Lecture 15 - Chapter 18 - Microbial Pathogenesis PDF

Summary

This chapter details microbial pathogenesis, looking at the molecular tools microbes use to cause disease, strategies for surviving in a host, and comparing pathogenic mechanisms across viral, bacterial, fungal, and protozoan pathogens. It also discusses the crucial steps in colonization including attaching to host cells, and surviving within a host through immune evasion.

Full Transcript

CHAPTER 18
Microbial Pathogenesis

Copyright © 2021 W. W. Norton & Company, Inc.
Microbial Pathogenesis
Chapter Objectives
▪ Describe the major molecular “tools” microbes use to cause
disease.
▪ Discuss the strategies different pathogens use to survive in a
host.
▪ Compare the pathogenic mechanisms of viral, bacterial, fungal,
and protozoan pathogens.

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18.2 Pathogen Entry and Colonization
Section Objectives
▪ Explain why pathogens need to attach to host cells.
▪ Describe various microbial attachment techniques.
▪ Differentiate the structure and function of type I and type IV pili.
▪ Discuss the role of biofilms in pathogenicity.

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Ex. Body mechanisms to prevent colonization
▪ The lungs: Mucociliary escalator → moves pathogens out.
▪ The intestine: Peristaltic action → constant flow
▪ The bladder: Detrusor contraction → propels urine with
tremendous force.
 Entry and Colonization
▪ The first step toward infection is attachment (adhesion).
▪ Types of adhesins.
Pili adhesins: Hairlike appendages - tips with receptors for
host cells surface.
Non-pili adhesins

Colonization and biofilming formation
Pilus Assembly – 1
▪ Pili are made up of identical pilin protein subunits.
The tip of the pilus contains an adhesion protein that binds
host cell receptors.

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Pilus Assembly – 2
▪ Assembly of the pili starts with the tip protein.
It will bind to carbohydrates on the host cell surface.

Pyelonephritis-associated pilus
(Pap) assembly in E. coli:
The Sec system secretes proteins
to the periplasm → PapD
chaperones them to the site of
assembly → Assembly starts
with the tip protein (PapG) →
subunits fit together → growing
pilus → binds to carbohydrates
on host membranes. 7
Types of Pili
▪ Type I pili: static, hairlike ▪ Type IV pili: dynamic, thin,
appendages used only for and flexible for “twitching
attachment motility”

Uropathogenic E. coli binding to epithelial Ex. Vibrio cholerae, Pseudomonas aeruginosa, certain
cells by pili. pathogenic strains of E. coli, Neisseria meningitidis, and N.
gonorrhoeae. 8
 Step 1: Colonization
Escherichia coli (UPEC) colonize the vaginal
and periurethral areas.
Step 2: Migration to Bladder
Uropathogens migrate from the periurethral
area to the bladder.
Step 3: UPEC Adherence & Internalization
UPEC type 1 pili (FimH protein at the tip)
binds to uroplakins/mannosylated
glycoproteins on superficial bladder umbrella
cells → internalization.
Step 4: Formation of Intracellular Bacterial
Communities (IBCs)
Inside the cells, UPEC multiply to form IBCs.
Step 5: Efflux & Reinvasion
UPEC efflux from IBCs to reinvade
neighboring cells.

Sihra, N., Goodman, A., Zakri, R. et al. Nonantibiotic prevention and management of recurrent urinary tract infection. Nat Rev
Urol 15, 750–776 (2018). https://doi.org/10.1038/s41585-018-0106-x
Nonpilus Adhesions
▪ Cell wall associated proteins that bind to host proteins like
integrin or fibronectin causing a more intimate attachment:
Bordetella pertactin: host integrin
Streptococcus protein F: host fibronectin
Streptococcus protein M: host fibronectin and the complement
regulatory factor H
▪ Neisseria meningitidis type IV pili → Neisserial Opa nonpilis
membrane proteins → more intimate attachment.

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 Discretion is advised

From: https://www.nhs.uk/conditions/pressure-sores/

From: https://www.accessmedicinenetwork.com/posts/53226-pressure-ulcer-staging-and-treatment
18.3 Surviving within a Host
Section Objectives
▪ Explain why and how pathogens distinguish between
intracellular and extracellular existence.
▪ Describe various strategies pathogens use to avoid the immune
system.
▪ Distinguish extracellular pathogens from facultative and obligate
intracellular pathogens.
▪ Discuss the three main ways intracellular pathogens avoid
intracellular destruction.

