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SECTION III BACTERIOLOGY

C

Pathogenesis of Bacterial
Infection
The pathogenesis of bacterial infection includes initiation of
the infectious process and the mechanisms that lead to the
development of signs and symptoms of disease. The biochemical, structural, and genetic factors that play important roles in
bacterial pathogenesis are introduced in this chapter and may
be revisited in the organism-specific sections. Characteristics of
bacteria that are pathogens include transmissibility, adherence
to host cells, persistence, invasion of host cells and tissues, toxigenicity, and the ability to evade or survive the host’s immune
system. Resistance to antimicrobials and disinfectants can also

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contribute to virulence, or an organism’s capacity to cause
disease. Many infections caused by bacteria that are commonly considered to be pathogens are inapparent or asymptomatic. Disease occurs if the bacteria or immunologic
reactions to their presence cause sufficient harm to the person.
Terms frequently used in describing aspects of pathogenesis are defined in the Glossary (see below). Refer to the
Glossary in Chapter 8 for definitions of terms used in immunology and in describing aspects of the host’s response to
infection.

G LOSSARY
Adherence (adhesion, attachment): The process by which
bacteria stick to the surfaces of host cells. After bacteria
have entered the body, adherence is a major initial step in
the infection process. The terms adherence, adhesion, and
attachment are often used interchangeably.

Invasion: The process whereby bacteria, animal parasites,
fungi, and viruses enter host cells or tissues and spread in
the body.

Carrier: A person or animal with asymptomatic infection that
can be transmitted to another susceptible person or animal.

Nonpathogen: A microorganism that does not cause disease;
may be part of the normal microbiota.

Infection: Multiplication of an infectious agent within the
body. Multiplication of the bacteria that are part of the
normal flora of the gastrointestinal tract, skin, and so on
is generally not considered an infection; on the other
hand, multiplication of pathogenic bacteria (eg, Salmonella
species)—even if the person is asymptomatic—is deemed
an infection.

Opportunistic pathogen: An agent capable of causing
disease only when the host’s resistance is impaired (ie,
when the patient is “immunocompromised”).

Microbiota: Microbial flora harbored by normal, healthy
individuals.

Pathogen: A microorganism capable of causing disease.
Pathogenicity: The ability of an infectious agent to cause
disease. (See also virulence.)

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Superantigens: Protein toxins that activate the immune
system by binding to major histocompatibility complex
(MHC) molecules and T-cell receptors (TCR) and stimulate
large numbers of T cells to produce massive quantities of
cytokines.

Virulence: The quantitative ability of an agent to cause
disease. Virulent agents cause disease when introduced
into the host in small numbers. Virulence involves
adherence, persistence, invasion, and toxigenicity (see
above).

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

IDENTIFYING BACTERIA THAT
CAUSE DISEASE
Humans and animals have abundant normal microbiota that
usually do not produce disease (see Chapter 10) but achieve
a balance that ensures the survival, growth, and propagation of both the bacteria and the host. Some bacteria that are
important causes of disease are cultured commonly with the
normal flora (eg, Streptococcus pneumoniae, Staphylococcus
aureus). Sometimes bacteria that are clearly pathogens (eg,
Salmonella serotype Typhi) are present, but infection remains
latent or subclinical, and the host is a “carrier” of the bacteria.
It can be difficult to show that a specific bacterial species
is the cause of a particular disease. In 1884, Robert Koch proposed a series of postulates that have been applied broadly to
link many specific bacterial species with particular diseases.
Koch’s postulates are summarized in Table 9-1.

TABLE 9-1

Koch’s postulates have remained a mainstay of microbiology; however, since the late 19th century, many microorganisms that do not meet the criteria of the postulates
have been shown to cause disease. For example, Treponema
pallidum (syphilis) and Mycobacterium leprae (leprosy) cannot be grown in vitro; however, there are animal models of
infection with these agents. In another example, Neisseria
gonorrhoeae (gonorrhea), there is no animal model of infection even though the bacteria can readily be cultured in vitro;
experimental infection in humans has been produced that
substitutes for an animal model.
In other instances, Koch’s postulates have been at least
partially satisfied by showing bacterial pathogenicity in an in
vitro model of infection rather than in an animal model. For
example, some forms of Escherichia coli–induced diarrhea
(see Chapter 15) have been defined by the interaction of the
E coli with host cells in tissue culture.

Guidelines for Establishing the Causes of Infectious Diseases

Koch’s Postulates

Molecular Koch’s Postulates

1. The microorganism should be
found in all cases of the disease in
question, and its distribution in the
body should be in accordance with
the lesions observed.

