Microbial Pathogenesis (Chapter 25) PDF

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This document provides an overview of microbial pathogenesis, focusing on bacteria, normal microbiota, and the language of pathogenesis.

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Microbial Pathogenesis
Chapter 25
 Bacteria Are Ubiquitous
We contact numerous microorganisms daily
Breathe in, ingest with food and drink, pick up on
skin
Relatively few are pathogens that
invade tissues and cause damage
Pathogenic microbes exploit those weaknesses, and the
result is disease.
All pathogens have distinct characteristics that allow
avoidance of body defenses – virulence factors
Salmonella enterica serotype Typhimurium
invading cultured human cells

By NIAID: These high-resolution (300 dpi) images may be downloaded directly from this site., Public Domain,
https://commons.wikimedia.org/w/index.php?curid=450281
The Normal Microbiota
Normal Microbiota –
community of microorganisms
found in/on body of healthy
individual
Resident microbiota inhabit sites
for extended periods
Important to human health

Transient microbiota inhabit
temporarily (hours – days)
because…
Not suitable environment
Host innate and adaptive defenses
Competition & antagonism from By DataBase Center for Life Science (DBCLS) - https://doi.org/10.7875/togopic.2020.154,
CC BY 4.0, https://commons.wikimedia.org/w/index.php?curid=89430513
resident microbes
The Normal Microbiota
The Protective Role of the Resident Microbiota
Significant contribution is protection against pathogens via
competition
Covering binding sites prevents attachment
Consumption of available nutrients, growth factors
Production of toxic compounds (bacteriocins, antibiotics)

When resident microbiota killed or suppressed -> dysbiosis:
Competition eliminated, pathogens may colonize, cause disease
Many examples
Ex: Oral antibiotics can inhibit intestinal microbiota, allow overgrowth of toxin-producing Clostridium difficile
“7 to 10 times more likely to get C. diff while on antibiotics and during the month after” - CDC

Kho ZY and Lal SK (2018) The Human Gut Microbiome – A Potential Controller of Wellness and Disease. Front.
Microbiol. 9:1835. doi: 10.3389/fmicb.2018.01835 (CC BY)
 The Normal Microbiota
The Protective Role of the Resident Microbiota
Stimulation of adaptive immune system
When small numbers of normal skin microbiota enter our body through
cuts, they stimulate an immune response
The antibodies made against normal microbiota may also bind to pathogens
Mice in microbe-free environment have
underdeveloped mucosal-associated
lymphoid tissue (MALT) – this is important in
mucosal immunity and prevents microbes
from entering mucous membranes
The Language of Pathogenesis
▪ By definition, a parasite is an organism that receives benefits at the expense of a
host.

In practice, the term “parasite” refers to disease-causing protozoa and
worms.

Bacterial, viral, and fungal parasitic agents of disease are called pathogens.

Ectoparasites live on the surface of the host; endoparasites live inside the
host’s body.

▪ An infection occurs when a pathogen or parasite enters or begins to grow on a
host. However, the term “infection” does not necessarily imply overt disease.
The Language of Pathogenesis

Disease – Any prolonged abnormal condition in which host cells are
damaged and symptoms and/or signs of illness are present
Infectious (contagious = caused by pathogen)
vs. noninfectious (not contagious = ex: cancer)

Pathogen – Any infectious biological agent that causes disease
Bacteria, viruses, fungi, protozoans, helminths (worms)

Host – An organism that harbors another organism either on or within
itself
 Disease Triangle
Disease is dependent on characteristics of the host, pathogen, and environment

Immunity (ability to stop pathogen)

Virulence (un)Favorable for pathogen (increase virulence/abundance)
(evade and reproduce in host) and/or
(un)favorable for host (decrease immunity)
 Environment

Favorable to Pathogen/Host
(Poorly Highly)

Disease

Pathogen
Host

Permeability to Pathogen
(Low -> High)

Host
Microbiome
Salamander Image by Jose Carlos Arenas-Monroy CC0 1.0 Bernardo-Cravo et al. 2020 Trends in Parasitology
 The Language of Pathogenesis
Disease is characterized by…

Signs are objective evidence of infection
(fever, rash, pus formation, swelling)

Symptoms and are subjective effects
experienced by patient (I feel... pain, nausea)
The Language of Pathogenesis
▪ It is often “friendly fire” by our immune system reacting to a
pathogen that causes major tissue and organ damage.
▪ The term immunopathogenesis applies when the immune response
to a pathogen is a contributing cause of pathology and disease.
▪ To fully understand any infectious disease, researchers must study
both the pathogenic mechanisms of the pathogen and the disease
symptoms/signs caused by immunopathogenesis.
The Language of Pathogenesis
Colonization refers to a microbe
establishing itself and multiplying
The term infection can be used to refer
to a pathogenic microbe that colonizes,
establishes, and multiplies

