Lecture 4 Microbiology PDF

Summary

Lecture 4 discusses the microbiology of bacterial infections and pathogenesis, covering normal human microbiota, virulence factors, and the pathogenesis of bacterial infections. It also analyses the relationships of microbiota with humans, including symbiotic, commensal, and parasitic interactions.

Full Transcript

Lecture 4

Microbiology: Bacterial Infection &
Pathogenesis

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 Content
Normal human microbiota (Role of the resident
microbiota, and locations in the human body)
Virulence of bacteria, bacterial virulence factors
and their regulation (exotoxin, endotoxin, and
their contribution to pathogenesis). Pathogenesis -
types of bacterial infections, transmission,
adherence , invasiveness, toxin production.
Infection process (development, and outcomes)

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 Morobiota and Microbiome
Although the terms “microbiota” and “microbiome” are
often used interchangeably, Microbiota refers to the
organisms that comprise the microbial community, whereas
the Microbiome refers to the collective genomes of the
microbes, which are composed of bacteria, bacteriophages,
fungi, protozoa, and viruses that live inside and on the
human body.
The microbiota is now considered a human organ, with its
own functions, i.e., modulating expression of genes involved
in mucosal barrier fortification, angiogenesis, and postnatal
intestinal maturation.
The vast majority of microbial species present in microbiota
give rise to symbiotic host–bacteria interactions that are
fundamental for human health.
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 Relationships of microbiota with the
humans
Symbiotic - benefits the host
Commensal – neutral to the host
Parasitic – injuries the host
The members of the normal flora may stay for a highly variable
periods.
Residents are strains that have an established niche at one of the
many body sites, which they occupy indefinitely.
Transients are acquired from environment and establish themselves
briefly, but tend to be excluded by competition from residents or
by innate or immune defense mechanism.
The term carrier state is used when potentially pathogenic
organism s are involved, however their implication of risk are not
always justified. 6
 Normal human microbiota
Typical human body contains about 1012-1013 eukaryotic cells. However,
most of the cells in our body are not our own, nor are they even human.
They are microbial.
Humans house about 1013-1014 microbial cells, at least 10 times more than
eukaryotic cells.
Almost every epithelial surface of our body contains a complex microbial
community: skin, mouth, vagina, and gastrointestinal tract.
Microbes can live even in the highly acidic environment of the stomach
(pH=2).
All these epithelial surfaces are populated by communities of
microorganisms, collectively called microbiota, rather than by individual
species, and often include hundreds and even thousands of different
microbial members.
Majority of these organisms are bacteria, though archaea, fungi,
eukaryotic microorganisms, and viruses also take residence in different
epithelial niches.
Total weight of human microbiota varies from 1 to 3 kg (approximately
1%-3% of the total weight). 7
It's all in our gut (and on our skin): the Human
Microbiome Revolution

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 Functions of microbiota
Renewed interest in the human microbiota is associated with the
recognition of the important relationships these microbes form with our
bodies.
Microbiota is essential for keeping us healthy and happy.
Microbiota of the gut participate in host energy metabolism by breaking
down complex polysaccharides in the diet, protect the host from pathogen
invasion.
Microbiota produces vitamins that we cannot make.
Resident microbes also benefits the body through competition for resources
or directly by inhibiting pathogen growth.
Microbiota modulate the proper development and functioning of the
human immune system, transform or excrete toxic substances, and help
maintain epithelial homeostasis.
Microbiota dysbiosis, defined as the perturbation of the normal microbial
profile, has been linked to a number of human diseases including dental
plaque, bacterial vaginosis, psoriasis, atopic dermatitis, and cystic fibrosis.
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 A Healthy Microbiome is a Healthy
You
Inside each and every one of us, we actually have our own
microbiome. The human microbiome plays an extremely
important role in the regulation of human bodily function.
Helps digest food
Protects against toxins
Boosts the immune system
Promotes skin health
Influences mental health

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 A Healthy Microbiome is a Healthy
You
The human microbiome is extensive and highly variable, serving many
functions in our bodies, the most notable of which are immune system
support and aiding in proper digestion.

Upsets in our bacteria can cause both of these things to fail.