1. The phenotype or property under
investigation should be significantly
associated with pathogenic strains of
a species and not with nonpathogenic
strains.

2. The microorganism should be
grown in pure culture in vitro (or
outside the body of the host) for
several generations.

2. Specific inactivation of the gene or
genes associated with the suspected
virulence trait should lead to a
measurable decrease in pathogenicity
or virulence.

3. When such a pure culture is
inoculated into susceptible animal
species, the typical disease must
result.
4. The microorganism must again be
isolated from the lesions of such
experimentally produced disease.

3. Reversion or replacement of the
mutated gene with the wild-type
gene should lead to restoration of
pathogenicity or virulence.

Molecular Guidelines for Establishing
Microbial Disease Causation
1. The nucleic acid sequence of a putative pathogen
should be present in most cases of an infectious
disease and preferentially in anatomic sites where
pathology is evident.
2. The nucleic acid sequence of a putative pathogen
should be absent from most healthy control
participants. If the sequence is detected in healthy
control participants, it should be present with a lower
prevalence as compared with patients with disease
and in lower copy numbers.
3. The copy number of a pathogen-associated
nucleic acid sequence should decrease or become
undetectable with resolution of the disease (eg, with
effective treatment) and should increase with relapse
or recurrence of disease.
4. The presence of a pathogen-associated nucleic acid
sequence in healthy subjects should help predict the
subsequent development of disease.
5. The nature of the pathogen inferred from analysis
of its nucleic acid sequence should be consistent
with the known biologic characteristics of closely
related organisms and the nature of the disease.
The significance of a detected microbial sequence
is increased when microbial genotype predicts
microbial morphology, pathology, clinical features of
disease, and host response

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CHAPTER 9
The host’s immune responses also should be considered
when an organism is being investigated as the possible cause
of a disease. Thus, development of a rise in specific antibody
during recovery from disease is an important adjunct to
Koch’s postulates.
Modern-day microbial genetics has opened new frontiers
to study pathogenic bacteria and differentiate them from nonpathogens. Molecular cloning has allowed investigators to isolate and modify specific virulence genes and study them with
models of infection. The ability to study genes associated with
virulence has led to a proposed form of molecular Koch’s
postulates. These postulates are summarized in Table 9-1.
Some pathogens are difficult or impossible to grow in
culture, and for that reason, it is not possible with Koch’s
postulates or the molecular Koch’s postulates to establish the
cause of their associated diseases. The polymerase chain reaction is used to amplify microorganism-specific nucleic acid
sequences from host tissues or fluids. The sequences are used
to identify the infecting organisms. The molecular guidelines for establishing microbial disease causation are listed in
Table 9-1. This approach has been used to establish the causes
of several diseases, including Whipple disease (Tropheryma
whipplei), bacillary angiomatosis (Bartonella henselae),
human monocytic ehrlichiosis (Ehrlichia chaffeensis), hantavirus pulmonary syndrome (Sin Nombre virus), and Kaposi
sarcoma (human herpesvirus 8).
Analysis of infection and disease through the application
of principles such as Koch’s postulates leads to classification
of bacteria as pathogens, opportunistic pathogens, or nonpathogens. Some bacterial species are always considered to be
pathogens, and their presence is abnormal; examples include
Mycobacterium tuberculosis (tuberculosis) and Yersinia
pestis (plague). Such bacteria readily meet the criteria of
Koch’s postulates. Other species are commonly part of the
normal microbiota of humans (and animals) but also can
frequently cause disease. For example, E coli is part of the
gastrointestinal microbiota of normal humans but is also a
common cause of urinary tract infections, traveler’s diarrhea,
and other diseases. Strains of E coli that cause disease are differentiated from those that do not by determining (1) whether
they are virulent in animals or in vitro models of infection
and (2) whether they have a genetic makeup that is significantly associated with production of disease. Other bacteria
(eg, Pseudomonas species, Stenotrophomonas maltophilia,
and many yeasts and molds) only cause disease in immunosuppressed and debilitated persons and are opportunistic
pathogens.

