Corynebacterial Toxins
The document discusses Corynebacteria and their toxins, focusing on Corynebacterium diphtheriae, which causes diphtheria. C. diphtheriae produces a potent exotoxin that inhibits protein synthesis and causes tissue damage. The toxin has two components - component A carries the enzymatic activity, while component B binds to host cell receptors to transport component A inside cells. After entering cells, the toxin enzymatically modifies elongation factor 2, blocking protein synthesis and killing host cells. Vaccines containing toxoid have greatly reduced diphtheria incidence worldwide.
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Corynebacterial toxins
1. Corynebacterial Toxins
Dr Ravi Kant Agrawal, MVSc, PhD
Principal Scientist (Veterinary Microbiology)
Food Microbiology Laboratory
Division of Livestock Products Technology
ICAR-Indian Veterinary Research Institute
Izatnagar 243122 (UP) India
2. Corynebacteria - Overview
• Gram positive, non-motile bacilli with irregularly stained
segments
• Frequently show club shaped swellings – corynebacteria
(coryne = club)
Found as free-living saprophytes in fresh and salt water, in soil
and in the air
C. diphtheriae: most important/ significant pathogen of this
genus, causes diphtheria
Members of the usual flora of humans and animals
(often dismissed as contaminants)
Often called “diphtheroids”
• Diphtheroids: commensals of nose, throat, nasopharynx, skin,
urinary tract & conjunctiva.
Other species may cause infections in the
immunocompromized hosts
Diphtherais Greek word for prepared hide or leather
3. General Characteristics
• Slender Gram positive bacilli, non-motile, non-spore
forming rods, non-capsulated
Arrange in palisades:
“L shape/ V shape/ Chinese characters/ Chinese
letter or Cuneiform arrangement
Pleomorphic: “club-ends” or coryneform
Beaded, irregular staining
Metachromatic granules (often near the poles) give
the rod a beaded appearance.
Strains of this genus contain short mycolic acid in
the cell wall.
• Stains irregularly, tends to get easily decolorised
• May show clubbing at one or both ends - Polar
bodies/ Metachromatic granules/ volutin or Babes
Ernst granules
• Metachromatic Granules:
– made up of polymetaphosphate
– Bluish purple color with Loeffler’s Methylene
blue
– Special stains: Albert’s, Neisser’s & Ponder’s
• Grows aerobically at 37°C
4. Historical overview: Corynebacterium diphtheriae
Bretonneau 1826: Clinical characterization of diphtheria –
diphtherite
Klebs 1883: Detecting the bacterium
Loeffler 1884: Isolating the bacterium
Roux and Yersin 1888: Discovering the diphtheria toxin
Behring & Kitasato 1890-1892: Discovered diphtheria antitoxin
- Antitoxic immunity (therapy and prevention)
Roux 1894- Treatment with antitoxin
Emil von Behring 1901: Nobel prize
Behring 1913: Active immunisation I. with toxin-antitoxin mix
Schick 1913: Skin test
Ramon 1923: Active immunisation II. Anatoxin = toxoid
Freeman 1951: PHAGE (lysogenia, toxin production)
9. C. diphtheriae
Pathogenesis and Immunity
C. diphtheriae occurs in the respiratory tract, in wounds, or on
the skin of infected persons or normal carriers.
It is spread by droplets or skin contact.
Portal of entry: respiratory tract or skin abrasions.
Diphtheria bacilli colonize and grow on mucous membranes,
and start to produce toxin, which is then absorbed into the
mucous membranes, and even spread by the bloodstream.
Local toxigenic effects: elicit inflammatory response and
necrosis of the faucial mucosa cells-- formation of “PSEUDO-
MEMBRANE” (composed of bacteria, lymphocytes, plasma
cells, fibrin, and dead cells), causing respiratory obstruction.
Systemic toxigenic effects: necrosis in heart muscle, liver,
kidneys and adrenals. Also produces neural damage.
