Biochemical Study of E. Coli PDF

Summary

This document details the biochemical study of E. coli, covering various aspects including microbiology, diseases, and laboratory tests for the identification of E. coli. It summarizes the techniques and analysis with additional information related to different bacteria.

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MICROBIOLOGY AND PARASITOLOGY

BIOCHEMICAL STUDY OF E.COLI
Dr. Olive Grace G. Tolentino, M.D. | Oct. 23, 2024

OUTLINE Sepsis
I. Enterobacteriaceae group Blood: entry of E.coli will cause sepsis especially in
A. Escherichia coli immunocompromised individuals like neonates
II. Diseases caused by E.coli → often the major clone associated is E. coli O25b/ST131
III. E.coli associated diarrheal
diseases
IV. Culture medium: Meningitis
MacConkey agar Meninges: caused by strains of E.coli having K1 antigen
V. Biochemical testing
(K) = capsular antigen
I. Enterobacteriaceae group
Most common group of Gram negative rods cultured in
clinical laboratories III. E. coli associated diarrheal diseases
Can reduce nitrate to nitrite
Natural habitat: intestinal tract of humans and animals Enteropathogenic E. coli Severe water diarrhea in
Motile/nonmotile: either motile (E.coli) with peritrichous (EPEC) infants
flagella, or nonmotile (Shigella and Klebsiella)
Growth in medium: grow well on Mac-Conkey agar Mechanism: Due to adherence
Facultative anaerobes: ferment rather than oxidize of EPEC to the mucosa and
glucose, often with gas production flattening the villi
Catalase: positive
Cytochrome oxidase: negative
Complex antigenic structure Enterotoxigenic E. coli Travellers diarrhea
Produce variety of toxins and virulence factors that (ETEC)
can successfuly cause many diseases Mechanism: Due due ETEC
Differentiated to species level by Biochemical tests producing two toxins:

Examples: Heat labile toxin (LT)
Escherichia, Shigella, Salmonella, Enterobacter, Proteus, Heat-stable toxin (ST)
Yersinia etc.

Enteroinvasive E. coli diseases similar to Shigellosis
A. Escherichia coli (EIEC)
Mechanism: Due to invasion of
the lining

Enteroaggregative E. coli Acute and Chronic diarrhea
(EAEC)
-persistent diarrhea in patients
with HIV
Chronic: more than 14 days

Mechanism: Unknown

Shiga toxin-producing E. coli Mild non-bloody diarrhea,
(STEC) hemorrhagic colitis,
hemolytic uremic syndrome

Mechanism: Due to production
Morphology: Gram negative bacilli
of toxins:
Motile due to presence of Peritrichous flagella
Complex antigenic structure
Shiga-like toxin 1
→ Capsule (K) antigen
Shiga-like toxin 2
→ LPS (O) or Somatic (O) antigen
→ Fimbriae (F) antigen
O157:H7 (most common strain)
Produce toxins

Diseases caused by E.coli (NOTE: “Maask ni siguro sa
mga lecture exams” -DOC T)
Manifestation of E.coli will depend on the site

A. Urinary Tract Infection (UTI)
Urinary tract: E.coli is the most common cause of UTI in
90% of women
→ Caused by certain O serotypes
→ strains have pili that help them adhere to specific
receptors on the urinary tract epithelium

Transcribed by: NMD 2027
 Biochemical study of E.coli
Lactose Fermenting Strains
IV. Culture Medium: MacConkey agar → Pink
→ Production of acid from lactose: Neutral red
▪ = color change of the dye when the pH is below 6.8

Lactose Non-Fermenting Strains
→ Colorless and transparent

MAC: Growth pattern of some
Enterobacteriaceae

Selective and Differential
→ Enterobacteriaceae group grow well in MacConkey
agar because this medium is selective for gram
negative organisms and most gram negative
organisms’ morphology are rods (bacilli)

Bile salts and Crystal violet
→ inhibit the growth of Gram positive organisms
Lactose fermenter, Lactose fermenter, Non-Lactose fermenter
Lactose
→ provides a source of fermentable carbohydrate,
allowing for differentiation
LACTOSE FERMENTATION
→ lactose will be added into the medium because it will
provide a source of fermentable carbohydrates which Lactose fermenters
some organisms can ferment and cannot ferment → B-galactoside permease - transport protein in the wall
that will facilitate the fast entry of the lactose into the
pH indicator: Neutral red cell.
→ turns pink at pH 6.8
Late or Delayed lactose fermenters
→ B-galactosidase only