Infection does not always lead to
disease Clinical
Threshold
Subclinical Infection = no or very mild
signs or symptoms

Colonization = non-pathogens
Infection = pathogens
Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
 The Language of Pathogenesis

Course of Infectious Disease

Subclinical infection: pathogen
replicates in host but at low levels that
do not produce obvious signs and
symptoms

Carriers may harbor and spread
infectious agents in the absence of signs
or symptoms

Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
The Language of Pathogenesis

Initial infection in a healthy individual is called
the primary infection, caused by a primary
pathogen
A primary pathogen can cause disease in a
healthy individual
Diseases such as plague, malaria, measles, influenza,
diphtheria, tetanus, and tuberculosis are caused by
primary pathogens

Plasmodium spp. = malaria

image by Ute Frevert;false color by Margaret Shear -
http://journals.plos.org/plosbiology/article?id=10.1371/journal.pbio.003019
2, CC BY 2.5, https://commons.wikimedia.org/w/index.php?curid=219588
 The Language of Pathogenesis
Damage from primary infection (or treatment of)
can predispose an individual to develop a
secondary infection caused by an opportunistic
pathogen

Opportunistic pathogens cause disease only when
the body’s immune defenses are compromised or
when introduced into an unusual location

Typically, members of normal microbiota or common
environmental microbe
Ex: Pseudomonas aeruginosa is a common environmental
microbe that can cause fatal infections in people with cystic
fibrosis
Ex: viral respiratory illness impairing barrier defenses can
result in pneumonia (bacterial lung infection)
Pseudomonas aeruginosa
Ex: infection that occurs as a result of surgery, cut, burn
CDC/ Janice Haney Carr Public Domain
The Language of Pathogenesis
▪ Pathogenicity refers to an organism’s ability to cause disease. It is
defined in terms of...
how easily an organism causes disease (infectivity)
how severe that disease is (virulence)
the specific genetic makeup of the pathogen
The Language of Pathogenesis

Virulence is a measure of the degree,
or severity of disease
The ability of an infectious agent to
multiply and cause damage to the host

Highly virulent bacterial strains cause severe
disease
Ex: Streptococcus pyogenes normally causes
strep throat, but highly virulent strains can cause
necrotizing fasciitis (“flesh-eating disease”)

Streptococcus pyogenes on neutrophil

NIAID Public Domain
 The Language of Pathogenesis
Measuring virulence
Virulence is measured by
determining the….

infectious dose ID50, - number of
cells/virions required to cause
infection in 50% of hosts
AND/OR
lethal dose LD50 - number of
cells/virions required to cause
death in 50% of hosts
Highly virulent pathogens – the
difference between LD50 and LD100
is small
The Language of Pathogenesis
Virulence factors are genes/products that allow
microbes to cause disease. Allows microbe to…
colonization of a niche in the host
entry into and exit out of cells
immunoevasion, evasion of the host's immune response
immunosuppression, inhibition of the host's immune
response
obtain nutrition from the host
Toxicity, ability of a pathogen to secrete a toxin

Virulence genes can sometimes be transferred Capsule of Bacillus anthracis
horizontally or acquired through temperate phages prevents phagocytosis by
immune cells
= Lysogenic conversion
Larry Stauffer, Oregon State Public Health Laboratory, USCDCP CC0
 Attenuation - The decrease or loss of virulence
Achieved in vitro through…
1. Culturing the pathogen outside of its host (successive sub-culturing) – “use it or
lose it”
2. Genetic engineering
Gene deletions – mutate or knock out virulence genes or how they are regulated

Achieved naturally through
Natural selection
Successful pathogens need to overcome host defenses long enough to
multiply and then exit host to infect another
If pathogen is too virulent, it causes severe illness/death before it is transmitted
If not virulent enough, host defenses eliminate
The Evolution of Virulence

Successful pathogens need to overcome
Optimal virulence… host defenses long enough to multiply
…more chance and then exit host to infect another
for transmission
If pathogen is too virulent, it causes
severe illness/death before it is
transmitted
If not virulent enough, host defenses
Parasite fitness (R0)

eliminate

High virulence…
No virulence…
…less chance for
…No chance for transmission
transmission

Virulence (mortality rate)
 Red Queen Hypothesis
Pathogens and hosts are constantly struggling to keep up with each
other in an evolutionary arms race

Host susceptibility
high Increased resistance in host,
prevents parasite
reproduction

non-susceptible host
parasite survive, able to Only highly virulent
virulence reproduce strains survive
high (host susceptibility low)

“It takes all the running you can do to stay in the same place”
Lewis Carrol – Through The Looking Glass
 Infection Cycles
▪ The infection cycle describes the route of
transmission of an infectious organism.
Horizontal transmission: passage from
one person or animal to another within
the same generation
― Can be direct (e.g., handshaking) or
indirect (e.g., sharing contaminated
objects)
o Fomite transmission: inanimate objects -
>skin contact (e.g., doorknobs, hand
towels, utensils)
o Vehicle transmission: ingested or inhaled
materials (e.g., food, water, air)