TRANSMISSION OF INFECTION
Bacteria (and other microorganisms) can adapt to a variety
of environments that include external sources such as soil,
water and organic matter or internal milieu as found within
insect vectors, animals and humans, where they normally
reside and subsist. In doing so, the bacteria ensure their

Pathogenesis of Bacterial Infection

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survival and enhance the possibility of transmission. By producing asymptomatic infection or mild disease rather than
death of the host, microorganisms that normally live in people enhance the possibility of transmission from one person
to another.
Some bacteria that commonly cause disease in humans
exist primarily in animals and incidentally infect humans.
For example, Salmonella and Campylobacter species typically infect animals and are transmitted in food products to
humans. Other bacteria produce infection of humans that is
inadvertent, a mistake in the normal life cycle of the organism;
the organisms have not adapted to humans, and the disease
they produce may be severe. For example, Y pestis (plague) has
a well-established life cycle in rodents and rodent fleas, and
transmission by the fleas to humans is inadvertent; Bacillus
anthracis (anthrax) lives in the environment, occasionally
infects animals, and is transmitted to humans by products
such as raw hair from infected animals. The Clostridium species are ubiquitous in the environment and are transmitted to
humans by ingestion (eg, C perfringens gastroenteritis and C
botulinum [botulism]) or when wounds are contaminated by
soil (eg, C perfringens [gas gangrene] and C tetani [tetanus]).
Both Bacillus anthracis and the Clostridium species elaborate spores to protect the organisms’ nucleic acid from harsh
environmental factors such as ultraviolet light, desiccation,
chemical detergents, and pH extremes. These spores ensure
survival in external environments including foods ingested
by humans. After being ingested or inoculated, the spores
germinate into the vegetative, metabolically active form of
the pathogen.
The clinical manifestations of diseases (eg, diarrhea,
cough, genital discharge) produced by microorganisms often
promote transmission of the agents. Examples of clinical syndromes and how they enhance transmission of the causative
bacteria are as follows: Vibrio cholerae can cause voluminous diarrhea, which may contaminate salt and fresh water;
drinking water or seafood such as oysters and crabs may be
contaminated; ingestion of contaminated water or seafood
can produce infection and disease. Similarly, contamination
of food products with sewage containing E coli that cause
diarrhea results in transmission of the bacteria. M tuberculosis (tuberculosis) naturally infects only humans; it produces
respiratory disease with cough and production of aerosols,
resulting in transmission of the bacteria from one person to
another.
Many bacteria are transmitted from one person to
another on hands. A person with S aureus carriage in the
anterior nares may rub his nose, pick up the staphylococci on
the hands, and spread the bacteria to other parts of the body
or to another person, where infection results. Many opportunistic pathogens that cause nosocomial infections are transmitted from one patient to another on the hands of hospital
personnel. Handwashing is thus an important component of
infection control.
The most frequent portals of entry of pathogenic
bacteria into the body are the sites where mucous membranes

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meet with the skin, which are the respiratory (upper and
lower airways), gastrointestinal (primarily mouth), genital,
and urinary tracts. Abnormal areas of mucous membranes
and skin (eg, cuts, burns, and other injuries) are also frequent
sites of entry. Normal skin and mucous membranes provide the primary defense against infection. To cause disease,
pathogens must overcome these barriers.

THE INFECTIOUS PROCESS
In the body, most bacteria that cause disease do so first by
attaching or adhering to host cells, usually epithelial cells.
After the bacteria have established a primary site of infection, they multiply and spread directly through tissues or
via the lymphatic system to the bloodstream. This infection (bacteremia) can be transient or persistent. Bacteremia
allows bacteria to spread widely in the body and permits them to reach tissues particularly suitable for their
multiplication.
Pneumococcal pneumonia is an example of the infectious
process. S pneumoniae can be cultured from the nasopharynx
of 5–40% of healthy people. Occasionally, pneumococci
from the nasopharynx are aspirated into the lungs; aspiration occurs most commonly in debilitated people and in settings such as coma when normal gag and cough reflexes are
diminished. Infection develops in the terminal air spaces of
the lungs in persons who do not have protective antibodies
against that particular pneumococcal capsular polysaccharide type. Multiplication of the pneumococci and resultant
inflammation lead to pneumonia. The pneumococci enter
the lymphatics of the lung and move to the bloodstream.
Between 10% and 20% of persons with pneumococcal pneumonia have bacteremia at the time the diagnosis of pneumonia is made. When bacteremia occurs, the pneumococci can
spread to secondary sites of infection (eg, cerebrospinal fluid,
heart valves, and joint spaces). The major complications of
pneumococcal pneumonia are meningitis, septic arthritis,
and rarely endocarditis.
The infectious process in cholera involves ingestion of
V cholerae, chemotactic attraction of the bacteria to the gut
epithelium, motility of the bacteria by a single polar flagellum, and penetration of the mucous layer on the intestinal
surface. The V cholerae adherence to the epithelial cell surface
is mediated by pili and possibly other adhesins. Production of
cholera toxin results in flow of chloride and water into the
lumen of the gut, causing diarrhea and electrolyte imbalance.

