BIOL 2010 Lecture 9: Identification Methods for Enterobacteriaceae

Summary

Lecture notes covering the identification methods for Enterobacteriaceae, including various agars and biochemical tests. The lecture introduces common Enterobacteriaceae, explains their characteristics, and discusses crucial identification methods. These notes are useful for understanding and practicing the techniques in clinical microbiology.

Full Transcript

BIOL 2010
Lecture 9 – Overview of identification
methods for Enterobacteriaceae
BAILEY AND SCOT T’S – CHAPTER 12, 19
DIAGNOSTIC MICROBIOLOGY – CHAPTER 9, 19
In this lecture
Introduction to Enterobacteriaceae
Common ID methods for Enterobacteriaceae
Special media
Tests
Test systems
Enterobacteriaceae
The family Enterobacteriaceae (also called enterics) includes many
genera and species.
Clinical isolates in acute-care settings consist PRIMARILY of three
organisms:
Escherichia coli
Klebsiella pneumonia
Proteus mirabilis
Bacterial
Species and
the
Infections
They
Commonly
Produce
Clinical Significance
Two major types
Opportunistic pathogens (This lecture)
Normal flora
Infections in other “nonnormal” sites
Ex. E. coli is normal in the gut, but can cause, septicemia, wounds, urinary tract infections
(UTIs), meningitis
Primary pathogens (i.e. ALWAYS pathogen)
Salmonella spp.
Shigella spp.
Yersinia spp.
 Clinical Significance – another way to
look at it
Opportunistic Pathogens Pathogens
Escherichia Salmonella
Klebsiella Shigella
Enterobacter Yersinia
Serratia Pathogenic E. coli
Citrobacter
Proteus
Morganella
Providencia
General Characteristics of ALL
Enterobacteriaceae
All ferment glucose
All reduce nitrate to nitrites
All are oxidase negative
Motility
All motile at body temperature except
Klebsiella
Shigella
Yersinia
Key Characteristics of the Family
Enterobacteriaceae

COPYRIGHT © 2015 BY
Copyright SAUNDERS,
© 2019 ANInc.
by Elsevier IMPRINT OFreserved.
All rights ELSEVIER INC.
Enterobacteriaceae – ID
Cellular morphology: Gram-negative coccobacilli or straight rods
Not very useful in identification other than ruling out other organisms

Growth conditions: Facultatively anaerobic
Molecular methods: modern methods
Culture**
Macroscopic morphology on BAP
Not very useful in identification other than ruling out other organisms
Large moist, gray colonies - some can be mucoid
Selective plates are utilized to ID pathogenic species in stool specimens.
MacConkey Agar
Enterobacteriaceae grow on MAC and
serve as first point for ID
Review of MacConkey (MAC) agar
Selective and differential
Bile salts and crystal violet inhibit gram-positive
Lactose fermentation is differential.
Colonies can be
LF or Lactose fermenters (Pink) - A
NLF or Non-Lactose Fermenters (Yellow) – B
LLF or Late Lactose Fermenters – these are NLF
at 24h, but become LF at 48h
 Lactose Non-Lactose
Fermenters Fermenters
1.Escherichia 1.Shigella **
2.Klebsiella 2.Citrobacter
3.Enterobacter (LLF)
4.Serratia 3.Salmonella
(LLF) **
4.Proteus
5.Providencia
6.Morganella
7.Yersinia **
EMB Agar
Eosin-methylene blue (EMB) agar
Selective and differential
Methylene blue inhibits gram-positive.
Lactose and sucrose fermentation is
differential.
Hektoen Enteric Agar
Media designed for Salmonella/Shigella
Hektoen enteric (HE) agar A
Selective and differential B
Bile salts inhibit gram-positive, some gram-negative.
Lactose and sucrose fermentation is differential.