The most skin and internal microbiome we carry with us is wholly
unimportant and generally unknown, however the fact is that it is a massive
part of our livelihood.

Bacterial cells outnumber our own cells by a factor of 10 to 1 i.e. the ratio
between the numbers of human cells and those forming our microbes more
than 10:1.

While the research into the nature of our microbiomes is just beginning
there has already been a large amount of evidence linking a healthy
microbiome to a healthy, or at least healthier, person in general. 11
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 INTERSTING!

Autistic populations have a unique microbiome
consisting of more clostridial species. Half of all
autistic children with gastrointestinal dysfunction
were found to have the bacteria Sutterella which
was completely absent in non-autistic children
with gastrointestinal dysfunction. There is
evidence that for some children with late-onset
autism antibiotics can alleviate symptoms
temporarily.

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 Gut microbiota and Mood
Reading: http://allergiesandyourgut.com/tag/bacteroides-fragilis/
Very good news! An exciting new field of medicine is on the horizon:
PSYCHOBIOTICS.
PROBIOTICS are micro-organisms that have beneficial effects on the body when
consumed

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 Colonization vs infection
Colonization: establishment of a site of reproduction of
microbes on a person without necessarily resulting in tissue
invasion or damage.
Infection: growth and multiplication of a microbe in or on
the body of the host with or without the production of
disease.
Outcomes of exposure to a microorganism:
1. Transient colonization
2. Permanent colonization
3. Disease
4. Normal Flora and
5. Pathogenesis

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 Microbiota at different sites
Sites that may be colonized:
Respiratory tract and head:
Blood, body fluids and Outer ear,
tissues are sterile. Eye
Nasopharynx
Sterile sites: Oral cavity
sinuses, Skin
Oropharynx
middle ear
Lungs
brain Gastrointestinal tract
lower respiratory tract esophagus,
stomach,
(trachea, bronchiole, lungs)
small intestine,
bladder large intestine
cervix Genitourinary system
Vagina
uterus Urethra
Penis
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 Oral cavity
Researchers have identified some 700 microbial species that inhabit the human mouth.
Oral bacteria include:
1. Streptococcus viridans
2. Lactobacilli
3. Staphylococci (S. aureus and S. epidermidis)
4. Corynebacterium sp.
5. Bacteroides sp.
6. Streptococcus sanguis (dental plaque)
7. Streptococcus mutans (dental plaque)
8. Actinomyces sp

Accumulating evidence suggests that the structure of this microbiome “is not haphazard or
random. Among other things there is [a] first layer of microorganisms that allows for the
attachment of the second-comers, the third-comers, the fourth, and so on, in a very
hierarchical type of organization.
“(http://www.the-scientist.com/?articles.view/articleNo/40600/title/The-Body-s-Ecosystem
/)

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 Oral
Microbiota

Oral bacteria have been
implicated in cardiovascular
disease, pancreatic cancer,
colorectal cancer,
rheumatoid arthritis, and
preterm birth, etc.

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 Normal microbiota of upper and low
respiratory tract
Upper respiratory tract
1.Staphylococcus epidermidis
2. Corynebacterium
3. Staphylococcus aureus
4. Neisseria sp.
5. Haemophilus sp
6. Streptococcus pneumoniae
The lower respiratory tract (trachea,
bronchi, and pulmonary tissues):
Usually sterile.
The individual may become susceptible to
infection by pathogens descending
from the nasopharynx e.g.
H. influenzae
S.pneumoniae 20
 Lung microbiota
There’s a constant flow into [the] lungs of aspirated bacteria from the
mouth, but through the action of cilia, the cough reflex, and other
cleansing responses, there’s also an outward flow of microbes, making the
lung microbiome a dynamic community.

The lung microbiome is about 1,000 times less dense than the oral
microbiome, and about 1 million to 1 billion times sparser than the
microbial community of the gut.

Lungs are like small islands of clustered bacteria and wide stretches of
unpopulated regions between them. That is in part because the lung lacks
the microbe-friendly mucosal lining found in the mouth and
gastrointestinal tract, instead harboring a thin layer of much-less-inviting
surfactant to keep the respiratory organs from drying out, as well as
ciliated cells that beat rhythmically to move debris and invading microbes.