11. C. diphtheriae: Agent of Diphtheria
Toxigenic Corynebacterium diphtheriae
Worldwide distribution but rare in places where vaccination
programs exist
Exotoxin, Diphtheria toxin, as the virulence factor
Not all C. diphtheriae strains produce toxin
Toxin is produced by certain strains
Toxin is antigenic
12. Diphtheria Toxin
• Blocks protein synthesis
• Protein 63Kd
• controlled by Tox gene
• lysogenic phage Beta-corynephage
• Expressed if [iron] low
• 2 components A-B
13. Toxin
• Part A
– Active site
– N terminal
– Enzyme
• Part B
– Binding site
– Binds to
membrane
receptor
– Transmembrane
14. Diphtheria toxin: Part A
• Active site
• Enzyme
• Blocks protein synthesis
– ADP-ribosyl transferase
– elongation factor 2 (EF2)
• Specific for mammalian cells
– Prokaryotes have different EF2
15. Diphtheria Toxin: Part B
• Binding Site
• Binds to cell receptor
• Bound receptor internalized
• Endosome
– Hydrolysed by protease
– Disulfide broken
– Part A released
18. Toxigenic Corynebacterium diphtheriae
Toxin consists of two
fragments (heat
labile)
– A: Active fragment
• Inhibits protein
synthesis
• Leads to cell/tissue
death
– B: Binding
• Binds to specific cell
membrane
receptors
• Mediates entry of
fragment A into
cytoplasm of host
cell
Diphtheria tox Gene in Beta Bacteriophage and Prophage
20. The first step of C. diphtheriae invasion: Adhesion
C. diphtheriae binds host cells' membrane by adhesive structures
called pili.
Sortase, a transpeptidase, recognizes LPLTG (or NPQTG) domain in
Spa subunits and helps in the assembly of the pili.
SpaA, SpaB and SpaC present a signal peptide to address them in the cytoplasm.
Pizarro-Cerdà and Cossart, 2006
21. Molecular Structure of Diphtheria Toxin
Catalytic Region
Receptor-Binding Region
Translocation Region
A Subunit
B Subunit
22. Diphteria toxin structure
Diphteria toxin is a 535 aa AB
toxin.
A domain is catalytic.
T domain is hydrophobic and
binds the endoplasmic
membrane.
B domain is connected to A
domain by a disulphuric bridge
and a peptidic bond, and it
binds cell receptor.
Todar, 2008
23. Endocytosis of the toxin
Diphteria toxin bind HB-EGF
(heparin binding epidermal
growth factor) on cell surface.
As far as it enters the cell via
endocytosis the acidification
of the endosome cause a
conformational change in the
toxin and it can translocate
the catalytic domain in the
cytoplasm.
Bafilocimycin A1 inhibits
release of toxins in the
cytoplasm by blocking their
escape from endosomes. It
blocks ATPases, that normally
acidify the endosomes. It also
seems to block subunit A and
B separation
Todar, 2008
24. Mechanism of action
Diphtheria toxin blocks protein elongation by binding EF2 elongation factor
EF2 + NAD+ -------------> ADP-ribose-dipthamide-EF2 + Nicotinamide + H+
By removing EF2 from the intracellular environment, it blocks the transition
between A site and P site in the ribosome.
• This factor is required for translocation of polypeptidyl-transfere RNA from
the acceptor to the donor site on the eukaryotic ribosome.
•Thus preventing protein synthesis leading to cell death.
Diphteria toxin has an extremely low lethal dose.
It is a heat-labile polypeptide that can be lethal in a dose of 0.1 ug/kg.
Toxin is lethal in human beings in an amount 130μg/kg BW
25. Regulation of Diphtheria Toxin High [Fe 2+]
dtxR
Fe 2+ + apo DtxR
[Fe 2+
*DtxR]
p
C diphtheriae
dtxR= repressor protein
NO Toxin Produced
tox
Corynebacteriophage beta
o
P
26. Regulation of Diphtheria Toxin Low [Fe 2+]
Fe 2+ + apo DtxR
[Fe 2+
*DtxR]
Toxin Produced!!!