The Clonal Nature of Bacterial Pathogens
One important result of the conservation of chromosomal
genes in bacteria is that the organisms are clonal. For most
pathogens, there are only one or a few clonal types that are
spread in the world during a period of time. For example,
epidemic serogroup A meningococcal meningitis occurs in
Asia, the Middle East, and Africa and occasionally spreads
into Northern Europe and the Americas. On several occasions, over a period of decades, single clonal types of serogroup A Neisseria meningitidis have been observed to appear
in one geographic area and subsequently spread to others
with resultant epidemic disease. There are many types of
Haemophilus influenzae, but only clonal H influenzae type B
is commonly associated with disease. There are two clonal
types of Bordetella pertussis, both associated with disease.
Similarly, Salmonella serotype Typhi (typhoid fever) from
patients is of two clonal types. There are, however, mechanisms that bacteria use, or have used a long time in the past,
to transmit virulence genes from one to another.

Mobile Genetic Elements
Primary mechanisms for exchange of genetic information
between bacteria include natural transformation and transmissible mobile genetic elements such as plasmids, transposons, and bacteriophages (often referred to as “phages”).
Transformation occurs when DNA from one organism is
released into the environment and is taken up by a different
organism that is capable of recognizing and binding DNA.
In other cases, the genes that encode many bacterial virulence factors are carried on plasmids, transposons, or phages.
Plasmids are extrachromosomal pieces of DNA and are capable of replicating. Transposons are highly mobile segments
of DNA that can move from one part of the DNA to another.
This can result in recombination between extrachromosomal
DNA and the chromosome (illegitimate or nonhomologous
recombination; Chapter 7). If this recombination occurs, the
genes coding for virulence factors may become chromosomal.
Finally, bacterial viruses or phages are another mechanism
by which DNA can be moved from one organism to another.
Transfer of these mobile genetic elements between members
of one species or, less commonly, between species can result
in transfer of virulence factors, including antimicrobial resistance genes. A few examples of plasmid- and phage-encoded
virulence factors are given in Table 9-2.

Pathogenicity Islands

GENOMICS AND BACTERIAL
PATHOGENICITY
Bacteria are haploid (see Chapter 7) and limit genetic interactions that might change their chromosomes and potentially
disrupt their adaptation and survival in specific environmental niches.

Large groups of genes that are associated with pathogenicity and are located on the bacterial chromosome are termed
pathogenicity islands (PAIs). They are large organized groups
of genes, usually 10–200 kb in size. The major properties of
PAIs are as follows: they have one or more virulence genes;
they are present in the genome of pathogenic members of

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TABLE 9-2

Examples of Virulence Factors Encoded
by Genes on Mobile Genetic Elements
Genus and Species
Plasmid encoded
Escherichia coli
Escherichia coli
Escherichia coli
and Shigella
species
Bacillus anthracis

Phage encoded
Clostridium
botulinum
Corynebacterium
diphtheriae
Vibrio cholerae

Virulence Factor and Disease
Heat-labile and heat-stable enterotoxins
that cause diarrhea
Hemolysin (cytotoxin) of invasive disease
and urinary tract infections
Adherence factors and gene products
involved in mucosal invasion
Capsule essential for virulence (on one
plasmid)
Edema factor, lethal factor, and protective
antigen are all essential for virulence
(on other plasmids)
Botulinum toxin that causes paralysis
Diphtheria toxin that inhibits human
protein synthesis
Cholera toxin that can cause a severe
watery diarrhea

a species but absent in the nonpathogenic members; they
are large; they typically have a different guanine plus cytosine (G + C) content than the rest of the bacterial genome;
they are commonly associated with tRNA genes; they are
often found with parts of the genome associated with mobile
genetic elements; they often have genetic instability; and
they often represent mosaic structures with components
acquired at different times. Collectively, the properties of

TABLE 9-3

Pathogenesis of Bacterial Infection

PAIs suggest that they originate from gene transfer from
foreign species. A few examples of PAI virulence factors are
provided in Table 9-3.

REGULATION OF BACTERIAL
VIRULENCE FACTORS
Pathogenic bacteria (and other pathogens) have adapted both
to saprophytic or free-living states, possibly environments
outside of the body, and to the human host. In the adaptive process, pathogens husband their metabolic needs and
products. They have evolved complex signal transduction systems to regulate the genes important for virulence.
Environmental signals often control the expression of the
virulence genes. Common signals include temperature, iron
availability, osmolality, growth phase, pH, and specific ions
(eg, Ca2+) or nutrient factors. A few examples are presented in
the following paragraphs.
The gene for diphtheria toxin from Corynebacterium
diphtheriae is carried on temperate bacteriophages. Toxin is
produced only by strains lysogenized by the phages. Toxin
production is greatly enhanced when C diphtheriae is grown
in a medium with low iron.
Expression of virulence genes of B pertussis is enhanced
when the bacteria are grown at 37°C and suppressed when
they are grown at lower temperatures or in the presence of
high concentrations of magnesium sulfate or nicotinic acid.
The virulence factors of V cholerae are regulated on multiple levels and by many environmental factors. Expression
of the cholera toxin is higher at a pH of 6.0 than at a pH of
8.5 and higher also at 30°C than at 37°C.