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 Skin microbiota
Propionobacterium
Corynebacterium
(diphteroides)
Staphylococcus
(coagulase-negative)

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 Normal microbiota of skin
The most important sites are:
1.Axilla
2.Groin
3.Areas between the toes

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 Non-health related application of
microbiome
The microbiome has non-health related applications as well.
The diversity of our skin microbiome is extensive, with a
higher degree of diversity between individuals than
that of our DNA. This uniqueness presents an
interesting opportunity in the world of forensics.
Since the skin microbiome is so diverse, it is actually a more
reliable way of telling people apart than fingerprints –
provided people live in the same general location during
a crime.
Microbe samples can be found on all sorts of surfaces where
fingerprints might not be viable; and an individual
microbiome can be matched to that person with a high
degree of certainty. While it certainly won’t replace
fingerprints, skin microbiome profiling can add a new
layer of evidence, and help bring criminals to justice.

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 Skin microbiota
Helococcus kunzii is a recently identified bacterium
that is thought to be a nonpathogenic member of
normal human skin flora and is rarely associated with
skin infections. In the study though, the researchers
report the isolation of the organism from an infected
cyst on the breast of a 57-year-old
immunocompromised woman.
Finding provides further support for the opportunistic
role of H. kunzii in causing infection in both
immunosuppressed and healthy people (A.H. Chagla,
A.A. Borczyk, R.R. Facklam, and M. Lovgren. 1998.
Breast abscess associated with Helocococcus kunzii.
Journal of Clinical Microbiology. 36:2377-2379.)
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Intestinal microbiota

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give us an information
about the sex of the
person

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 Genitourinary tract microbiota
In women In men
Lactobacillus spp. Lactobacillus
Lactobacillus iners, L. crispatus, Streptococcus
L. gasseri, or L. jensenii. Prevotella
Fusobacterium
These Lactobacillus sp. are thought to
play key protective roles by
lowering the environmental pH
through lactic acid production and
by producing various
bacteriostatic and bacteriocidal
compounds.
However, the composition of the
vaginal microbiome largely differs
by age and ethnicity.

Cause of vaginitis
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When do we get colonized with normal
microbiota?
A human first becomes colonized by a normal
flora at the moment of birth and passage through
the birth canal.
In uterus, the fetus is sterile, but when the
mother's water breaks and the birth process
begins, so does colonization of the body surfaces.
Handling and feeding of the infant after birth
leads to establishment of a stable normal flora on
the skin, oral cavity and intestinal tract in about 48
hours.

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 Development of microbiota
Originally, the intestine was thought to be
sterile during fetal life, however the result of
recent studies are changing these views.
When present in the uterine compartment,
some bacteria such as Ureaplasma spp. and
Fusobacterium spp. appear to be the most
significantly associated with negative
pregnancy outcomes (e.g., prematurity).

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 Development of microbiota
Upon delivery, the neonate is exposed to microbes from a
variety of sources, including maternal vaginal, fecal, and skin
bacteria.

Initial colonization of the infant gut is highly influenced by the
mother’s vaginal and fecal bacterial communities, which
include facultative anaerobes such as streptococci and
enterobacteriaceae.

The first and most important phase of normal colonization
occurs when the newborn fetus passes through the birth
canal and ingests maternal vaginal and colonic
microorganisms.
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 Development of microbiome
The process of natural birth
introduces the mother’s gut
and vaginal microbes and
shortly after birth, we’re
exposed to the skin
microbiome as well. This is a
vital process for a healthy
immune system, and, as it
turns out there are much
higher rates of allergies and
asthma in children born
through C-sections, a sterile
process allowing the newborn
to be exposed to only the
mother’s skin microbiome
(Pollan 2013)

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 Development of microbiota
Infants delivered by cesarean section have a reduced
number of bacteria compared with vaginally
delivered infants, and colonization by bifidobacteria
can be delayed by up to 6 months.

