Lecture 1 – Pathogenesis of Microbial Disease PDF

Summary

This document provides a lecture on the pathogenesis of microbial disease covering infection versus infectious disease, normal flora, primary and secondary infections, and the phases of infection. It also discusses bacterial virulence, endotoxins, and exotoxins. The lecture includes thought questions and a section on host-microbe relationships.

Full Transcript

BIOL 2010
Lecture 1 – Pathogenesis of Microbial
Disease
CHAPTER 2
BAILEY AND SCOT T’S – CHAPTER 3
In this lecture
2.0 Pathogenesis of Infectious Disease
2.1 Discuss infection versus infectious disease
2.2 Discuss normal flora and their role in infectious disease
2.3 Describe primary and secondary infection
2.4 Describe the phases of the infectious process
2.5 Explain the characteristics and pathogenesis of commonly encountered clinically
significant microorganisms, including the most frequently isolated species by body
system, under various groupings.
2.6 Discuss bacterial virulence
2.7 Discuss endotoxins and exotoxins
Thought questions
What makes some microbes pathogenic but others non-pathogenic?
If microbes are ubiquitous, and we encounter them all the time, why don’t
we develop more infections?
Host-Microbe Relationships
Symbiosis: two organisms living together
Commensalism: Microorganism benefits while host is not harmed.
Mutualism: Microorganism and host benefit
Parasitism: Microorganism benefits while the host is harmed.

Indigenous (normal) flora: Microorganisms commonly found on or in
healthy persons
Colonization: Refers to the growth of microbiota in or on a body site without causing
damage or notable symptoms
Resident Microbiota: or microorganisms that colonize an area for months or years
Transient flora: Microorganisms temporarily colonizing a host
Carrier state: Condition of hosts capable of transmitting the infection
Host-Microbe Relationships
Host-microbe relationship can be:
Pathogenic: Organism causes a disease
Ex. Salmonella
Nonpathogenic: Organisms which don’t generally cause disease
Ex. Corynebacterium species – indigenous flora of skin
Opportunistic pathogen: Organisms which cause infections when one or more host
defenses are compromised
Ex. Indigenous flora
Carriers: People can carry pathogens in body parts without it causing an
infection/disease
Ex. Many people carry Staphylococcus aureus in their nares, without experiencing an
infection. If this gets passed to another person, they can cause severe infections.
Terms
The degree to which a microorganism can cause disease is called
pathogenicity
Pathogens are therefore highly pathogenic – they often damage the human host
severely
Non-pathogens have low pathogenicity
This distinction is not always clear, as host factors can affect the development of
infections and disease
The degree of pathogenicity is called virulence
Indigenous
Microbiota
in humans
Host-Microbe Interactions
Infection: growth and multiplication of microorganisms that result in
damage to the host
When infection produces notable changes in human physiology = disease occurs
Disease which can be transmitted: Infectious Disease
Host-Microbe Interactions
For an infection to occur, a few things
must occur (Image on right)
Host factors, and an organism’s
pathogenicity/virulence plays a role in
the development of infection
Host-Microbe encounter
Recall: Microbes are everywhere!
Hosts can encounter microbes in a variety of ways, based on
Reservoirs: The origin of the etiologic agent or location from which it disseminates
Mode of Transmission: The means by which etiologic agents are brought in contact
with the human host
Host-Microbe encounter
RESERVOIR TRANSMISSION

Humans Direct – host contacts microbial
Indigenous flora reservoir directly
Infected individuals Ex. birth, sexual contact,

Animals Indirect – host encounters
Ex. through eating meat, animal bites microbe through an agent
Non-living – fomites
Environment
o How HAI are spread
Ex. water, soil Living - vectors
Host-Microbe encounter
Colonization of host surfaces
Colonization can be
Harmless (i.e. become part of flora or transient colonizers)
The last step in the establishment of a long-lasting, mutually beneficial (i.e.,
commensal) or harmless relationship between a colonizer and the human host.
Entry, Invasion and Dissemination
In most instances, to establish infection, microorganisms must penetrate
or circumvent the host’s physical barriers (i.e., skin or mucosal surfaces);
Overcoming these defensive barriers depends on both host and microbial
factors
 Skin

Physical Barriers
Against Initial
Colonization Mucous
= first line of membranes
defense Organ specific
defenses

Overview of
Host Barriers Phagocytes
Coagulation
System
When microbes
penetrate physical Inflammation
barriers
Cytokines

Antibodies
Host barriers
Once a microbe attains contact with a human host, outcome is based on
interaction with host and can lead to colonization
Persistent survival of microbes on a surface of the human body