A Few Examples of the Very Large Number of Pathogenicity Islands of Human Pathogens

Genus and Species

PAI Name

Escherichia coli

PAI I536, II536

Alpha hemolysin, fimbriae, adhesions, in urinary tract infections

Escherichia coli

PAI IJ96

Alpha hemolysin, P-pilus in urinary tract infections

Escherichia coli (EHEC)

O157

Macrophage toxin of enterohemorrhagic Escherichia coli

Salmonella serotype Typhimurium

SPI-1

Invasion and damage of host cells; diarrhea

Yersinia pestis

HPI/pgm

Genes that enhance iron uptake

Vibrio cholerae El Tor O1

VPI-1

Neuraminidase, utilization of amino sugars

Staphylococcus aureus

SCC mec

Methicillin and other antibiotic resistance

Staphylococcus aureus

SaPI1

Toxic shock syndrome toxin-1, enterotoxin

Enterococcus faecalis

NP

Cytolysin, biofilm formation

m

153

Virulence Characteristics

PAI, pathogenicity island
SPI, Salmonella pathogenicity island
HPI, high pathogenicity island
VPI, Vibrio pathogenicity island
SCC, staphylococcal cassette chromosome mec
SaPI, Staphylococcus aureus pathogenicity island
NP, non-protease

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Osmolality and amino acid composition also are important. As many as 20 other genes of V cholerae are similarly
regulated.
Y pestis produces a series of virulence plasmid-encoded
proteins. One of these is an antiphagocytic fraction 1 capsular protein that results in antiphagocytic function. This
protein is expressed maximally at 35–37°C, the host temperature, and minimally at 20–28°C, the flea temperature at
which antiphagocytic activity is not needed. The regulation
of other virulence factors in Yersinia species also is influenced
by environmental factors.
Motility of bacteria enables them to spread and multiply
in their environmental niches or in patients. Yersinia enterocolitica and Listeria monocytogenes are common in the environment where motility is important to them. Presumably,
motility is not important in the pathogenesis of the diseases
caused by these bacteria. Y enterocolitica is motile when grown
at 25°C but not when grown at 37°C. Similarly, Listeria is motile
when grown at 25°C and not motile or minimally motile when
grown at 37°C.

BACTERIAL VIRULENCE FACTORS
Many factors determine bacterial virulence or the ability to
cause infection and disease.

Adherence Factors
When bacteria enter the body of the host, they must adhere
to cells of a tissue surface. If they did not adhere, they would
be swept away by mucus and other fluids that bathe the tissue
surface. Adherence, which is only one step in the infectious
process, is followed by development of microcolonies and
subsequent steps in the pathogenesis of infection.
The interactions between bacteria and tissue cell surfaces in the adhesion process are complex. Several factors
play important roles, including surface hydrophobicity and
net surface charge, binding molecules on bacteria (ligands),
and host cell receptor interactions. Bacteria and host cells
commonly have net negative surface charges and therefore
repulsive electrostatic forces. These forces are overcome by
hydrophobic and other more specific interactions between
bacteria and host cells. In general, the more hydrophobic the
bacterial cell surface, the greater the adherence to the host
cell. Different strains of bacteria within a species may vary
widely in their hydrophobic surface properties and ability to
adhere to host cells.
Bacteria also have specific surface molecules that interact with host cells. Many bacteria have pili, thick rodlike
appendages or fimbriae, shorter “hairlike” structures that
extend from the bacterial cell surface and help mediate
adherence of the bacteria to host cell surfaces. For example,
some E coli strains have type 1 pili, which adhere to epithelial
cell receptors; adherence can be blocked in vitro by addition
of d-mannose to the medium. E coli organisms that cause