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Environment or Host?
▪ The microbe monitors the conditions and detect changes when in
a host such as:
Temperature
Iron levels
Yes? Expression of
Magnesium levels Host? virulence genes
pH levels
Hormones
▪ The virulence factors expressed depends on:
Extracellular pathogen
Intracellular pathogen
Facultative intracellular pathogen
Extracellular Pathogens
▪ Extracellular immune avoidance
Capsules: coat bacterial cell walls and can prevent phagocytes
from binding.
– Opsonizing antibodies can bind to the capsule.

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Extracellular Pathogens
▪ Extracellular immune avoidance
Cell surface proteins like protein A (S. aureus) can sequester
antibodies.
– Bind Fc region of antibodies

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Kobayashi SD, DeLeo FR.2013.Staphylococcus aureus Protein A Promotes Immune Suppression. mBio4:10.1128/mbio.00764-13.https://doi.org/10.1128/mbio.00764-13
Extracellular Pathogens
▪ Extracellular immune avoidance
Some pathogens vary surface antigens to avoid immune
detection.
▪ Salmonella expressing
Flagellin A can change
to Flagellin B.

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Extracellular Pathogens
▪ Extracellular immune avoidance
Cell-cell communication via quorum sensing can also help
pathogens evade the immune system.
– Autoinducer molecule will rise as the number of bacteria
increases.

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Intracellular Pathogens
▪ Intracellular pathogens avoid innate and humoral immune
mechanisms by living inside host cells → not detected.
▪ Facultative intracellular pathogens can invade host cells but
can also survive outside the host cell.
Example: Salmonella, Shigella, Listeria
▪ Obligate intracellular pathogens invade and reproduce inside a
host cell only.
Example: Rickettsia, Coxiella, Bartonella

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Intracellular Pathogens
▪ Fates of intracellular
pathogens

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18.4 Host Damage and Manipulation – 1
Section Objectives
▪ Describe the nine basic cellular targets for bacterial toxins.
▪ Explain the modes of action for staphylococcal alpha toxin,
cholera toxin, diphtheria toxin, Shiga toxin, and anthrax toxin.
▪ Differentiate endotoxin from exotoxin.
▪ Describe secretion systems pathogens use to export
exotoxins/effector proteins.

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 Exotoxin Modes of Action – 1
Microbial exotoxins are categorized on the basis of their cellular
targets and mechanisms of action.
Pores
formation

Actin polymerization
and depolymerization

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Exotoxin Modes of Action – 2
▪ Two-subunit AB toxins
A subunit is toxic.
B subunit binds host cell
receptors.

‘A’ subunit possess an
ADP-ribosyltransferase
→ inactivates or alters
ADP- ribosylates target The G protein controls the cAMP-
proteins (G-protein). producing enzyme adenylyl
cyclase. 24
Exotoxin Modes of Action – 3
▪ Toxins that disrupt the membrane:
▪ Alpha toxin forms a seven-membered transmembrane pore in
target cell membranes.
Causes cell contents to leak
Cell lysis

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Exotoxin Modes of Action – 4
▪ Toxins that disrupt signal transduction:
E. coli binds to the villus and secretes toxins that disrupt
normal function.

▪ How does diarrhea benefit the
pathogen?

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Cholera and labile
toxins
Exotoxin Modes of Action – 5
▪ Toxins that disrupt protein synthesis:
C. diphtheriae remains in the
pharynx.
Low levels of iron? → Diphtheria
toxin released (also an ADP-
ribosyltransferase and AB toxin).

▪ How does this bacteria can cause
nervous system or cardiovascular
affections?
▪ Can you name another toxin?
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Endotoxin (LPS)
▪ Endotoxin
Part of the outer membrane
of the Gram-negative cell
wall that includes
lipopolysaccharide
– Fever
– Activation/Depletion of
clotting factors (petechiae)
– Activation of complement,
– Vasodilation
– Shock → death
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Secretion of Virulence Proteins

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Secretion of Virulence Proteins ‒ 3
▪ Type II secretion system
“Piston” delivery

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Secretion of Virulence Proteins ‒ 4
▪ Type III secretion system
“Syringe” delivery
▪ Type IV secretion system
“Tube” delivery → to the host plasma membrane

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Salmonella: A Model of Bacterial Pathogenesis

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