tox
Corynebacteriophage beta
o
P
28. Clinical Forms of Diphtheria
Respiratory
Acquired by droplet spray
or hand to mouth contact
Non-immunized individuals
are susceptible
Non-respiratory
Systemic
Skin and cutaneous forms
Bull-neck appearance
Bull-neck appearance of
diphtheritic cervical lymphadenopathy
29. Diphtheria
Respiratory disease–diphtheria
Incubation period–2 to 5 days
Symptoms: sore throat, fever, malaise
Toxin is produced locally, usually in the
pharynx or tonsils
Toxin causes tissue necrosis, can be
absorbed to produce systemic effects
Forms a tough, thick, adherent grey to
white pseudo-membrane which may
cause suffocation (WBC + RBCs
+organism +fibrin +dead cells)
30. Diphtheria Pseudomembrane
• No True membrane
• Very few live cells
• Deposit of dead cells and
protein
CONTAINS
– bacteria
– lymphocytes
– plasma cells
– fibrin
– dead cells
COVERS
– tonsils,
– uvula,
– palate
– nasopharynx
– larynx.
31. Diphtheria: Systemic complications
• Nerves
– toxic peripheral neuropathy
– paralysis of short nerves
– mouth, eye, facial extremities
• Cardiac
– Congestive heart failure
– high amount of toxin 48-72 hours
– Low amount of toxin 2-6 weeks
32. Laboratory Diagnosis
• Specimen – swab from the lesions
1. Microscopy
– Gram stain: Gram +ve bacilli, chinese letter pattern
– Immunofluorescence
– Albert’s stain for metachromatic granules
2. Culture
• Isolation of bacilli requires media enriched with blood, serum
or egg
a. Blood agar: to differentiate from staphylococal or
streptococcal pharyngitis
C. diphtheriae colonies are small, granular, irregular
edges and gray with small zones of hemolysis
a. Loeffler’s serum slope – rapid growth, 6 to 8 hrs
b. Tellurite blood agar – tellurite is reduced to tellurium, gives
gray or black color to the colonies
c. Hoyle’s media: modifications of TBA
d. McLeod’s media
33. Specialized media
Tellurite:
black colonies
Not diagnosticallly significant
tellurite inhibits many organisms but not C. diphtheriae
Loeffler
best colonial morphology
Dextrose horse serum (1887)
now Dextrose beef serum
Blood tellurite
Selective & differential medium
Corynebacteria are resistant to tellurite
Reduced to tellurium
Forms deposit in colonies
Colonies appear dark
Biotypes - gravis, intermedius, mitis
34. Laboratory Diagnosis: Cultural Characteristics
• Loeffler's slant used to demonstrate
pleomorphism and metachromatic
granules ("Babes’ Ernst bodies“)
• Growth on Serum Tellurite or
modified Tinsdale exhibits brown or
grayish→ to black halos around the
colonies
• Blood agar plate, grey translucent
colonies
• Small zone of beta-hemolysis also
seen
Tellurite: tellurium dioxide (TeO2).
35. Growth of diphtheria bacilli
Blood agar
Loeffler’s serum slope
Tellurite blood agar
37. Biotypes of Diphtheria bacilli
• Based on colony morphology on the tellurite medium & other
properties, McLeod classified diphtheria bacilli into three types:
Features 1. Gravis 2. Intermedius 3. Mitis
Case fatality rate High High Low
Complications Paralytic,
hemorrhagic
Hemorrhagic Obstructive
Predominance In epidemic areas Epidemic areas Endemic areas
Spread Rapid Rapidly than mitis Less rapid
Colony on TBA ‘Daisy head” colony ‘Frog’s egg colony ‘Poached egg’
colony
Hemolysis Variable Nonhemolytic Usually hemolytic
38. Laboratory Diagnosis
3. Biochemical reactions
a. Hiss's serum water - ferments sugar with acid formation but
not Gas
ferments: glucose, galactose, maltose and dextrin
b. Resistant to light, desiccation and freezing
c. Sterilization: sensitive to heat (destroyed in 10mins at 58°C
or 1min in 100°C), chemical disinfectants
39. Biochemical tests:
The colonial morphology of C. diphtheria on Tinsdale medium is the
most important characteristics in differentiating it from other species
of corynebacteria.
=Urease Negative
=Nitrate Positive
=Gelatin liquefaction: Negative
Fermentation reactions of various carbohydrates.