urinary tract infections commonly do not have d-mannose–
mediated adherence but have P-pili, which attach to a portion of the P blood group antigen; the minimal recognition
structure is the disaccharide α-d-galactopyranosyl-(1–4)β-d-galactopyranoside (GAL–GAL binding adhesion). The
E coli that cause diarrheal diseases (see Chapter 15) have pilus
(fimbriae)-mediated adherence to intestinal epithelial cells.
The type of pili and specific molecular mechanisms of adherence appear to be different depending on the form of the
E coli that induce the diarrhea.
Other specific ligand-receptor mechanisms have evolved
to promote bacterial adherence to host cells, illustrating the
diverse mechanisms used by bacteria. Group A streptococci
(Streptococcus pyogenes) (see Chapter 14) also have hairlike
appendages, termed fimbriae, that extend from the cell surface. Lipoteichoic acid, protein F, and M protein are found
on the fimbriae. The lipoteichoic acid and protein F cause
adherence of the streptococci to buccal epithelial cells; this
adherence is mediated by fibronectin, which acts as the host
cell receptor molecule. M protein acts as an antiphagocytic
molecule and is a major virulence factor.
Antibodies that act against the specific bacterial ligands
that promote adherence (eg, pili and lipoteichoic acid) can
block adherence to host cells and protect the host from
infection.
After adherence occurs, conformational changes in the
host cell ensue that can lead to cytoskeletal changes allowing organism uptake by the cell. Sometimes changes in the
adhesin molecule after attachment may trigger activation of
virulence genes that promote invasion or that result in other
pathogenic changes as described below.

Invasion of Host Cells and Tissues
For many disease-causing bacteria, invasion of the host’s epithelium is central to the infectious process. Some bacteria
(eg, Salmonella species) invade tissues through the junctions
between epithelial cells. Other bacteria (eg, Yersinia species,
N gonorrhoeae, Chlamydia trachomatis) invade specific types
of the host’s epithelial cells and may subsequently enter
the tissue. When inside the host cell, bacteria may remain
enclosed in a vacuole composed of the host cell membrane,
or the vacuole membrane may be dissolved and bacteria may
be dispersed in the cytoplasm. Some bacteria (eg, Shigella
species) multiply within host cells, but other bacteria do not.
Invasion is the term commonly used to describe the
entry of bacteria into host cells, implying an active role
for the organisms and a passive role for the host cells. In
many infections, the bacteria produce virulence factors that
influence the host cells, causing them to engulf (ingest) the
bacteria. The host cells play a very active role in the process.
Toxin production and other virulence properties are
generally independent of the ability of bacteria to invade cells
and tissues. For example, C diphtheriae is able to invade the
epithelium of the nasopharynx and cause symptomatic sore
throat even when the C diphtheriae strains are nontoxigenic.

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In vitro studies with cells in tissue culture have helped
characterize the mechanisms of invasion for some pathogens;
however, the in vitro models have not necessarily provided
a complete picture of the invasion process. Full understanding of the invasion process, as it occurs in naturally acquired
infection, has required study of genetically engineered
mutants and their ability to infect susceptible animals and
humans. Thus, understanding of eukaryotic cell invasion by
bacteria requires satisfying much of Koch’s postulates and
the molecular Koch’s postulates. The following paragraphs
contain examples of bacterial invasion of host cells as part of
the infectious process.
Shigella species adhere to host cells in vitro. Commonly,
HeLa cells are used; these undifferentiated unpolarized cells
were derived from a cervical carcinoma. The adherence causes
actin polymerization in the nearby portion of the HeLa cell,
which induces the formation of pseudopods by the HeLa cells
and engulfment of the bacteria. Adherence and invasion are
mediated at least in part by products of genes located on a large
plasmid common to many shigellae. There are multiple proteins, including the invasion plasmid antigens (IpA-D), that
contribute to the process. Inside the HeLa cells, the shigellae either are released or escape from the phagocytic vesicle,
where they multiply in the cytoplasm. Actin polymerization
propels the shigellae within a HeLa cell and from one cell
into another. In vivo the shigellae adhere to integrins on the
surface of M cells in Peyer’s patches and not to the polarized
absorptive cells of the mucosa. M cells normally sample antigens and present them to macrophages in the submucosa. The
shigellae are phagocytosed by the M cells and pass through
the M cells into the underlying collection of macrophages.
Shigellae inside the M cells and macrophages can cause
these cells to die by activating the normal cell death process
(apoptosis). The shigellae spread to adjacent mucosal cells in a
manner similar to the in vitro model by actin polymerization
that propels the bacteria.
From studies using cells in vitro, it appears that the
adherence-invasion process with Y enterocolitica is similar to
that of Shigella. Yersiniae adhere to the host cell membrane
and cause it to extrude protoplasmic projections. The bacteria are then engulfed by the host cell with vacuole formation.
Invasion is enhanced when the bacteria are grown at 22°C
rather than at 37°C. When yersiniae have entered the cell, the
vacuolar membrane dissolves and the bacteria are released
into the cytoplasm. In vivo, the yersiniae are thought to
adhere to and invade the M cells of Peyer’s patches rather than
the polarized absorptive mucosal cells, much like shigellae.
L monocytogenes from the environment is ingested
in food. Presumably, the bacteria adhere to and invade the
intestinal mucosa, reach the bloodstream, and disseminate.
The pathogenesis of this process has been studied in vitro.
L monocytogenes adheres to and readily invades macrophages and cultured undifferentiated intestinal cells. The
listeriae induce engulfment by the host cells. Proteins, called
internalins, have a primary role in this process. The engulfment process, movement within a cell and movement between