Vertical transmission: passage from a
mother to her fetus during pregnancy
(transplacental) or birth (parturition) © McGraw Hill, LLC
Bab y image: Labora toir es Ser vier
Creative Commons Attribu tion-Sha re Alike 3.0
Infection Cycles
▪ Complex infection cycles often involve vectors as intermediaries (usually arthropods
like mosquitoes, ticks, mites, or flies).
For example, a mosquito vector transfers the virus that causes yellow fever from
infected to uninfected individuals.

Akil Rolle-Rowan/Shutterstock © McGraw Hill, LLC

“Figure 16.12 (a) A mechanical vector carries a pathogen on its body from one host to another, not
as an infection. (b) A biological vector carries a pathogen from one host to another after becoming
infected itself.” from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
Infection Cycles
▪ A reservoir is an animal, bird, or arthropod that normally harbors the
pathogen, often without exhibiting disease.
In the case of yellow fever, the mosquito is not only the vector but the
reservoir as well, because the insect can pass the virus to future
generations of mosquitoes through vertical transmission.
▪ Reservoirs are critically important for the survival of a pathogen and as a
source of infection.
 Some pathogens are more easily transmitted
(contagious) than others

Contagiousness is dependent upon… Pathogen of Infectious Dose
Measles 1 virions
Infectivity -> Infectious dose = the number of microbes
necessary to establish infection (in a healthy individual) Smallpox 10-100 virions
Intestinal shigellosis results from ~10–100 ingested Plague 100-500 cells
Shigella cells
Salmonellosis results from at least 10 6 ingested Anthrax 8,000-50,000 spores
Salmonella cells Typhoid 10,000 cells
Difference partially reflects the ability to survive stomach Cholera 100,000,000 cells
acid
SARS-CoV2 1-7 million virions
Mode of transmission
Ingestion = sometimes larger ID

Ability to survive outside of the host
Biological and abiotic reservoirs
How easily a pathogen spreads in population is measured by Ro
The average number of healthy people that one sick person will infect

R0 of Covid-19 variants and other infectious diseases

Original Covid in Wuhan = 2.4-2.6
Delta = 5-8
Omicron variant = 8.2
Mumps = 12
Measles = 18

Sources:
Lancet, Australian government
J Travel Med. 2022 May 31
 Infection Cycles
The course of infectious disease

Main periods
Incubation period: time between exposure
and onset of illness (signs/symptoms)

Varies considerably: a few days for the
common cold to years for leprosy
Depends on:
1. Generation time of microbe
2. Condition of the host
3. infectious dose

© McGraw Hill, LLC
 Infection Cycles
(Latent)
Course of Infectious Disease

Prodromal Stage – symptoms begin (vague
symptoms – headache, malaise = general
feeling of illness)

Illness: period when signs and symptoms
of disease appear

© McGraw Hill, LLC
 Infection Cycles

Course of Infectious Disease
Convalescence: time when person recovers
from infection – some permanent damage
may occur

© McGraw Hill, LLC
 Infection Cycles

Course of Infectious Disease
Incubation Period: time between exposure and onset of illness (signs/symptoms)

Latent Period: time between exposure and becoming contagious

Pre-symptomatic
Transmission

By Patilsaurabhr - Own work, CC0, https://commons.wikimedia.org/w/index.php?curid=22904276
Infection Cycles
Duration of Symptoms
Acute infections: symptoms develop quickly, last a short time (strep throat)
Persistent infections:
Chronic infections: can develop slowly, last for months/years
Latent infections: similar to acute, but pathogen never eliminated; can reactivate later
Decrease in immunity may allow reactivation
Chicken pox (acute); remain latent in sensory nerves (provirus), reactivated later in life
Varicella-zoster
virus (latent)

By Isabellelyy - Own work, CC BY-SA 4.0,
https://en.wikipedia.org/w/index.php?curid=63628177

Depledge DP, Sadaoka T, Ouwendijk WJD.
Molecular Aspects of Varicella-Zoster Virus
Latency. Viruses. 2018; 10(7):349.
https://doi.org/10.3390/v10070349
icensee MDPI, Basel, Switzerland. This article is
an open access article distributed under the terms
and conditions of the Creative Commons
Attribution (CC BY) license
(http://creativecommons.org/licenses/by/4.0/).
 Infection Cycles
Acute infections
Are a result of productive infections (pathogen replication occurs immediately)
- Analogous to lytic phage
Usually short in duration (days-weeks)
Host may develop long-lasting immunity
Disease signs & symptoms result from tissue damage, infection of new cells, and immunopathogenesis