How to detect fermentation in Mac? “If the transport of lactose does not have the permease
enzyme they can only absorb slowly. So that's why they are
“carbohydrate fermentation in most of your bacteria, they slow or delayed lactose fermenter or late lactose fermenter”
will produce acid and gas, your CO2 and hydrogen. So - DOC T
carbohydrate fermentation releases acid, for example
lactose fermentation - lactic acid, which will decrease the Non-lactose fermenters
pH of the medium and the pH change will be detected by → Lack both enzymes
the indicator dye added to the medium” -DOC T

Differentiation between Lactose
fermenters (LF) and Non lactose
fermenters (NLF) by Growth on
MacConkey agar
MacConkey agar is selective and differential
medium for Enterobacteriaceae
How to differentiate lactose fermenters, Delayed and
See image at the last page Non? Based on the image above
MAC: Result interpretation Lactose fermenters (right side)
→ Pink colony with halo - due to more acid produced
Late or Delayed lactose fermenters (middle)
→ Pink colony only - due to less acid produced
Non-lactose fermenters (left)
→ Colorless - lack enzymes

See image at the last page for additonal info

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BIOCHEMICAL TESTING Results
Read both slant and butt. Observe the following
Used for further differentiation of Enteric bacilli color changes:
After growth in MacConkey agar, it will be transferred to Red color: Alkaline (K)
biochemical tubes for inoculation Yellow color: Acidic(A)
○ If:
Yellow butt: only
glucose is fermented
Yellow slant: glucose,
lactose and/or sucrose
are fermented

Reading Results
Note: Read both slant and butt.
Observe the following color changes:

- Yellow color: Acidic (A)
- Red color: Alkaline (K)
Triple Sugar Iron agar, Lysine Iron Agar, Citrate and
Urease - solid tubes ○ Example 1:
→ Due to large percentage of agar alkaline slant / acid butt =
red/yellow= K/A
Sulfide Indole Motility - semi solid Only butt is yellow: glucose
→ Test for motility fermented
→ bacteria needs to be able to move in the medium Only glucose is fermented

Slant ○ Example 2: acid slant/ acid butt =
→ Exposed to air yellow/yellow= A/A
→ Aerobic reactions Both slant and butt are yellow:
→ Inoculate by Simple streaking glucose, lactose and/or sucrose
are fermented
Butt All sugars are fermented
→ Anaerobic reactions
→ Inoculate by Stab

Triple Sugar Iron Test

Is this result possible?

Composition
○ Protein sources: peptone, beef and yeast extract
○ Sugars: 1% lactose, 1% sucrose, 0.1 % glucose

Indicator
○ Phenol red: pH indicator
Alkaline: Red
Acidic: Yellow

○ Ferrous sulfate/ Ferrous ammonium A/K?
sulfate: hydrogen sulfide (H2S) production Acid/Alkaline Lactose fermentation only?
indicator
ANSWER: NO, If a microbe can ferment lactose it must be
○ Sodium thiosulfate (sulfate source) able to ferment glucose.
H2S production: BLACK
precipitate “Lactose is disaccharide, which means that sugars making
up lactose is glucose and galactose. If bacteria will
To inoculate: Stab, Streak breakdown lactose, it must automatically be able to break
Test for carbohydrate fermentation: down your glucose to use it as carbohydrate” - DOC T
○ Carbohydrate fermentation causes acid
production lowers pH, turns phenol red to
yellow

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If only glucose is fermented:

○ Slant and butt initially turn yellow from the
small amount of acid produced
○ After 12 hours: glucose is consumed,
bacteria on the slant use up the peptones
aerobically: alkaline reaction in slant: red
color

“If the peptone breaks down, it releases an alkaline product
producing an alkaline slant, turning it into red” - DOC T