The microbiota of vaginally delivered infants mirrors
the mother’s vaginal and intestinal microbiota. These
infants exhibit bacterial communities composed of
prominent genera such as Lactobacillus, Prevotella,
Escherichia, Bacteroides, and Bifidobacterium.

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 Role of microbiota in defense

Intestinal mucosal barrier function can be defined as the capacity of the intestine to host the
commensal bacteria and molecules, while preserving the ability to absorb nutrients and prevent the
invasion of host tissues by resident bacteria.
The dense communities of bacteria in the intestine are separated from body tissues by a monolayer of
intestinal epithelial cells.
The assembly of the multiple components of the intestinal barrier is initiated during fetal
development and continues during early postnatal life.

Collectively, the gut microbiota also influences tissue regeneration, permeability of the
epithelium, vascularization of the gut, and tissue homeostasis.

Pic from: http://journal.frontiersin.org/article/10.3389/fimmu.2012.00310/full
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 Factors disrupting microbiota
Epidemiological studies have established, an association
between the mode of delivery or the use of antibiotics and
the occurrence of health disorders or diseases.

The use of cesarean section delivery has markedly increased
in the past 2 decades in a large number of middle- and
high-income countries in the world, reaching an
unprecedented level of 50.1% in Brazil in 2009.

Although these operations can be lifesaving, both for
mother and child, there is concern that increasing rates also
may have short- and long- term deleterious effects. Studies
suggested that children delivered by cesarean section could
have increased risk later in life of atopy and allergies,
asthma, and type 1 diabetes.
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 Factors influencing microbiota
The makeup of the normal flora may be influenced by various
factors, including genetics, age, sex, stress, nutrition and diet of
the individual.

Three developmental changes in humans, weaning, the Vaginal dryness
eruption of the teeth, and the onset and cessation of ovarian
functions, invariably affect the composition of the normal flora
in the intestinal tract, the oral cavity, and the vagina,
respectively. However, within the limits of these fluctuations,
the bacterial flora of humans is sufficiently constant to a give
general description of the situation

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, weaning eruption of the teeth
 Factors Affecting Normal Flora
1. Local Environment
(pH, temperature, redox
potential, O2, H2O, and
nutrient levels…).
2. Diet
3. Age
4. Health condition
(immune activity…)
5. Antibiotics,…..etc

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 Factors disrupting microbiota
Antibiotic usage changes gut microbiota. For example,
administration of broad-spectrum antibiotics
significantly reduced the relative abundance of
Bacteroides, with a concurrent increase in Firmicutes.

The understanding of the dynamics and mechanisms
that underlie functional changes in the microbiome in
response to antibiotic treatments remains limited. The
response depends on the type of antibiotics, length of
dosing, and baseline microbiome.

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 Fecal bacteriotherapy
Fecal bacteriotherapy, which is now
officially and scientifically known as
fecal micro biota transplantation
(FMT) and is also referred to as fecal
micro biota therapy, fecal transfusion,
fecal transplant, stool transplant,
fecal enema or human probiotic
infusion (HPI), is a medical treatment
for patients with pseudomembranous
colitis (caused by Clostridium
difficile), or ulcerative colitis that
involves restoration of colon
homeostasis by reintroducing normal
bacterial flora from stool obtained
from a healthy donor

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 Fecal transplantation
Like an organ transplant, fecal
microbiota transplantation begins
with finding a donor, often a family
member.
The treatment team collects a fresh
stool sample, at least 200 to 300
grams.
The sample is mixed with salt water
in a blender and filtered to remove
particulate matter.
It can be administered to the
recipient through a colonoscopy, as
an enema, or -- when the inflamed
region is higher in the colon --
through a naso-gastric tube 41
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 Robert Koch’s postulates
That the organism could be
discoverable in every instance of the
disease;

That, extracted from the body, the germ
could be produced in a pure culture,
maintainable over several microbial
generations.