By Isabellelyy - Own work, CC BY-SA 4.0,
https://en.wikipedia.org/w/index.php?curid=63628177
Infection Cycles
Persistent infections
are a result of the pathogen continually present in the host

Two types
1. Chronic infections - continuous production of low levels of
virions/cells

2. Latent infections - viral genome (provirus) remains silent in
host cell; can reactivate
 Categories of Animal Virus Infections

Latent infections:
Herpes Simplex Virus
Initial infection causes cold
sores, sore throat

Virus moves up cranial nerve
near the brain and becomes
latent in neuron
Provirus integrated into
host chromosome
Cannot be eliminated

Can later be reactivated (may
be due to stress) and move
down nerve to cause cold sore
Verzosa AL, McGeever LA, Bhark S-J, Delgado T, Salazar N and Sanchez EL (2021) Herpes Simplex Virus 1 Infection of Neuronal and Non
Neuronal Cells Elicits Specific Innate Immune Responses and Immune Evasion Mechanisms.Front. Immunol. 12:644664. doi:
10.3389/fimmu.2021.644664 Creative Commons Attribution License (CC BY).
Infection cycles
Localized infection: microbe limited to small area (boil caused by
Staphylococcus aureus)

Systemic infection: agent spread throughout body (measles) –
circulatory/lymphatic system
Usually cause severe fever, fatigue – a result of systemic immune response
Bacteremia - bacteria circulating in blood
Toxemia
Viremia
Sepsis: acute, life-threatening inflammation caused by infectious agents or
products in bloodstream
Identifying the pathogen of an infectious disease
Koch’s Postulates
1. Microorganism must be present
in every case of disease & not
healthy hosts

2. Organism must be grown in
pure culture from diseased host

3. Same disease must be
produced when pure culture is
introduced into susceptible
hosts

4. Organism must be recovered in
culture from experimentally
infected host

© McGraw Hill, LLC
Establishing the Cause of Infectious Disease

Koch’s Postulates (LIMITATIONS)
1. Microorganism must be present in every case of disease (not healthy hosts)
Subclinical infection -> carriers (Infected individuals do not always
display symptoms)

1. Organism must be grown in pure culture from diseased host
Some organisms cannot be grown in laboratory medium (ex:
Treponema pallidum)
2. Same disease must be produced when pure culture is introduced into susceptible
hosts
Suitable animal hosts not always available for testing
Subclinical infection may occur
1. Organism must be recovered in culture from experimentally infected host
Establishing the Cause of Infectious Disease

Molecular Koch’s Postulates
Rely on studying virulence factors (gene or product-toxin, protein, etc.)

1. Virulence gene or product is found in all pathogenic strains of organism

2. Mutating virulence factor gene to disrupt function should reduce
virulence

3. Reversion or replacement of gene should restore virulence to the strain

Limitation: often requires culturing (less so with current technology)
Mechanisms of Pathogenesis
From a microbe’s perspective the interior of the human body is a
rich source of nutrients guarded by the innate and adaptive
immune system

The ability to get past host defenses is what distinguishes pathogens
from other microbes
Mechanisms of Pathogenesis
▪ To cause disease, all pathogens must...
Enter a host
Find their unique niche
Avoid, circumvent, or subvert normal host defenses
Multiply
Transmit to a new susceptible host
Infection cycles
Localized infection: microbe limited to small area (boil caused by
Staphylococcus aureus)

Systemic infection: agent spread throughout body (measles) –
circulatory/lymphatic system
Usually cause severe fever, fatigue – a result of systemic immune response
Bacteremia - bacteria circulating in blood
Toxemia
Viremia
Sepsis: acute, life-threatening inflammation caused by infectious agents or
products in bloodstream
 Mechanisms of Pathogenesis
Pathogenic mechanisms follow
several general patterns:
1. Produce toxins that are ingested
Microbe does not grow on or in host
Produces toxins that are ingested -
foodborne intoxication CDC/ George Lombard Public Domain

Clostridium botulinum grows in
canned foods, produces the
neurotoxin botulinum

2. Colonize mucous membranes,
multiplies, and produce toxins
E. coli O157:H7 grows in intestines
produces shiga toxin and causes
bloody diarrhea CDC/ Debora Cartagena Public Domain

Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
 Pathogenic mechanisms follow several general patterns:
3. Invade host tissues (typically wound) and then produce toxins
Clostridium tetani causes tetanus
Bacteria colonize wound and secrete tetanospasmin – carried to neuron cells in spinal cord
and prevents inhibitory interneurons actions -> prevents muscle relaxation

“Figure 15.16 Mechanisms of botulinum and tetanus toxins. (credit micrographs: modification of work by Centers for Disease Control and Prevention)” from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
Pathogenic mechanisms follow several
general patterns:
4. Avoid host defenses (macrophages and
antibodies), invade host tissues & multiply