39
abed elkader elottol
40. Laboratory Diagnosis
4. Virulence tests - Test for toxigenicity
A. Invivo tests – animal inoculation (guinea pigs)
a. Subcutaneous test
b. Intracutaneous test
B. Invitro tests
a. Elek’s gel precipitation test
b. Tissue culture test
41. Laboratory Diagnosis
Virulence tests - Invivo tests
• Bacterial growth from Loeffler’s serum slope is emulsified in 2-
4 ml broth.
• Two guinea pigs (GP A and GP B)
I. Subcutaneous test – 0.1 ml of emulsion is injected SC into each
guinea pig
GP A - has diphtheria antitoxin (500 units injected 18 to 24 hours before)
GP B - Doesn't have antitoxin
II. Intracutaneous test - 0.1 ml of emulsion is injected IC into each
guinea pig
GP A - has diphtheria antitoxin (500 units injected 18 to 24 hours before)
GP B – 50 units of antitoxin IP four hrs after the skin test
43. Laboratory Diagnosis
Virulence tests - Invitro tests
I. Elek's gel precipitation test
– filter paper saturated with
antitoxin (1000units/ ml) is
placed on agar plate with
20% horse serum
– bacterial culture streaked at
right angles to filter paper
II. Tissue culture test
- incorporation of bacteria
into agar overlay of
eukaryotic cell culture
monolayers.
Result: toxin diffuses into cells
and kills them
44. Treatment
• Infected patients treated with anti-toxin and antibiotics
– Anti-toxin produced in horses
– Antibiotics have no effect on circulating toxin, but prevent
spread of the toxin by bacteial killing
• Penicillin drug of choice, erythromycin
• Specific treatment must not be delayed if clinical picture
suggests of diphtheria
• Rapid suppression of toxin-producing bacteria with
antimicrobial drugs (penicillin or erythromycin)
• Early administration of antitoxin: 20,000 to 1,00,000 units for
serious cases, half the dose being given IV
45. Prophylaxis
1) Active Immunization (Vaccination)
i. Formol toxoid (fluid toxoid)
• incubation of toxin with 0.3% formalin at pH 7.4 - 7.6 at 37°C for 3 to 4 weeks
• fluid toxoid is purified and standardized in flocculating units (Lf doses)
ii. Adsorbed toxoid (more immunogenic than fluid toxoid)
• purified toxoid adsorbed onto insoluble aluminium phosphate or aluminium
hydroxide
• given IM (DTP or TD)
Adsorbed Toxoid
a. DPT - triple vaccine given to children; contains diphtheria toxoid, Tetanus toxoid
and pertussis vaccine
b. DaT - contains absorbed tetanus and ten-fold smaller dose of diphtheria toxoid.
(smaller dose used to diminish likelihood of adverse reactions)
• Schedule
i) Primary immunization - infants and children
- 3 doses, 4-6 weeks interval
- 4th dose after a year
- booster at school entry
ii) Booster immunization - adults
-Td toxoids used (travelling adults may need more)
• SHICK test - to test susceptibility to vaccine, not done now-a-days
46. Diagnostic Schick Skin Test
TOXIN TOXOID
Immune Status to C. diphtheriae and Sensitivity to
Diphtheria Toxoid
47. Prophylaxis
2. Passive immunization
ADS (Antidiphtheritic serum, antitoxin) - made from horse
serum
- 500 to1000 units subcutaneously
3. Combined immunization
First dose of adsorbed toxoid + ADS, to be continued by the
full course of active immunization
48. CONTROL
1. Isolate patients
2. Treat with antibiotics actively
3. Complete vaccination schedule should be used with
booster every 5 years
50. Urinary tract infections (UTI’s); rare but important
Urease hydrolyzes urea; release of NH4
+, increase in pH,
alkaline urine, renal stones
Corynebacterium urealyticum
51. Opportunistic infections in
immunocompromised (e.g.,
patients with blood disorders,
bone marrow transplants,
intravenous catheters)
Multiple antibiotic resistance
common (MDR)
Carriage on skin of up to 40% of
hospitalized patients (e.g.,
marrow t-plants)
Corynebacterium jeikeium
Percentage of Individuals
Colonized
52. Thanks
Acknowledgement: All the presentations available online on the subject
are duly acknowledged.
Disclaimer: The author bear no responsibility with regard to the source
and authenticity of the content.