Colonial morphology
Orange color (lactose fermentation, low pH). =
nonpathogens (A)
Blue green color = target pathogen
Salmonella will produce H2S and have a black center C
(B)
Shigella will NOT produce H2S and appear blue
green (C)
Xylose Lysine Deoxycholate Agar
Another media designed for Salmonella/Shigella
Xylose lysine deoxycholate (XLD) agar
Selective (less so than MAC and HE) and differential
Sodium deoxycholate
Inhibits gram-positive, some gram-negative
Three carbohydrates, sucrose and lactose in excess, and xylose with a phenol red
indicator
Lysine present to detect lysine decarboxylation
Thiosulfate present to detect hydrogen sulfide (H2S)
Xylose Lysine Deoxycholate Agar
Colonial morphology
Yellow colonies = nonpathogens (A)
Fermenters or those not producing lysine
decarboxylase Escherichia coli, Citrobacter A B
Red colonies with black centers = target
pathogen (B)
Initially yellow then revert to red
When lysine is decarboxylated, causing
alkaline pH
Salmonella
C
Colorless or red colonies = target
pathogen (C)
Shigella
Salmonella Shigella Agar
SS agar designed to isolate and differentiate Salmonella and Shigella
Selective ingredients
Bile salts, sodium citrate, and brilliant green
Inhibit gram-positive organisms and some lactose-fermenting, gram-negative rods
normally found in the stool.
Differential ingredients
Lactose and neutral red
Sodium thiosulfate, ferric ammonium citrate
Salmonella Shigella Agar
Colonial morphology
Lactose fermenters (pink) = non- A
B
pathogens (A)
Non-Lactose Fermenters (Colorless) =
pathogens
Colorless with black center = Salmonella
(B)
Colorless = Shigella (C)
(Note: Not all Shigella grow on SS) C
CIN media
Cefsulodin, irgasan, novobiocin media
Designed to isolate Yersinia spp.
Inhibitory agents: incorporates
cefsulodin, irgasan, novobiocin, bile
salts, and crystal violet
MAC selective agents plus antimicrobials
Inhibits normal intestinal microbiota

Differential ingredient: mannitol with
phenol red
Many formulations of agar available
CIN media
Presentations:
Mannitol fermenters
Decrease in pH around colony due to mannitol
fermentation = causes phenol red to turn red
Bile precipitates in the middle of the colony
Bullseye colonies (image)

Mannitol non-fermenters are translucent,
colorless
Selenite Broth
Selective inhibition of gram-positive and many gram-negative organisms.
Selective enrichment for the growth of Salmonella spp.
Some Shigella also grow

Useful if Salmonella is in small numbers in stool
Procedure generally involves incubating sample in Sel broth for 16-20
hours, then subculturing on another selective/differential media
Other media for Salmonella
Brilliant Green Agar
Selective ingredients: Brilliant Green, which is inhibitory to
most gram-positive and gram-negative bacteria
Salmonella grow as white to pink or red colonies surrounded
by a bright halo (Top image)
Bismuth Sulfite Agar
Selective ingredients: Bismuth and Brilliant Green
Salmonella grow as black colonies (Bottom image)
May inhibit some Salmonella strains though
Enterobacteriaceae - Biochemical tests
Oxidase (Note all should be neg) Urea
TSI (Screening test) Deaminase
ONPG Indole
Decarboxylase (Adenine, Lysine, VP
Ornithine) Gelatin
Citrate
Sugar fermentation
H2S
*We will learn about these using API
Lysine Iron Agar (LIA) and TSI
Screening
Identification
Determine if Enterobacteriaceae
Gram-negative
Oxidase negative
Except for Plesiomonas shigelloides
Always use young colonies from sheep blood agar (SBA) plates
Ferment glucose
Reduce nitrate to nitrite
Serologic Grouping
Serologic grouping
Salmonella
60 types of O antigens
95% are serogroups A through E1
Direct or latex agglutination tests for serogroup
Shigella
A through D serogroups
Historical Methodologies
HISTORICAL METHODOLOGIES CURRENT METHODOLOGIES

Biochemical testing Newer technology available: matrix-
Based on phenotypic characteristics assisted laser desorption–ionization-
time-of-flight mass spectrometry
o Miniaturized multitest systems
(MALDI-TOF MS)
Serotyping (a.k.a., serogrouping) Based on characterization of microbial
proteins
Use of antibodies to detect specific
antigens located on the bacterial Molecular biology
surface Based on genotype, nucleic acid sequences
o Highly sensitive, specific, and rapid,
providing accurate results in a few hours
or less