Yersinia pestis
Virulence factors turn off killing
ability of macrophages once inside
them; then they multiply
Infected macrophages dies and
release bacteria

Mycobacterium tuberculosis
Macrophages engulf TB cells but are
unable to destroy because of the
mycolic acids in cell wall prevents
fusion of phagosome with lysosome
Bacteria leave phagosome and
multiply within macrophage
© McGraw Hill, LLC
 Infection Process
Exposure
Pathogen must be
exposed to suitable
tissue

Adherence
First line of host defense
is to sweep microbes
away – how do they stick
around to cause disease?
Pathogens must adhere
to body/mucosal surface

By Uhelskie - Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=53717337
 Establishing Infection
Adherence
Any microbial factor that promotes
attachment is called an adhesin
Viruses attach to host cells through spikes.
Bacteria use a variety of strategies,
including pili (fimbriae) and other nonpilus
proteins, to bind to specific host cell factors.
Often located at the tips of fimbriae
Can also be a component of capsules or
various cell wall proteins – nonpilus

Adhesins attach to host cell receptor
Host receptors are usually glycoproteins or
glycolipids on the cell surface

© McGraw Hill, LLC
 Establishing Infection
Adherence

Binding highly specific
Dictates what type of cell the pathogen
can adhere to
Ex: common E. coli cells have adhesins that
allow them to adhere to cells that line the
large intestine
Pathogenic E. coli strains have adhesins
(FimH) at the tips of fimbriae (Type I pilus)
that allow them to bind to additional
tissues
urinary tract infection E. coli –
fimbriae that attach to the bladder
Strains that cause diarrhea can attach
to cells in the small intestine

Image 1 By Chen, J.; Dai, W.; Wang, H.; Lei, W.; Fang, G.; Dai, D. Cloning and Expression of Pigeon-Derived Escherichia coli Type 1 Pilus Clusters and Analysis of Amino Acid Sequence Characteristics of Functional Proteins. Genes 2024, 15, 1253. https://doi.org/10.3390/genes15101253 CCBY
Image 2 By Peteruetz - PPT, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=56465855
 Nonpilus Adhesins
▪ Bacteria also possess adhesins that are
not fimbriae.
Streptococcus pyogenes: M protein
― Binds to fibronectin

Bordetella pertussis: pertactin
― Binds to host cell integrin

Pseudomonas aeruginosa:
multivalent adhesion molecule 7
(MAM7)
― Binds to phospholipids and
fibronectin in host cell membranes

© McGraw Hill, LLC
Biofilms and Infections
▪ Bacteria can attach to surfaces as
a population, forming a biofilm.
▪ Biofilms play an important role in
chronic infections by enabling
persistent adherence, resistance
to host defenses, and tolerance
to antimicrobial agents.

© McGraw Hill, LLC
Adherence
▪ Why are some people susceptible to certain infections, whereas
others are not?
Immunocompetence
Receptor availability
▪ Pathogens rely on very specific surface structures (receptors) to
recognize and attach to appropriate host cells.
Person-to-person differences in receptor structures are possible.
Example: HIV binds C-C chemokine receptor type 5 (CCR5);
individuals with a CCR5 mutation are resistant to HIV infection!
 Invasion—Breaching the
Anatomical Barriers

Some pathogens can cause disease
while remaining on the mucosal
surfaces (by producing toxins) others
must penetrate anatomical barriers
Once inside, the microbe multiplies in
nutrient-rich tissues without competition

Penetrating the Skin
Most difficult barrier to penetrate
Some bacteria rely on injuries
Staphylococcus aureus enters via cut or
wound;
Others via vectors
Yersinia pestis invades via flea bite

“Figure 16.13 (credit “Black fly”, “Tick”, “Tsetse fly”: modification of work by USDA; credit: “Flea”: modification
of work by Centers for Disease Control and Prevention; credit: “Louse”, “Mosquito”, “Sand fly”: modification of
work by James Gathany, Centers for Disease Control and Prevention; credit “Kissing bug”: modification of work
by Glenn Seplak; credit “Mite”: modification of work by Michael Wunderli)” from Parker et al. 2022 OpenStax
Infection figure by Uhelskie - Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=53717337
Microbiology CC BY 4.0.
 Invasion—Breaching the
Anatomical Barriers
Penetrating Mucous Membranes
Entry point for most pathogens

Directed Uptake by Cells By NIAID: These high-resolution (300 dpi) images may be downloaded directly from this
site., Public Domain, https://commons.wikimedia.org/w/index.php?curid=450281

Pathogen induces cells to engulf via
endocytosis after attachment to cell
Salmonella uses type III secretion
system (T3SS -injectisome) to
deliver effector proteins to intestinal
epithelial cell
Causes the host cell’s actin
molecules to rearrange leading
to ruffling of the membrane,
ruffles enclose bacteria,
bringing them into the cell