Host has various defenses to prevent colonization
Nonspecific, physical barriers: The first areas to encounter microorganisms, and
offer first line of defense
Physical surfaces like skin and mucus membranes
Nonspecific barriers
Nonspecific characteristics unique to specific organs
Host barriers - Skin
Skin as a barrier
It is a non-specific defense
Protective factors include:
Dry, acidic, cool outer layer which acts as a
physical barrier
Production of antibacterial substances such as
sebum and sweat
Conjunctiva produces lysozymes in tears
Indigenous flora may also secrete substances
which deter growth of pathogens – microbial
antagonism
Skin-Associated Lymphoid tissue
Host barriers – Mucus Membrane
Mucus membranes as a barrier
It is a non-specific defense – lines respiratory tract,
GI tract and genitourinary tract
Protective factors include:
Rapid sloughing of mucosal cells
Mucus (produced by goblet cells)– helps trap bacteria
Production of antibacterial substances such as
Lactoferrin, Lysozymes, Lactoperoxidase
Mucosa-Associated Lymphoid Tissues (MALT) – consist
of immune cells which respond to bacteria which have
penetrated the membranes
Host barriers –
Mucus
Membranes
Summary of specific
defenses in various parts
of the body’s mucous
membranes
Host barriers – Other nonspecific
barriers
Specific characteristics which deter growth of pathogens
Oral cavity consists of saliva, antibody (IgA), lysozymes and indigenous flora which
confer protection
Stomach has low pH and proteolytic enzymes
Small Intestines have bile salts and resident microbiota
Upper Respiratory tract have cilia
Vaginal lining has a low pH, resident microbiota and a thick mucus plug
Host Barriers - Phagocytes
Host also has various defenses when microbes are successful in
penetrating physical barriers
Phagocytes are white blood cells which ingest and destroy bacteria and
other foreign particles
Process is called phagocytosis

Main cells:
Neutrophils or Polymorphonuclear Neutrophils (PMN)
Monocytes/Macrophages
Dendritic cells

Note: Not all microbes can be targeted by PMNs
Host Barriers - Phagocytes
Host Barriers - Inflammation
Inflammation is a broad term – includes cellular and biochemical
components
Manifestations of inflammation: Swelling, Redness, Heat, Pain

Complement system
Cascade which attracts and enhances the activities of phagocytes OR directly kills bacteria
(via Membrane Attack Complex)
Coagulation System
Walls off the site of infection

Cytokines
Chemical messengers secreted by many immune cells which enhance immune response
Host Barriers - Inflammation
Host Barriers - Antibodies
Antibodies are the central molecule of
the immune system and highly specific
Antibodies (or immunoglobulins)
Secreted by Plasma cells (activated B cells)
in response to a foreign substance
Such as chemicals, toxins, components of
organism’s structures
Usually proteins or polysaccharides
Protect the host if organism is encountered 2nd
or 3rd time – has memory
Circulate in the liquid portion of the host’s
blood, as well as in secretions (ex. saliva)
Overcoming Host Barriers
Despite host barriers, microorganisms can overcome them to colonize
body surfaces and/or cause infection
Colonization can be
Harmless
Ex. Indigenous microbiota
First step in the development of infection
Overcoming Host Barriers
How do microbes overcome host barriers?
Microbes have defenses against ALL host barriers
Defenses against first line of defense (ex. physical barriers)
Virulence factors
Biofilm Formation
 Overcoming Host Barriers
Some host factors can also break the barrier such as:
Trauma
Deep wounds, abrasions – including surgical wounds, needle sticks
Burns
Childbirth

Inhalation
Smoking, toxic gas inhalation

Implantation of Medical Devices
Overuse of Antibiotics
Chronic diseases
Previous infections
Chronic diseases: ex. diabetes
 Overcoming Host Barriers
Microbial Strategies to overcoming first line of defenses:
1. Survival Against Environmental Conditions
Localization in moist areas
Protection in ingested or inhaled debris
Expression of specific metabolic characteristics (e.g., salt tolerance)