26
Traditional biochemical tests
Carbohydrate Amino Acid Miscellaneous
utilization Utilization tests
ONPG Decarboxylase Citrate
Lactose utilization Dihydrolase DNAse
OF Lysine Iron Agar Indole
Glucose Deaminase MIO
fermentation Nitrate
TSI Oxidase
MRVP Urease
Oxidase Test - review
Purpose
Determines the presence of cytochrome oxidase activity for oxidase-negative enteric bacteria
from other gram-negative rods
Gram negative identification should start here

Principle
Determines the presence of cytochrome oxidase using tetramethyl-p-phenylenediamine
dihydrochloride to indophenol (bluish-purple)
Limitation
Nickel-base alloy wires that contain chromium and iron may cause a false-positive result
Oxidase Test - review
Results
Positive: Purple within 60s (A)
Negative: NO purple – colony may stay colorless or
pink (B)
Quality control
Positive—P. aeruginosa
Negative—E. coli
Lactose Utilization
The most important carbohydrate determination
Can be used to differentiate lactose fermenting (LF) bacterial species from
nonlactose fermenters (NLFs)
Lactose is a disaccharide bond consisting of glucose and galactose connected by a
galactoside bond.
An enzyme degrades lactose into glucose and galactose – hence glucose becomes
available for metabolism.

What is a common way to test this? (Hint: Media)

30
Lactose Degradation
Requires two enzymes
β-galactoside permease
Transports lactose through the cell wall
β-galactosidase
Breaks lactose to yield subunits

Some bacterial species lack permease but
have β-galactosidase.
Known as late or delayed LFs

31
ONPG Test
Purpose of test
To determine if an organism found to be a dLF (one that lacks the enzyme β-
galactoside permease but possesses β-galactosidase) is a true NLF
Principle
Substrate is Ortho-Nitrophenyl-β-D-Galactopyranoside
ONPG is structurally similar to lactose, but ONPG is more readily transported through
the bacterial plasma membrane.
Therefore NO permease enzyme required.
Simply tests for B-galactosidase enzyme
β-galactosidase hydrolyzes ONPG into Galactose and O-nitrophenol (Yellow color)

32
 ONPG Test
Steps to perform ONPG Test
Make a heavy suspension of bacteria in sterile saline.
Add ONPG disk/tablet.
Incubate at 35° C.
Positive results usually seen within 6 hours
Results
Positive: Yellow
Negative: Clear

Limitations:
Yellow pigment producing bacteria should not be tested
because of potential false-positive results.

33
Two Pathways of Glucose Metabolism

34
Glucose fermentation tests
Oxygen is not required
Glycolysis pathway
Glucose to pyruvate
Oxidized to other acid products and gases

Acid is detected by pH indicators.
Remember CTA sugars?

35
Oxidation–Fermentation (O/F) Tests
Bacterial sugar utilization patterns
Oxidation
Utilize carbohydrates aerobically
Produce weak acids
Ex. OF test with high sugar content
Fermentation
Utilize carbohydrates anaerobically
Strong acid producer
Ex. CTA sugar with lower sugar content
Asaccharolytic
Do not utilize carbohydrates

36
O/F Basal Media (OFBM)
Lower concentration of peptones
Help classify as oxidizer or fermenter
Detects small amounts of acids
Contents
pH indicator is bromothymol blue.
Uninoculated is green.
Acid pH is yellow.
Alkaline pH is blue.

37
O/F Basal Media (OFBM)
Uses two tubes
Tube #1 is Aerobic
Aerobic: only open tube produces acid
(oxidizer)
Tube #2 is Anaerobic (overlaid with
sterile mineral oil)
Anaerobic: only closed tube produces acid
(fermenter)
Facultative: both tubes produce acid (both)

38
O/F Basal Media (OFBM)
Organism 1
Both are yellow = sugar is being used with
and without oxygen
Organism is a fermenter

Organism 2
Only the tube exposed to air is yellow =
sugar is only being used with oxygen
Organism is an oxidizer

Organism 3
NO tube is yellow – sugar is not utilized,
and organism is asaccharolytic

39
Triple Sugar Iron Agar (TSI)
Media and Principle
TRIPLE sugars: sucrose, glucose, and lactose
Lactose and sucrose present in 10:1 ratio to glucose.
Kligler iron agar (KIA) is similar but no sucrose.
Ferrous sulfate and sodium thiosulfate
Detect production of hydrogen sulfide (H2S) as a black color
Phenol red Indicator
Below 6.8 yellow (acidic)
Above 6.8 red (alkaline)
Reaction chambers
Slant is aerobic.
Butt is anaerobic.