© McGraw Hill, LLC
 Invasion—Breaching the
Anatomical Barriers
Penetrating Mucous Membranes
Exploiting Antigen-Sampling Processes
Simplified overview of how the adaptive immune
system works
Lymphatic system brings lymphocytes into contact
with antigens

Sites where lymphocytes gather to contact antigens
Lymph nodes, spleen, tonsils, Peyer’s patch

Peyer’s patches allow host to sample contents from
lumen of intestine
Microbes enter Peyer’s patch via M cell
Macrophage destroys microbes and presents
antigens to B cells and T cells, which make
antibodies

Tindemans I, Joosse ME, Samsom JN. Dissecting the Heterogeneity in T-Cell Mediated Inflammation in IBD. Cells. 2020; 9(1):110.
https://doi.org/10.3390/cells9010110 Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and
conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
Invasion—Breaching the
Anatomical Barriers
Penetrating Mucous
Membranes
Exploiting Antigen-Sampling
Processes
Most microbes destroyed by
macrophages in Peyer’s patch
Some pathogens use M cells to
cross intestinal barrier
Shigella survives phagocytosis by
macrophages and induces
apoptosis
Causes host cell to polymerize
actin to propel bacteria into
adjacent cells

Other pathogens invade by means
of alveolar macrophages
(Mycobacterium tuberculosis)

© McGraw Hill, LLC
 Establishing Infection
Colonization
A microbe must also multiply in order to colonize the host; To do this the pathogen must:

1. Obtain resources
Ex: Some microbes secrete siderophores that binds/strips and transports iron
Host cells produce lactoferrin and transferrin which bind to iron making it
unavailable to microbes.

Vinuesa, V.; McConnell, M.J. Recent Advances in Iron Chelation and Gallium-Based Therapies for Antibiotic Resistant Bacterial
Infections. Int. J. Mol. Sci. 2021, 22, 2876. https://doi.org/10.3390/ijms22062876 Licensee MDPI, Basel, Switzerland. This article is
an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license
(http://creativecommons.org/licenses/by/4.0/).
Establishing Infection
Colonization
2. Compete with normal
microbiota
Outcompete others for
space and nutrients
Tolerate antimicrobials
produced by normal
microbiota

Pathogens can grow in biofilms to
circumvent these obstacles

© McGraw Hill, LLC
 Establishing Infection
Colonization
A microbe must also multiply in
order to colonize the host; To do
this the pathogen must:

3. Deal with/avoid host
defenses

© McGraw Hill, LLC
 Avoiding the Host Defenses
Avoiding Destruction by Phagocytes – many mechanisms:
Phagocytes - Major role in innate immunity – they eliminate invading microbes. Contribute to adaptive
immunity - present antigens to lymphocytes.

i. Microbes invade -> complement system activated
ii. C5a secreted -> phagocytes attracted
iii. microbes covered in C3b
iv. Phagocytes destroy microbes

llustration of Enhanced Attachment of Bacteria to Phagocytes by the Opsonin C3b.jpg by Gary E. Kaiser,
Ph.D. This work is licensed under a Creative Commons Attribution 4.0 International License. Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
 Avoiding the Host Defenses
Avoiding Destruction by Phagocytes – many mechanisms:
1. Preventing Encounters with Phagocytes
Secrete C5a peptidase - degrades the chemoattractant C5a (recruits phagocytes)
Streptococcus pyogenes

Secrete streptolysin O -
membrane-damaging toxin kill
phagocytes, other cells
S. pyogenes

Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
 Avoiding the Host Defenses

2. Avoiding Recognition and Attachment
Phagocytes recognize and engulf foreign material more efficiently when coated by c3b or
antibodies

Bacterial capsules
(Streptococcus pneumoniae)
and M protein (S. pyogenes)
inactivate C3b receptors on
phagocytes

a) modification of work by Centers for Disease Control and Prevention) from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
 Avoiding the Host
Defenses
2. Avoiding Recognition and Attachment

Consequences of Antigen-Antibody Binding
Precipitation
Formation of immune complexes when antibodies (Abs) bind to
soluble antigens (Ag).
Effect: Results in visible precipitate, aiding in immune recognition.
Opsonization
Antibodies bind to antigens on cells, making them easier for
phagocytes to recognize.
Effect: Enhances phagocytosis, improving immune response
efficiency.
Agglutination
Antibodies cross-link antigens, creating large, insoluble complexes.
Effect: Traps pathogens, limiting their mobility and making them
easier to eliminate.
Complement Fixation
Immune complexes activate the complement cascade.
Effect: Leads to lysis of bacterial cells, increasing pathogen
destruction.
Neutralization
Antibodies bind to toxins or viruses, blocking them from binding to
host cells.
Effect: Prevents infection and neutralizes pathogenic toxins.