That the disease could be
Koch's postulates are four criteria designed reproduced in experimental animals
to establish a causative relationship between through a pure culture removed by
a microbe and a disease - a sequence of numerous generations from the
experimental steps that verified the germ organisms initially isolated;
theory.
He identified cause of anthrax, TB, and That the organism could he
cholera retrieved from the inoculated
animal and cultured a new.
Developed pure culture methods 43

 Pathogenicity
A pathogen is a microorganism that is able to cause disease in a plant,
animal or insect.
Pathogenicity comes from Greek “patho” disease and “gene” – creation.
Pathogenicity is a step-by-step ability to produce disease in a host
organism.
Virulence is a degree of pathogenicity
Determinants of virulence of a pathogen are any of its genetic or
biochemical or structural features that enable it to produce disease in a
host.
The relationship between a host and a pathogen is dynamic, since each
modifies the activities and functions of the other.
The outcome of such a relationship depends on:
the virulence of the pathogen and
the relative degree of resistance or susceptibility of the host, mainly due
to the effectiveness of the host defense mechanisms.
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 Mechanisms of bacterial pathogenicity
Invasiveness: the ability to invade tissues
encompasses mechanisms for colonization
(adherence and initial multiplication),
production of extracellular substances which
facilitate invasion (invasins) and ability to
bypass or overcome host defense mechanism.

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 Number of invading microbes
LD 50 - Lethal Dose of a microbes or toxin that will kill
50% of experimentally inoculated test animal within
a certain period of time
ID 50 - Infectious Dose required to cause disease in
50% of inoculated test animals
Example:
ID 50 for Vibrio cholerea 10 8 cells (100,000,000 cells)
ID 50 for Inhalation Anthrax - 5,000 to 10,000 spores
ID for E.coli O157:H7 - < 10 cells

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 How bacteria overcomes host defense?
1. Adherence - almost all pathogens have the means to
attach to host tissue binding sites through adhesins
and ligands
2. Capsules
3. Enzymes
A. Leukocidins
B. Hemolysins
C. Coagulase
D. Kinases
E. Hyaluronidase
F. Collagenase
G. Necrotizing Factor 48
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 Adherance
Surface molecules on a pathogen, called adhesins or ligands,
bind specifically to complementary surface receptors on cells
of certain host tissues.
Adhesins and ligands are usually on Fimbriae
Examples: Neisseria gonorrhoeae, ETEC (Entertoxigenic E.
coli), Bordetella pertussis , etc.

Adhesin/ligand

Cell surface

Cell receptor

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 Capsule –prevent phagocytosis
Examples:
Streptococcus
pneumoniae
Klebsiella pneumoniae
Haemophilus influenzae
Bacillus anthracis
Streptococcus mutans
Yersinia pestis
Klebsiella pneumoniae

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 Enzymes
Many pathogens secrete enzymes that contribute to their pathogenicity
A. Leukocidins - Attack certain types of WBC’s
1. Kills WBC’s which prevents phagocytosis
2. Releases & ruptures lysosomes that contain powerful hydrolytic enzymes
which then cause more tissue damage
B. Hemolysins - cause the lysis of RBC’s Streptococci
1. Alpha Hemolytic Streptococci - secrete hemolysins that cause the incomplete
lysis or RBC’s
2. Beta Hemolytic Streptococci - Secrete hemolysins that cause the complete
lysis of RBC’s

Action of
Hemolysins

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 Enzymes
C. Coagulase - cause blood to coagulate
Blood clots protect bacteria from phagocytosis from WBC’s and
other host defenses.
Staphylococci - are often coagulase positive

Negative

Positive 53
 Enzymes
D. Kinases - enzymes that dissolve blood clots
1. Streptokinase - Streptococci
Streptokinase - used to dissolve blood clots in the Heart (Heart Attacks due to
obstructed coronary blood vessels)
1. Staphylokinase - Staphylococci - Helps to spread bacteria causes
Bacteriemia
E. Hyaluronidase - Breaks down Hyaluronic acid (found in connective tissues)
It is known as “Spreading Factor”
Use of Hyaluronidase - Mixed with a drug to help spread the drug through a
body tissue
In cosmetics Hyaluronidase is used to dissolve the skin fillers.