2. Achieving Attachment and Adherence to Host Cell Surfaces
Pili
Adherence proteins
Biofilms
Various protein adhesins

3. Other Factors
Motility
Production of substances that compete with the host for acquisition of essential nutrients (e.g., siderophores to capture iron)
Ability to coexist with other colonizing microorganisms
Overcoming Host Barriers –
Virulence Factors
Virulence factors are characteristics which allow pathogens to cause
damage to host.
Most virulence factors protect organism against host attack or mediate
damaging effects on host cells
Virulence factors can be specific to certain pathogenic genera, species or
strains
Knowledge of a microorganism’s capacity to cause infections plays a
major role in the development of clinical microbiology
An organism can possess more than one virulence factor
Overcoming Host Barriers –
Virulence Factors
Virulence factors can cause infection by aiding:
Attachment
Invasion
Survival against Inflammation
Ex. Capsules produced by Streptococcus pneumoniae
Ex. Ability to live inside phagocytes by Mycobacterium tuberculosis
Ex. production of toxins and enzymes which destroy phagocytes, complement proteins
Toxin Production
 Overcoming Host Barriers –
Virulence Factors
Toxins are biochemically active substances released by microorganisms
that have a particular effect on host cells
Endotoxin Exotoxin
Mostly associated with gram-negative bacteria Mostly associated with gram-positive bacteria
o Composed of the lipopolysaccharide portion of cell Produced and released by living bacteria; do not require
envelope bacterial death for release
o Released when a gram-negative bacterial cell is Effects are specific to host cells
destroyed The type of toxin varies with the bacterial species
Effects on host are generalized and can include: Effects can:
o Disruption of clotting, causing clots to form throughout o Kill host cells and help spread bacteria in tissues
the body (i.e., disseminated intravascular coagulation o Destroy or interfere with specific intracellular activities
[DIC]) o Ex. Botulism toxin interferes with neuromuscular
o Fever functions
o Activation of complement and immune systems o Ex. Diphtheria toxin inhibits protein synthesis
o Circulatory changes that lead to hypotension, shock,
and death
Overcoming Host Barriers –
Pathogenicity Islands
Pathogenicity Islands are genomic regions of pathogens which encode
for virulence factors
May be acquired mobile genetic elements

PAIs facilitate the dissemination of virulence capabilities among bacteria
Ex. Antimicrobial resistance genes

PAIs are widely disseminated among medically important bacteria
Ex. E. coli, Pseudomonas aeruginosa, Salmonella spp., Neisseria spp.
Overcoming Host Barriers – Biofilms
A biofilm is an accumulation of microorganisms embedded in a complex matrix
composed of proteins, polysaccharides, extracellular DNA (eDNA), and other molecules
Can be monomicrobic or polymicrobic population of organisms that
Biofilms provide a protective environment for the resident microbes

Clinical relevance:
Biofilm formation on medical implants and prosthetic devices
Biofilms are resistant to treatment

Clinicallly relevant organisms which form biofilms include:
Staphylococcus aureus,
Pseudomonas aeruginosa
Aggregatibacter spp
Candida albicans
Outcome of Infectious Diseases
Outcomes depend on:
State of host’s health
Virulence/Pathogenicity of the pathogen
Whether host can clear pathogen

Types of infections:
Acute – develops rapidly
Chronic—Develops slowly (insidious)
Latent—Silent phase with
no symptoms
Localized – infection in one site
Systemic – infection has spread

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Outcome of Infectious Diseases

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Outcome of Infectious Diseases
A symptom of a disease is defined as some evidence of a disease that is experienced
or perceived by the patient—something that is subjective.
Examples: ache or pain, a ringing in the ears (tinnitus), blurred vision, nausea,
dizziness, itching, and chills.
A sign of a disease is defined as some type of objective evidence of a disease.
Examples: hepatomegaly, splenomegaly, abnormal heart or breath sounds, blood
pressure, pulse rate, and laboratory results as well as abnormalities that appear on
radiographs, ultrasound studies, or computed tomography scans.
Signs and symptoms reflect the stages of infection.

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Outcome of Infectious Diseases
One infectious disease may commonly follow another, in which case the first disease is referred to
as a primary infection and the second disease is referred to as a secondary infection.
Example:
During the primary infection, a virus causes damage to the ciliated epithelial cells that line the
respiratory tract – this causes coughing
While coughing, the patient may inhale some saliva, containing an opportunistic bacterial
pathogen, such as Streptococcus pneumoniae or Haemophilus influenzae.
Because the ciliated epithelial cells were damaged by the virus, they are unable to clear the
bacteria from the lungs. The bacteria then multiply and cause pneumonia.
In this example, the viral infection is the primary infection, and bacterial pneumonia is the
secondary infection.

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Stages of Infectious Diseases

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 Outcome of Infectious Diseases -
stages
1. Incubation period: time that elapses between arrival of the pathogen and the onset of symptoms.
The length is influenced by many factors such as: overall health and nutritional status of the host, the
immune status of the host, virulence of the pathogen, and number of pathogens that enter the body.

2. Prodromal period: the time during which the patient feels “out of sorts” but does not yet experience actual
symptoms of the disease.
Patients may feel like they are “coming down with something” but are not yet sure what it is.

3. Period of illness is the time during which the patient experiences the typical symptoms associated with
that particular disease (e.g., sore throat, headache, and sinus congestion).
Communicable diseases are most easily transmitted during this third period.

4. Convalescent period: time during which the patient recovers.
For certain infectious diseases (Ex. viral respiratory diseases), the convalescent period can be quite long.
Permanent damage may be caused by destruction of tissues in the affected area even after recovery.
Ex. brain damage may follow encephalitis or meningitis
Ex. Paralysis may follow poliomyelitis
Ex. deafness may follow ear infections.
Thought questions - revisiting
You should be able to add to your answers from earlier
What makes some microbes pathogenic but others non-pathogenic?
If microbes are ubiquitous, and we encounter them all the time, why don’t
we develop more infections?