Bacterial Pathogens and Diseases I (Exotoxins)

Question 1

Pathogen - define

Answer 1

Pathogen: A microorganism capable of causing disease.

Question 2

Pathogenicity - define

Answer 2

Pathogenicity: The ability of an infectious agent to cause disease.

Question 3

Virulence - define

Answer 3

Virulence: The quantitative ability of an agent to cause disease.

Question 4

Toxigenicity - define

Answer 4

Toxigenicity: The ability of a microorganism to produce a toxin that contributes to the development of disease.

Question 5

Virulence – Mechanisms - list

Answer 5

Adherence Factors

Biofilms

Invasion of Host Cells and Tissues

Toxins – endotoxins and exotoxins

Question 6

What are exotoxins?

Answer 6

Heterogeneous group of proteins produced and secreted by living bacterial cells.

Question 7

Exotins - produced by what

Answer 7

Produced by both gram negative and gram positive bacteria.

Question 8

Exotins - effect

Answer 8

Cause disease symptoms in host during disease.

Cause disease? – may help transmission of disease, however in severe disease host may be a literal and evolutionary dead end.

Question 9

Exotins - action

Answer 9

Act via a variety of diverse mechanisms.

Question 10

What selective advantages do exotoxins give to the bacteria?

Answer 10

With many toxins the disease causing activity may be not be the primary function.
Other activities:

Evade immune response
Enable biofilm formation
Enable attachment to host cells.
Escape from phagosomes

All allowing for colonisation, niche establishment and carriage - Evolutionary advantage.

Question 11

Haemolytic toxins - effect, involved in which disease and give examples

Answer 11

Haemolytic toxins:

cause cells to lyse by forming pores

Important cause of features of S. aureus disease.

α,β,δ, toxins ,Panton Valentine Leukocidin (PVL), LukAB, LukED, LukMF

Question 12

Describe genetic encoding of exotins

Answer 12

Can be encoded by chromosomal genes Shiga toxin in Shigella dysenteriae, TcdA & TcdB in C. difficile

Many toxins coded by extrachromosomal genes:

Plasmids – Bacillus anthracis toxin, tetanus toxin

Lysogenic bacteriophage – e.g. streptococcal pyrogenic exotoxins in Scarlet Fever, Diphtheria toxin.

Question 13

Classification of Exotoxins

Answer 13

As very diverse group of proteins and many ways to classify.
Classification can be by the toxins activity .

Membrane Acting Toxins – Type I
Membrane Damaging Toxins – Type II
Intracellular Toxins – Type III

Question 14

Problems with classification of Exotoxins

Answer 14

This classification has its problems –
Many toxins may have more than one type activity.
As mechanisms better understood this classification tends to break down.

Question 15

Membrane Acting toxins – Type I, describe where they:

• Act
• Interfere
• Target

Answer 15

• Act = Act from without the cell.
• Interfere = Interfere with host cell signaling by inappropriate activation of host cell receptors.

- Target = Target receptors include 
Guanylyl cyclase  → ↑  intracellular cGMP
Adenyl cyclase → ↑ intracellular cAMP
Rho proteins
Ras proteins

Question 16

Membrane damaging toxins – type II - describe and explain action

Answer 16

Cause damage to the host cell membrane.

Insert channels into host cell membrane.
β sheet toxins e.g. S.aureus α – toxin, δ toxin, PVL
α helix toxins – e.g. diphtheria toxin
Enzymatical damage e.g. S. aureus β- haemolysin, PSM

OR

Receptor mediated

Receptor Independent

Question 17

Membrane Damaging Toxins - describe action

Answer 17

Soluble monomer
Membrane associated monomer binding to specific receptor – ADAM10 - a sheddase a disintegrin and metalloproteinase
Nascent oligomer/pre pore complex
Membrane insertion

Question 18

Intracellular toxins – type III - action

Answer 18

Active within the cell – must gain access to the cell

Usually 2 components – AB Toxins

• Receptor binding and translocation function – B
• Toxigenic (enzymatic) – A
• May be single or multiple B units e.g. Cholera toxin AB5

Question 19

Enzymatic component A – wide variety of activities - List

Answer 19

Enzymatic component A – wide variety of activities.

ADP – ribosyl transferases - e.g. Exotoxin A of Pseudomonas aeruginosa, pertussis toxin.
Glucosyltransferases – e.g. TcdA and TcdB of Clostridium difficile
Deamidase – e.g. dermonecrotic toxin of Bordetella pertussis.
Protease – e.g. Clostridial neurotoxins: botulism & tetanus
Adenylcyclase - e.g. EF toxin of Bacillus anthracis

Question 20

Describe superantigen mech for exotoxins

Answer 20

Superantigen – non specific bridging of the MHC Class II and T- cell receptor leading to cytokine production. E.g. Staphylococcal Exfoliative Toxin A, Toxic Shock Syndrome Toxin 1 (TSST1)

Question 21

Describe inflammasome mech for exotoxins

Answer 21

Via activation of the different inflammasome leading to release IL1 β and IL18 e.g. S. aureus toxin A, PVL.

Question 22

Exotin relation to cytokine action - describe and list examples

Answer 22

Exotoxins are able to induce inflammatory cytokine release

IL1, IL1β, TNF, IL 6,δ interferon, IL18

Question 23

Toxins can be inactivated using

Answer 23

Toxins can be inactivated using formaldehyde or glutaraldehyde → toxoids

Question 24

What allows toxioids to form basis of vaccines - give examples

Answer 24

Toxoids are inactive proteins but still highly immunogenic – form the basis for vaccines.
Tetanus Vaccine
Diphtheria
Pertussis (acellular).*

Question 25

Treatment of toxin mediated disease can be affected by

Answer 25

Treatment of toxin mediated disease can be affected by administering preformed antibodies to the toxin:

Diphtheria antitoxin – horse antibodies.
Tetanus – pooled human immunoglobulin. Specific or normal.
Botulism – horse antibodies

Question 26

Clostridium difficile

(Clostridioides difficile) - describe microbiology

Answer 26

Microbiology:

gram-positive bacillus.
anaerobic.
spore-forming.
toxin-producing.
can be carried asymptomatically in the gut. 
3 toxins.