40
Triple Sugar Iron Agar (TSI)
Purpose
Determines whether a gram-negative rod ferments glucose and
lactose or sucrose and forms hydrogen sulfide
Principle
Triple sugar iron (TSI) agar contains 10 parts lactose; 10 parts
sucrose;1 part glucose and peptone; and ferrous sulfate
Butt of tube turns yellow if glucose is fermented (acid)
Slant of tube turns yellow if lactose or sucrose are fermented (acid)
Tubes turns black if hydrogen sulfide is produced
Gas formation results in bubbles or breaking of the agar

41
TSI - results
Lactose or sucrose (or both) fermentation
A/A after using glucose then use lactose or sucrose
Both stay yellow

Hydrogen sulfide Production
Black precipitate – can mask acid reaction
Acid from bacteria + sodium thiosulfate H2S gas + ferric ions ferrous sulfide (black
ppt)
Gas production
Bubbles or splitting of media is due to gas generated.

42
TSI - reactions
Examples
A: A/A, Gas
B: K/A, Gas, H2S
C: K/K
D: K/K

43
TSI - reactions

44
Examples of TSI Reactions

45
Glucose Metabolism
Occurs via the Embden–Meyerhof pathway
Produces several intermediate by-products, including pyruvic acid
Further degradation of pyruvic acid can produce mixed acids as end products.
Enterics take two separate pathways
Mixed acid fermentation
Butylene glycol pathway
The methyl red (MR) and Voges–Proskauer (VP) test detect end products of
glucose fermentation.
One broth including glucose inoculated, then separated into two tubes
One tube = MR test
Second tube = VP test

46
MR test
Principle
Detects mixed acids pathway
Test read directly after incubation

Results
Negative: MR-negative cultures remain
yellow after addition of the pH indicator (pH
6.0).
Positive: Glucose pyruvic acid mixed acid
ferm pH 4.4 red color with MR (positive test)
VP test
Principle
Tests butylene glycol pathway products (acetoin and glycol)
MUST add reagents first, then gently shake tube to increase
oxygenation.
α-naphthol which serves as a catalyst/color intensifier.
Add 40% potassium hydroxide (KOH) or sodium hydroxide
(NaOH).

Results
Positive: Produces butylene glycol and acetoin, which is further
converted to diacetyl
Diacetyl + KOH + -naphthol red complex
Negative: NO Diacetyl to react with reagents, colorless
Decarboxylase and Dihydrolase Tests
Purpose
This test is used to differentiate decarboxylase-producing Enterobacterales from other
gram-negative rods
Decarboxylase principle
Test the presence of enzymes capable of removing carboxyl group (COOH)
Specific for amino acids
 Lysine, ornithine, arginine
Lysine lysine decarboxylase cadaverine + CO2
Ornithine Ornithine decarboxylase putrescine + urea

Dihydrolase principle
Arginine arginine dihydrolase citrulline ornithine putrescine

49
Decarboxylase and Dihydrolase Tests
(Moeller’s) Broth medium used to detect decarboxylation
Contains glucose, peptones
pH indicators
Bromocresol purple
Cresol red
Specific amino acid at a concentration of 1%
Overlay with oil
Initial pH of 6.0
Un-incoulated media is yellow

50
Decarboxylase and Dihydrolase Tests
Results
Positive: If amino acid is broken down, amines
cause an alkaline pH shift, causing a purple
color
Negative: If color remains yellow.
Note: Two conditions must be met for
decarboxylation to occur.
An acid pH
An anaerobic environment (hence the oil overlay)
A control tube is usually inoculated

51
Phenylalanine Deaminase Test
Purpose:
This test is used to determine the ability of an organism to oxidatively deaminate
phenylalanine to phenylpyruvic acid. The genera Morganella, Proteus, and
Providencia are positive.

