella serotype Paratyphi A and Typhi negative 40 Key Characteristics of the Enterobacteriaceae TSI E A/A coli Shi AC Shi D Ed Sal Cit Ak/ A Ak/ A Ak/ A Ak/ A A/A Ak/ A Yer A/A ON GAS H2S VP IND CIT PDA UR MO LYS OR AR / + + + + + + / + +/ + + + + +/ + + + + + + + + (1) RT=room temperature + + + + +/ + + + +/ +/ / + + +/ RT (1) + 41 Key Characteristics of the Enterobacteriaceae Kle pne Kle oxy En aer En cloa Serr (1) Haf TSI ON GAS H2S VP A/A + + + + + + + + + + + + + A/A A/A A/A A/A Ak/ A Pan A/A Alk/ A /+ + + + + + + IND CIT PDA UR + + + + + + +/ /+ +/ /+ MO LYS OR AR + + + + + + + +/ + + + + + + + + + /+ (1) Produces DNase, lipase, and gelatinase 42 Key Characteristics of the Enterobacteriaceae Prot mir a Prot vulg Mor Pro v GAS H2S VP IND CIT PDA UR MO LYS OR AR TSI ON Ak/ A + + A/A +/ + + /+ + + +s + + + + + + + + + + + Ak/ A Ak/ A +/ +/ + + +s + s = swarming motility 43 Biochemical Characteristics of Escherichia coli and Shiglla TSI Lactose ONPG Sorbitol Indole Methyl red VP Citrate Lysine Motility 1Shigella E. coli A/Ag + + + + + – – + + E. coli O157:H7 A/Ag + + – + + – – + + Shigella Alk/A – –/+1 +/– +/– + – – – – sonnei (group D) ONPG + 44 Biochemical Characteristics of Salmonella TSI H2S (TSI) Citrate Lysine Ornithine Dulcitol Rhamnose Indole Methyl red VP Most Serotypes Alk/A + + + + + + – + – Typhi Alk/A + (weak) – + – – – – + – Paratyphi A Alk/A – – – + + + – + – 45 Xylose Lysine Deoxycholate (XLD) Agar: Composition • • • • • • • • • • • • Xylose Lysine Lactose Sucrose Sodium chloride Yeast extract Sodium deoxycholate Sodium thiosulfate Ferric ammonium citrate Agar Phenol red pH = 7.4 0.35% 0.5% 0.75% 0.75% 0.5% 0.3% 0.25% 1.35% XLD Agar: Growth of Salmonella • Salmonella selective due to bile salt. • Xylose fermentation (except Salmonella serotype Paratyphi A) acidifies agar activating lysine decarboxylase. – With xylose depletion fermentation ceases, and colonies of Salmonella (except S. Paratyphi A) alkalinize the agar due to amines from lysine decarboxylation. • Xylose fermentation provides H+ for H2S production (except S. Paratyphi A). XLD Agar: Appearance of Salmonella • Ferric ammonium citrate present in XLD agar reacts with H2S gas and forms black precipitates within colonies of Salmonella. • Agar becomes red-purple due to alkaline pH produced by amines. • Back colonies growing on red-purple agar-presumptive for Salmonella. XLD Agar: Growth of Escherichia coli and Klebsiella pneumoniae Escherichia coli and Klebsiella pneumoniae are lysine-positive coliforms that are also lactose and sucrose fermenters. The high lactose and sucrose concentrations result in strong acid production, which quenches amines roduced by lysine decarboxylation. Colonies and agar appear bright yellow. Neither Escherichia coli nor Klebsiella pneumoniae produce H2S. XLD Agar: Growth of Shigella and Proteus Shigella species do not ferment xylose, lactose, and sucrose, do not decarboxylate lysine, and do not produce H2S. Colonies appear colorless. Proteus mirabilis ferments xylose, and thereby provides H+ for H2S production. Colonies appear black on an agar unchanged in color (Proteus deaminates rather than decarboxylates amino acids). Proteus vulgaris ferments sucrose, and colonies appear black on a yellow agar. Hektoen Enteric (HE) Agar: Composition • • • • • • • • • • • • Peptone Yeast extract Bile salts Lactose Sucrose Salicin Sodium chloride Ferric ammonium citrate Acid fuchsin Thymol blue Agar pH = 7.6 1.2% 0.3% 0.9% 1.2% 1.2% 0.2% 0.5% 1.4% HE Agar: Growth of Enteric Pathogens and Commensals • High bile salt concentration inhibits growth of grampositive and gram-negative intestinal commensals, and thereby selects for pathogenic Salmonella (bile-resistant growth) present in fecal specimens. • Salmonella species as non-lactose and non-sucrose fermenters that produce H2S form colorless colonies with black centers. • Shigella species (non-lactose and non-sucrose fermenters, no H2S production) form colorless colonies. • Lactose and sucrose fermenters (E. coli, K. pneumoniae) form orange to yellow colonies due to acid production. 58 Pseudomonas aeruginosa Some strains appear mucoid Particularly common in patients with cystic fibrosis Some strains produce diffusible pigments Pyocyanin [blue] Fluorescein [yellow] Pyorubin [redbrown] 59 Laboratory Diagnosis Culture Grow easily on common isolation media such as blood agar and MacConkey 37-42C Identification The colonial morphology (e.g., colony size, hemolytic activity, pigmentation, odor) + Biochemical tests (e.g., positive oxidase reaction) 60 61 62 The End 63