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cells, requires actin polymerization to propel the bacteria, as
with shigellae.
Legionella pneumophila infects pulmonary macrophages
and causes pneumonia. Adherence of the legionellae to the
macrophage induces formation of a long, thin pseudopod
that then coils around the bacteria, forming a vesicle (coiling
phagocytosis). The vesicle remains intact, phagolysosome
fusion is inhibited, and the bacteria multiply within the
vesicle.
N gonorrhoeae uses pili as primary adhesins and opacity associated proteins (Opa) as secondary adhesins to host
cells. Certain Opa proteins mediate adherence to polymorphonuclear cells. Some gonococci survive after phagocytosis
by these cells. Pili and Opa together enhance the invasion of
cells cultured in vitro. In uterine (fallopian) tube organ cultures, the gonococci adhere to the microvilli of nonciliated
cells and appear to induce engulfment by these cells. The
gonococci multiply intracellularly and migrate to the subepithelial space by an unknown mechanism.

Toxins
Toxins produced by bacteria are generally classified into two
groups: exotoxins and endotoxins. Exotoxins are proteins
that are most often excreted from the cell. However some
exotoxins accumulate inside the cell and are either injected
directly into the host or are released by cell lysis. Endotoxins
are lipid molecules that are components of the bacterial cell
membrane. The primary features of the two groups are listed
in Table 9-4.

A. Exotoxins
Many gram-positive and gram-negative bacteria produce
exotoxins of considerable medical importance. Some of these
toxins have had major roles in world history. For example,
tetanus caused by the toxin of C tetani killed as many as
50,000 soldiers of the Axis powers in World War II; the Allied
forces, however, immunized military personnel against tetanus, and very few died of that disease. Vaccines have been
developed for some of the exotoxin-mediated diseases and
continue to be important in the prevention of disease. These
vaccines—called toxoids—are made from exotoxins, which
are modified so that they are no longer toxic. Many exotoxins consist of A and B subunits. The B subunit generally
mediates adherence of the toxin complex to a host cell and
aids entrance of the exotoxin into the host cell. The A subunit provides the toxic activity. Examples of some pathogenetic mechanisms associated with exotoxins are given below.
Other toxins of specific bacteria are discussed in the chapters
covering those bacteria.
C diphtheriae is a gram-positive rod that can grow on
the mucous membranes of the upper respiratory tract or
in minor skin wounds (see Chapter 12). Strains of C diphtheriae that carry a lysogenic, temperate corynebacteriophage (β-phage or ω-phage) with the structural gene for the

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TABLE 9-4

Bacteriology

Characteristics of Exotoxins and Endotoxins (Lipopolysaccharides)

Exotoxins

Endotoxins

Excreted by living cell; high concentrations in liquid medium

Integral part of the cell wall of gram-negative bacteria; released on bacterial
death and in part during growth; may not need to be released to have
biologic activity

Produced by both gram-positive and gram-negative bacteria

Found only in gram-negative bacteria

Polypeptides with a molecular weight of 10,000–900,000

Lipopolysaccharide complexes; lipid A portion probably responsible for
toxicity

Relatively unstable; toxicity often destroyed rapidly by heating
at temperatures above 60°C

Relatively stable; withstand heating at temperatures above 60°C for hours
without loss of toxicity

Highly antigenic; stimulate formation of high-titer antitoxin;
antitoxin neutralizes toxin

Weakly immunogenic; antibodies are antitoxic and protective; relationship
between antibody titers and protection from disease is less clear than
with exotoxins

Converted to antigenic, nontoxic toxoids by formalin, acid, heat,
and so on; toxoids are used to immunize (eg, tetanus toxoid)

Not converted to toxoids

Highly toxic; fatal to animals in microgram quantities or less

Moderately toxic; fatal for animals in tens to hundreds of micrograms

Usually bind to specific receptors on cells

Specific receptors not found on cells

Usually do not produce fever in the host

Usually produce fever in the host by release of interleukin-1 and other
mediators