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 Avoiding the Host Defenses
2. Avoiding Recognition and Attachment
Fc receptors & Protein A – proteins that bind Fc region of
antibodies
Normally, Fab region (of antibody) attaches to
bacteria/antigen and Fc region sticks out and serves as
marker for phagocytes
If Fc region binds to bacteria, then phagocytes cannot
recognize
Staphylococcus aureus, Streptococcus pyogenes

© McGraw Hill, LLC
Avoiding the Host Defenses
2. Avoiding Recognition and Attachment
IgA protease: cleaves the antibody IgA (found in
mucus and other secretions)
Produced by Neisseria gonorrhoeae and
others

Antigenic variation: alter structure of surface
antigens
Stay ahead of antibody production by altering
the molecules that antibodies recognize
Neisseria gonorrhoeae varies antigenic
structure of pili

Mimicking host molecules: cover surface with
molecules similar to those found in host cell,
appear to be “self”
Streptococcus pyogenes form capsule composed
of hyaluronic acid, a polysaccharide found in
human tissues

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 Avoiding the Host Defenses
3. Avoiding Destruction by Phagocytes
Some bacteria use phagocytes to hide
from antibodies and as mechanism to
be transported throughout body

Surviving Within Phagocytes
Escape from phagosome: before it fuses
with lysosomes and then can multiply
within cytoplasm of phagocyte
Listeria monocytogenes forms pores in
phagosome membrane
Shigella species lyse phagosome

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 Avoiding the Host Defenses
3. Avoiding Destruction by Phagocytes
Surviving Within Phagocytes
Prevent phagosome-lysosome fusion: avoid
destruction
Mycobaterium tuberculosis prevents fusion
of phagosome with lysosome via mycolic
acid

Survive within phagolysosome: few can
survive destructive environment
Coxiella burnetii (causes Q fever) survives
phagolysosome

© McGraw Hill, LLC
Damage to the Host
Damage due to infection can be the result of direct or
indirect effects
Direct = toxins produced
Indirect = immune response (immunopathogenesis)

Damage typically helps the pathogen to exit the host and spread
to others
Vibrio cholerae induces diarrhea which contaminates water supplies
Bordetella pertussis triggers severe coughing, and pathogens are released
into the air
Toxins Subvert Host Functions
▪ Bacterial toxins can be divided into two main types.
1. Exotoxins
― Proteins produced and secreted by various types of bacteria
― Kill host cells and unlock their nutrients

2. Endotoxin
― A part of lipopolysaccharide (LPS) of Gram-negative bacteria
― Hyperactivate host immune systems to harmful levels
 Damage to the Host
Bacteria produce exotoxins:
proteins with specific tissue-
damaging effects

Either secreted or leaked into
tissue following bacterial lysis
Pathogen must colonize and
multiply in great numbers to
produce enough toxin
Foodborne intoxication results from
consumption of toxin
Ex: C. botulinum grows in food,
produces toxin, consumed by
animal – even tiny amounts can
type II secretion system - Proteins to be secreted
cause paralysis
first enter the periplasm, then they get folded and
secreted via an outer membrane pore.

© McGraw Hill, LLC
The type III secretion system
(T3SS) is a reengineered
flagellar synthesis mechanism
that uses a molecular syringe
to inject proteins from the
bacterial cytoplasm directly
into the host cell.
Secretion is normally
triggered by cell-cell contact
between host and bacterium.
Found in Salmonella, Yersinia,
Shigella, and Escherichia
species.

© McGraw Hill, LLC
Damage to the Host
Antigenic - Because exotoxins are proteins, the immune system can
generate neutralizing antibodies
Vaccines are critical because toxins can cause death before a natural immune
response occurs
Toxoids (inactivated toxins – via heat/chemical) are injected and cause the production of
specific toxin-inhibiting antibodies (botulism, diphtheria, pertussis, tetanus)
Antibodies will immediately bind if toxin is encountered again

Antitoxin is suspension of neutralizing antibodies and can be taken if person
develops symptoms of toxin-mediated disease

Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
Damage to the Host
Exotoxins can be grouped into functional categories according to the
tissues they affect:
Neurotoxins damage nervous system
Enterotoxins cause intestinal disturbance
Cytotoxins damage variety of cell types by either interfering with cellular
mechanisms or lysing cells

Exotoxins can also be categorized by their structure and mechanism of
action:
A-B toxins
Membrane-damaging toxins
Superantigens
Damage to the Host
A-B toxins have two parts
A (active) subunit is toxic, usually an
enzyme and is responsible for the
effects on the host cell
B (binding) subunit binds to cell,
determines cell type to be infected
Structure of A-B toxins allows novel
approaches for vaccines and
therapies
Ex: researchers are developing
medications attached to B subunits to
deliver medications directly to specific
cells
Ex: B subunit of cholera toxin is used as
vaccine against cholera toxin
© McGraw Hill, LLC
 Two-Subunit AB Exotoxins
Diphtheria Toxin Structure and Mechanism of Action

Diphtheria toxin is a two-subunit AB toxin.
The B subunit binds to a host cell receptor, facilitating
entry of the A subunit.
The A subunit inhibits protein synthesis by ADP-
ribosylating EF-2.