Principle
Microorganisms that produce phenylalanine deaminase remove the amine (NH2)
from phenylalanine.
The reaction results in the production of ammonia (NH3) and phenylpyruvic acid.
The phenylpyruvic acid is detected by adding a few drops of 10% ferric chloride; a
green-colored complex is formed between these two compounds.

Results:
MUST add 10% ferric chloride
Positive: Green
Negative: colorless

52
Tryptophan Deaminase Test
Purpose:
This test is used to determine the ability of an organism to
oxidatively deaminate Tryptophan
Most strains of E. coli, P. vulgaris, P. rettgeri, M. morgani and
Providencia are positive
Principle
Microorganisms that produce tryptophanase remove the amine
(NH2) from tryptophan to produce indole, pyruvic acid,
ammonium.
Results:
Positive: Reddish brown
Negative: LIGHT brown (can sometimes be confusing)

53
 Citrate Utilization
Purpose
Citrate test determines whether an organism can use sodium citrate as a sole carbon
source.

Principle
Use of citrate results in an alkaline pH.
Media is green when uninoculated. It is inoculated with a light inoculum
Too heavy = organisms will die and become source of carbon
Incubate in aerobic conditions

Limitations:
Some organisms are capable of growth on citrate and do not produce a color change -
Growth is considered a positive

Results
Positive: blue
Negative: Green

54
 Indole
Purpose
This test is used to identify organisms that produce the enzyme
tryptophanase

Principle
Organisms that possess tryptophanase can deaminate tryptophan
resulting in indole.

Bacteria are inoculated into tryptophan or peptone broth and
incubated for 48 hours before indole testing can be done.
Result is based on reagent used
Ehrlich’s reagent (more sensitive) = red is positive
Kovac’s reagent = red is positive
Spot indole (quick, done on filter paper with DMACA reagent) = blue
is positive
(Bottom image)

55
Motility-Indole-Ornithine (MIO) Agar
MIO agar
Semi-solid
Used to detect Motility and Indole and Ornithine decarboxylase production
Useful in differentiation Klebsiella spp. from Enterobacter and Serratia spp.

Results
Positive Motility is shown by a clouding or medium or spreading growth from the
inoculation line.
Positive Ornithine decarboxylation is indicated by a purple color throughout
medium.
Positive Indole is detected by adding Kovac’s reagent.
Pink to red color in reagent area is positive test.

56
Nitrate and Nitrite Reduction
Purpose
Determines whether an organism can reduce nitrites

Principle
Microorganisms capable of reducing nitrite to nitrogen will not turn a color and will
produce gas in the nitrate reduction (nitrate to nitrite) test
Limitation
Zinc dust is added if broth does not become red or no gas is observed

Quality control
Positive—Proteus mirabilis (ATCC 12453); colorless gas
Negative—Acinetobacter baumannii (ATCC 19606); red, no gas

57
 Urease (Christensen’s)
Purpose
This test is used to determine an organism’s ability to produce the enzyme urease, which
hydrolyzes urea.
Proteus spp. may be presumptively identified by the ability to rapidly hydrolyze urea.

Principle
Urea is the product of decarboxylation of amino acids.
Hydrolysis of urea produces ammonia and CO2. The formation of ammonia alkalinizes
the medium, causing a pH shift.