○ Fermentation of glucose (anaerobic) in
Test for gas formation
the butt: produces larger amounts of acid,
overcomes the alkaline effects of peptone Bubble formation
degradation: butt remains acidic (yellow) cracking or splitting of the agar
upward displacement of the agar
“Butt is still yellow because glucose fermentation is mainly pulling away of the medium from the walls of test tube
anaerobic and it happens more in the butt and in the butt we
have more concentration of acid. So the acidity here can still
neutralize the alkaline of the peptone. So remaining in the
butt is the yellowing of the glucose fermentation” - DOC T

Test for H2S production
Blackening of the butt indicates H2S positive
If glucose + lactose or sucrose are fermented: H2S is produced only in acid enviroment
○ So much acid is produced that the slant
and butt remain yellow (acid)

Sample TSI tubes
Sample Results Let’s combine the three tests (CHO, gas and H2S) and
practice reading!

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 Biochemical study of E.coli
More TSI tubes:
Read the following TSI results:

Last batch of TSI tubes: “Ang mag labas sa evals E.coli lang, memorize
Let’s read the following: E.coli only” - DOC T

Lysine Iron Agar Test
It has lysine in the tube which the bacterial enzymes lysine
deaminase or lysine decarboxylase will act about

Composition:
➔ Peptones and yeast extract, glucose,
lysine

Indicators:
○ Bromcresol purple: pH indicator
REMEMBER! Below pH 5.2 (Acidic): Yellow
Above pH 6.8 (Alkaline): Puple
Timing is critical in reading TSI test results: ○ Sodium thiosulfate/ Ferric ammonium
early reading could reveal yellow throughout the citrate: H2S production indicator
medium H2S production: BLACK
late reading could reveal red slant, yellow butt
throughout To inoculate: Stab, Stab, Streak

very important that reactions be read within an 18- to 24-hour
incubation period Test for decarboxylation and
deamination
Detects bacterial ability to decarboxylate or deaminate
lysine and to reduce sulfur

○ Lysine deamination:
Aerobic process, occurs at the slant.
Positive reaction: Red color change.
-Presence of color red in slant automatically
deaminase

○ Lysine decarboxylation:
Anaerobic process, occurs at the butt
Positive reaction: Purple color.
What is the result of E.coli on TSI? -Presence of color purple in butt automatically
decarboxylate

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When inoculated with a lysine
deaminase-positive organism
Oxidative deamination will produce a compound that react
with ferric ammonium citrate and a coenzyme, flavin
mononucleotide, forming a red color on the slant

Positive results

When inoculated with a lysine
decarboxylase-positive organism
Initial yellowing of butt (glucose fermentation)

Cadaverine neutralizes acids produced by glucose
fermentation, Medium reverts to alkaline = purple color
on the butt

Sample LIA tubes
Let’s practice reading:

How to read deamination, How to read
decarboxylation

In the 4th tube (labeled as “4,” when you see the black part it
is opposite with the TSI. If in TSI the H2S only occurs in

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acidic environment in LIA the H2S is formed in alkaline
environment

Therefore, in the 4th tube (+)H2s (so it is alkaline, and is
color purple) so (+) decarboxylase.

What is the result of E. Coli on LIA

Doc did not explain this.

What happens
Citrate permease brings citrate into the bacterial cell:

Other organism: Ex. Shigella on LIA Bromthymol blue in alkaline pH changes to blue.

What about other organisms?

Results

Note: LIA is really confusing so better practice! The important
thing here is to memorize the characteristics of E. Coli.

CITRATE UTILIZATION TEST
Composition: Simmon’s Citrate Agar
○ Carbon source: Sodium Citrate
○ Determines if bacteria can use citrate as a
sole carbon source.
Indicators: Bromthymol blue (pH indicator)
○ Neutral pH: Green
○ Alkaline pH: Blue
To Inoculate: Streak

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What is the result of E. Coli on citrate? Results of various enteric bacteria

What is the result of E. Coli on urease?

Results of various enteric bacteria

UREASE TEST SULFIDE INDOLE MOTILITY TEST
Composition: Christensen’s Urea Agar (solid) / Stuart’s Tests three different parameters, which are represented
Urea Broth (liquid) by the three letters in the name:
Urea, peptone, glucose
○ Indicators: Phenol red: pH indicator
○ Alkaline (>pH 8.4): Pink/magenta
○ Acidic(