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 Enzymes
F. Collagenase -Breaks down collagen (found in many
connective tissues)
Clostridium perfringens - Gas Gangrene
Uses - to spread through muscle tissue
Used in cosmetics to fight cellulitis, contacture

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 Enzymes
G. Necrotizing Factor - Causes death (necrosis) to
tissue cells “ Flesh Eating Bacteria”

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 Bacterial toxins
Bacterial Toxins - Poisonous substances produced
by microorganisms
Toxins - primary factor of pathogenicity
220 known bacterial toxins
40% cause disease by damaging the Eukaryotic
cell membrane
Toxemia
Toxins in the bloodstream
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 Toxins
Toxigenesis: ability to produce toxins.
Bacteria may produce two types of toxins:
i. exotoxins and
ii. endotoxins.

Exotoxins are released from bacterial cells and may act at
tissue sites remote from the site of bacterial growth.

Endotoxins are cell-associated substance. (classic sense,
endotoxin refers to the lipopolysaccharide component of
the outer membrane of Gram-negative bacteria).
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 Toxins
Endotoxins may be released from growing bacterial cells
and cells that are lysed as a result of effective host defense
(e.g. lysozyme) or the activities of certain antibiotics (e.g.
penicillins and cephalosporins).

Hence, bacterial toxins, both soluble and cell-associated,
may be transported by blood and lymph and cause
cytotoxic effects at tissue sites

Some bacterial toxins may also act at the site of
colonization and play a role in invasion.
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 Toxins
Cytotoxins – kills cells Response to toxins
Shigella If exposed to exotoxins:
Vibrio antibodies against the toxin
(antitoxins )
Neurotoxins –interfere with
normal nerve impulses Exotoxins inactivated ( heat,
Cl. tetani formalin or phenol) no longer
cause disease, but stimulate
Cl.botulinum the production of antitoxin
Enterotoxins – affect cells lining Altered exotoxins - Toxoids
to the gastrointestinal tract
Toxoids - injected to stimulate
E.coli the production of antitoxins
Salmonella and provide immunity

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 Portals of entry of infection
Ingestion (fecal-oral)
Inhalation (respiratory)
Trauma (e.g burn)
Arthropod bite (zoonoses:
mosquito, flea, tick,
Tsetse fly)
Sexual transmission
Lathrogenic (needle stick,
blood transfusion)
Maternal-neonatal

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 Modes of infectious disease transmission
Bacteria, fungi, virus…
Ingestion: Salmonella, Shigella, Vibrio, Clostridium
etc..
Inhalation: Mycobacterium, Mycoplasma, Chlamydia
etc..
Trauma: Clostridium tetani
Arthropod bite: Rickettsia, Yersinia pestis, etc.
Sexual transmission: Neisseria gonorrhoeae, HIV,
chlamydia, etc.
Needle stick: Staphylococcus, HIV, HBV
Maternal-neonatal: HIV, HBV, Neisseria

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Modes of infectious disease
transmission

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 Modes of infectious disease
transmission
Contact transmission
Direct contact (person-to-person): syphilis,
gonorrhearel herpes
Indirect contact (formites): enterovirus
infection, measles
Droplet (less than 1 meter): whooping cough,
strep throat
Vehicle transmission
Airborne: influenza, tuberculoses, chickenpox
Water-borne (fecal-oral infection): cholera,
diarrhea
Food-borne: hepatitis, food poisoning, typhoid
fever
Vector transmission
Biological vectors: malaria, plaque, yellow fever
Mechanical vectors: E. coli diarrhea,
salmonellosi
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 Extracellular versus Intracellular
Parasitism
Extracellular parasites - destroyed
when phagocytosed.
damaging tissues as they
remain outside cells.
inducing the production of
opsonizing antibodies, they
usually produce acute diseases
of relatively short duration.

Intracellular parasites
can multiply within
phagocytes.
frequently cause chronic
diseases.

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Reading

Your manual

Chapters:
9. Pathogenesis of
bacterial infection
10. Normal human
microbiota

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11. Normal Microbial Flora of the Human Body.................................... 197
Role of the Resident Flora 197
Normal Flora of the Skin 198
Normal Flora of the Mouth & Upper Respiratory
Tract 198
Normal Flora of the Intestinal Tract 199
Normal Flora of the Urethra 200
Normal Flora of the Vagina 200
Normal Flora of the Conjuctiva 201
Review questions

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