Limitations
False positive can occur upon prolonged incubation

Result
Positive: BRIGHT pink (right)
Negative: light yellow (left)
Quick note about IMVIC Test
Stands for
Indole
Methyl Red
Voges Proskauer
Citrate
Quick panel of tests to screen for organisms, Examples:

I MR VP C
E. coli + + - -
K. pneumoniae - - + +
 Multi-test systems
Microbial ID methods fall into one of five categories (or combination):
Methods can be manual or automated
System Pure Examples
culture
required
1. pH-based Yes Analytical Profile Index (API) – manual method
2. Enzyme profile No Microscan rapid panels
3. Carbon Yes Color change based on transfer of electrons to colorless
utilization indicator Ex. Biolog
4. Visual Yes Measurement of turbdity ex. MicroScan
detection
5. Molecular Yes MALDI-TOF – protein patterns
assays – include No PCR – DNA materials
characterization of
molecules like fatty Yes Immunoassay
Analytical Profile Index (API)
Released in 1970
System for the identification of gram-negative fermentative bacteria (the
family Enterobacteriaceae) is called API 20E.
API 20E system highlights
Consists of 20 cupules attached to plastic strip each with a specific lyophilized, pH-
based substrate (miniaturized versions of biochemical tests we just discussed)
A liquid bacterial suspension is used to rehydrate the cupules.

61
API 20E - example
API 20E System Highlights
Inoculation
Prepare a bacterial suspension and inoculate all cupules
Some cupules require mineral oil overlay.
Principles of the tests are the same for similar tests performed in test tubes.
Strip is incubated for 18 to 24 hours.
Interpretation (AFTER incubation)
Reagents are added to some cupules, as appropriate
Results are recorded and a 7-digit code profile number is determined.
The code profile number is checked against a database provided by manufacturer for
identification.
Results = organism ID, with a confidence score
Additional testing may be needed.

63
Rapid identification systems
Traditional methods to ID require growth and isolation of bacteria – this
could take days, maybe weeks
Why would this be an issue?

Rapid identification systems (since the 1970s) aim to get ID quicker in
comparison to traditional method
The phrase “rapid method” is quite loose, and encompasses a wide
variety of procedures and techniques
For example, a 3-hour enzyme immunoassay method to detect Clostridioides difficile
toxin is rapid compared with a 48-hour cell culture cytotoxicity assay.
Rapid
identificati
on system
-
Examples
Automated Identification Systems
Examples
MicroScan System
TREK Diagnostic System
Vitek 2 System
BD Phoenix Automated Microbiology System
Biolog OmniLog ID System
Sherlock Microbial Identification System

66
Evaluation of Identification Systems
Compare side by side to current methods of reference procedures.
Test
Accuracy
Cost effectiveness
Work flow

Systems can provide decreased sensitivity or specificity for some
bacteria.
Usually supplemental and differential media and biochemicals will still need to be kept
on hand.

67
Knowledge Check
Which of the following tests detects the production of mixed acids from
glucose because of subsequent metabolism of pyruvate?
a. Methyl red test
b. Voges-Proskauer test
c. Citrate test
d. Indole test
Knowledge Check
A gram-negative bacillus that produces an acid slant and acid butt on
triple sugar iron agar can ferment which of the following carbohydrates?
a. Glucose only
b. Glucose and lactose or sucrose or both
c. Lactose only
d. Lactose and sucrose, but not glucose
Knowledge Check
Tryptophan broth is inoculated and incubated 24 hours. After incubation,
Kovac’s reagent is added. A red color develops at the surface of the broth.
Which product of metabolism was formed?
a. Mixed acids
b. H2S
c. Phenylpyruvate
d. Indole
Knowledge Check
Indole-positive bacteria:
a. Produce tryptophanase
b. Deaminate lysine
c. Decarboxylate tryptophane
d. Decarboxylate ornithine
Knowledge Check
What type of ID method is employed by the API system?
a. Immunoassay
b. Enzyme characterization
c. Carbohydrate utilization and pH
d. Molecular methods
Knowledge Check
What do black colonies on XLD agar indicate?
a. Shigella
b. E. coli
c. Salmonella
d. Non-pathogenic Enterobacteriaceae
Knowledge Check
What do orange colonies on HEK agar indicate?
a. Shigella
b. E. coli
c. Salmonella
d. Non-pathogenic Enterobacteriaceae
Knowledge Check
Most pathogenic Enterobacteriaceae are
a. Lactose fermenters on MAC
b. Non-Lactose Fermenters on MAC
c. Alpha hemolytic on BAP
d. Pink on XLD
Knowledge Check
Pink (lactose fermenting) colonies on SS agar could be:
a. Salmonella
b. Shigella.
c. E. coli
d. All of the above