© McGraw Hill, LLC
Membrane-Damaging Toxins
▪ Some exotoxins disrupt host cell membranes
by forming pores that cause leakage of cell
constituents (host cell lysis).
Hemolysins lyse red blood cells (and
sometimes other cells).
Leukocidins lyse white blood cells
(leukocytes).
Some membrane-disrupting exotoxins
function as both hemolysins and
leukocidins.
― Streptolysin O of Streptococcus pyogenes

© McGraw Hill, LLC
Membrane-Damaging Toxins
▪ Two types of exotoxins disrupt host cell membranes.
Pore-forming toxins insert themselves into membranes, form pores (channels) that allow
fluids to enter/exit the cell
o Alpha toxin of Staphylococcus aureus

Phospholipase enzymes hydrolyze phospholipids into fatty acids, lyse cells
o Phospholipase C of Clostridium perfringens

© McGraw Hill, LLC
 Damage to the Host
Superantigens:
Proteins (exotoxins) produced by bacterial cells that…
Stimulate production of helper T cells (TH cells)
TH cells secrete cytokines which increase the activity of other immune cells
Overstimulation causes a “cytokine storm”
Leads to overactive immune response – causing fever, nausea, vomiting, diarrhea, organ
failure, and circulatory collapse

Examples Include: toxic shock syndrome toxin and several other toxins from Staphylococcus
aureus

highly specific interaction SAg circumvents
Abdurrahman G, Schmiedeke F, Bachert C, Bröker BM, Holtfreter S. Allergy—A New Role
for T Cell Superantigens of Staphylococcus aureus? Toxins. 2020; 12(3):176.
normal interaction
https://doi.org/10.3390/toxins12030176 Licensee MDPI, Basel, Switzerland. This article is by crosslinking APC
an open access article distributed under the terms and conditions of the Creative
Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). with T cell
Damage to the Host
Superantigens:
Proteins (exotoxins) produced by bacterial
cells that…
Stimulate production of helper T cells (TH
cells)
TH cells secrete cytokines which increase
the activity of other immune cells
Overstimulation causes a “cytokine storm”
Leads to overactive immune response
– causing fever, nausea, vomiting,
diarrhea, organ failure, and circulatory
collapse

Examples Include: toxic shock syndrome
toxin and several other toxins from
Staphylococcus aureus

© McGraw Hill, LLC
 Damage to the Host
Endotoxin is the lipid A portion of LPS
(lipopolysaccharide)
Makes up outer layer of the outer
membrane of G- bacteria
As bacteria die, they release endotoxin, a
microbe-associated molecular pattern
(MAMP) molecule that binds to receptors
on macrophages or B cells.
Receptor binding triggers a massive
cytokine release that can trigger fever,
inflammation, shock, and death.
A widespread immune response to LPS can
have harmful effects

© McGraw Hill, LLC
 Damage to the Host
Endotoxin
Lipid A triggers inflammatory response
When localized, response helps clear infection
When systemic, causes inflammation
throughout the body
Called septic shock or endotoxic shock
Lipid A only causes response when released
following cell lysis of bacteria as a result of
phagocytosis or antibiotics
Lipid A is heat-stable; autoclaving does not
destroy
Therefore, solutions intended for IV use must be
not only sterile, but also free of endotoxin Credit: Gregory Breese/USFWS Public Domain

Limulus amoebocyte lysate (LAL) assay – protein
from horseshoe crab blood that surrounds
endotoxin and creates a clot
Damage to the Host
Comparison of Exotoxins and Endotoxin
Exotoxins from Gram-positives and Gram-negatives
Protein; potent; usually heat-inactivated; may or may not be secreted
Endotoxins only from Gram-negatives
Lipid A component of LPS; small localized amounts yield appropriate
response, but systemic distribution can be deadly; heat-stable
Review Questions

1) The microorganisms that are occasionally found in 3) Growth of a pathogen in or on the host is
or on the body are called referred to as
A) normal microbiota. B) abnormal microbiota. A) pathogenism. B) colonization.
C) variant microbiota. D) transient microbiota. C) infection. D) mutualism.

2) The number of organisms necessary to ensure infection is 4) People who carry and may spread pathogenic
termed the organisms without any symptoms of illness are
A) lethal dose. B) pathogenic number. called
C) infectious dose. D) minimum inhibitory concentration. A) mutualists. B) primary infections.
C) secondary infections. D) carriers.