Question 27

Clostridium difficile

(Clostridioides difficile) - describe epidemiology

Answer 27

Epidemiology:

Common hospital acquired infection worldwide.
Spread by ingestion of spores – remain dormant in environment.
Coloniser of the human gut up to 5% in adults.
Risk factors – antibiotic use, age, antacids & prolonged hospital stay.

Question 28

Clostridium difficile – antibiotics - describe action

Answer 28

Thought to act by disrupting the microbial ecosystem within the gut.

Question 29

Clostridium difficile – antibiotics - benefits

Answer 29

Antibiotics provide a competitive advantage to spore forming anaerobes over non spore forming anaerobes.
Allows C. difficile colonisation and growth.

Question 30

Coding of Cytotoxin A

Answer 30

Cytotoxin A - TcdA coded by tcdA gene

Question 31

Coding of Cytotoxin B

Answer 31

Cytotoxin B – TcdB coded by tcdB gene

Question 32

The A component of toxins are

Answer 32

The A component of toxins are glycosylating enzymes.

Question 33

Clostridium difficile disease - characteristics

Answer 33

Asymptomatic

Watery Diarrhoea

Dysentery

Pseudomembranous Colitis

Toxic Megacolon and
Peritonitis

Question 34

Clostridium difficile disease - pathology

Answer 34

Cytopathic & Cytotoxic:

Patchy necrosis with neutrophil infiltration
Epithelial ulcers
Pseudomembranes – leucocytes, fibrin, mucous, cell debris.

Question 35

C. difficile - diagnosis

Answer 35

Clinical signs and symptoms
Raised white cell count in blood.

Detection of organisms and toxins in stool

2 phase test:

Glutamate dehydrogenase – detects if C. difficile organism present.
Toxin enzyme linked immunosorbent assay (ELISA) for TcdA and TcdB toxins.

Detection of tcdA and tcdb genes – PCR

Colonoscopy – pseudomembranous colitis

Question 36

C. difficile treatment

Answer 36

Treatment dependent on severity and presence of surgical complications
Ideally removal of offending antibiotic – not always possible
Antibiotics fidaxomicin or metronidazole or vancomycin
Surgery – partial, total colectomy
Recurrent – faecal transplant.

Question 37

Verocytotoxin Escherichia coli (VTEC) disease - effect

Answer 37

VTEC, or Shiga-toxin (Stx) producing E. coli (STEC) can cause disease mild to life threatening disease.

Question 38

Verocytotoxin Escherichia coli (VTEC) disease - presentation

Answer 38

Stx carried by some E. coli – most commonly O157:H7
Identified usually by growth on sorbitol MacConkey agar (SMac) – does not ferment sorbitol and hence is clear.
Other less common types not identified using SMac.

Question 39

Verocytotoxin Escherichia coli (VTEC) disease - describe epidemiology

Answer 39

E. coli O157:H7 naturally colonizes the gastrointestinal tracts of cattle who are generally asymptomatic.

Transmission:

Predominantly via consumption of contaminated food and water
Person to person, particularly in child day-care facilities, and from
Animal to person. E.g. in petting zoos, dairy farms, or camp grounds.

Very low infectious dose

Question 40

SLT - describe structure

Answer 40

Toxin – Shiga like toxin (SLT) = shigatoxin (Stx) = verocytotoxin (VTEC)
Stx, Stx1, Stx1a, 1c, 1d Stx2a, 2c, 2d – variations in a.a. sequence
Gene carried on lysogenic bacteria.
Type III exotoxin – AB5
Enzymatic component A = N-Glycosidase
Bound to 5 B subunits

Question 41

SLT - describe mechanism

Answer 41

Bind to receptor globotriaosylceramide Gb3 or globotetraosylceramide (Gb4) on host cell membrane

Bound toxin internalised by receptor mediated endocytosis.

Carried by retrograde trafficking via the Golgi apparatus to the endoplasmic reticulum.

The A subunit is cleaved off by membrane bound proteases

Once in the cytoplasm A1 and A2 disassociate

A1 binds to 28S RNA subunit – blocks protein synthesis.

Question 42

STEC - Pathogenesis

Answer 42

Closely adheres to epithelial cells of the gut mucosa.

Route from intestine to the kidney and other tissues is debated, possibly polymorphonuclear neutrophils (PMNs)

Bind to glomerular endothelial cells of kidney, cardiovascular and central nervous system.

Very high levels of Gb3 in kidney so kidneys most affected.

Thought that Stx favours inflammation resulting in microvascular thrombosis and inhibition of fibrinolysis.

Question 43

STEC Disease - characteristics

Answer 43

Can be severe and life threatening
Children < 5 years  greatest risk
Abdominal cramps, watery or bloody diarrhoea – may not be present 
Haemolytic uraemic syndrome
Less common are neurological symptoms

Question 44

Describe Haemolytic uraemic syndrome

Answer 44

Haemolytic uraemic syndrome
Anaemia
Renal Failure
Thrombocytopaenia

Question 45

STEC Diagnosis

Answer 45

Diagnosis:

Clinical signs and symptoms
Haematological and biochemical evidence.
Stool culture – Growth on SMac
PCR for Stx genes

Question 46

STEC Treatment

Answer 46

Treatment:

Supportive including renal dialysis and blood product transfusion
Antibiotics have little to no role