Frequently controlled by extrachromosomal genes
(eg, plasmids)

Synthesis directed by chromosomal genes

toxin are toxigenic and produce diphtheria toxin and cause
diphtheria. Many factors regulate toxin production; when
the availability of inorganic iron is the factor limiting the
growth rate, then maximal toxin production occurs. The
toxin molecule is secreted as a single polypeptide molecule
(molecular weight [MW], 62,000). This native toxin is enzymatically degraded into two fragments, A and B, linked
together by a disulfide bond. Fragment B (MW, 40,700) binds
to specific host cell receptors and facilitates the entry of fragment A (MW, 21,150) into the cytoplasm. Fragment A inhibits
peptide chain elongation factor EF-2 by catalyzing a reaction
that attaches an adenosine diphosphate–ribosyl group to EF-2,
yielding an inactive adenosine diphosphate–ribose–EF-2
complex. Arrest of protein synthesis disrupts normal cellular
physiologic functions. Diphtheria toxin is very potent.
C tetani is an anaerobic gram-positive rod that causes
tetanus (see Chapter 11). C tetani from the environment contaminates wounds, and the spores germinate in the anaerobic
environment of the devitalized tissue. Infection often is
minor and not clinically apparent. The vegetative forms of
C tetani produce the toxin tetanospasmin (MW, 150,000)
that is cleaved by a bacterial protease into two peptides (MW,
50,000 and 100,000) linked by a disulfide bond. The toxin
initially binds to receptors on the presynaptic membranes
of motor neurons. It then migrates by the retrograde axonal
transport system to the cell bodies of these neurons to the
spinal cord and brainstem. The toxin diffuses to terminals
of inhibitory cells, including both glycinergic interneurons
and γ-aminobutyric acid (GABA)–secreting neurons from
the brainstem. The toxin degrades synaptobrevin, a protein

required for docking of neurotransmitter vesicles on the presynaptic membrane. Release of the inhibitory glycine and
GABA is blocked, and the motor neurons are not inhibited.
Spastic paralysis results. Extremely small amounts of toxin
can be lethal for humans. Tetanus is totally preventable
in immunologically normal people by immunization with
tetanus toxoid.
C botulinum causes botulism. This anaerobic, grampositive spore-forming organism is found in soil or water and
may grow in foods (eg, canned, vacuum packed) if the environment is appropriately anaerobic. An exceedingly potent
toxin (the most potent toxin known) is produced. It is heat
labile and is destroyed by sufficient heating. There are seven
distinct serologic types of toxin. Types A, B, E, and F are
most commonly associated with human disease. The toxin
is very similar to tetanus toxin, with a 150,000 MW protein
that is cleaved into 100,000-MW and 50,000-MW proteins
linked by a disulfide bond. Botulinum toxin is absorbed from
the gut and binds to receptors of presynaptic membranes of
motor neurons of the peripheral nervous system and cranial
nerves. Proteolysis, by the light chain of botulinum toxin, of
target proteins in the neurons inhibits the release of acetylcholine at the synapse, resulting in lack of muscle contraction
and flaccid paralysis.
Spores of C perfringens are introduced into wounds by
contamination with soil or feces. In the presence of necrotic
tissue (an anaerobic environment), spores germinate, and
vegetative cells can produce several different toxins. Many
of these are necrotizing and hemolytic and—together with
distention of tissue by gas formed from carbohydrates and

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interference with blood supply—favor the spread of gas
gangrene. The alpha toxin of C perfringens is a lecithinase
that damages cell membranes by splitting lecithin to phosphorylcholine and diglyceride. Theta toxin also has a necrotizing effect. Collagenases and DNAses are produced by
clostridiae as well.
Some S aureus strains growing on mucous membranes
(eg, the vagina in association with menstruation) or in
wounds, elaborate toxic shock syndrome toxin-1 (TSST-1),
which causes toxic shock syndrome (Chapter 13). The illness is characterized by shock, high fever, and a diffuse red
rash that later desquamates; multiple other organ systems
are involved as well. TSST-1 is a super antigen and stimulates
T-cells to produce large amounts of interleukin-2 (IL-2) and
tumor necrosis factor (TNF) (see Chapter 8). The major clinical manifestations of the disease appear to be secondary to
the effects of the cytokines. Many of the systemic effects of
TSST-1 are similar to those of toxicity caused by lipopolysaccharide (LPS; see discussion below).
Some strains of group A β-hemolytic streptococci produce pyrogenic exotoxin A that is similar to or the same
as streptococcal erythrogenic toxin, which results in scarlet
fever. Rapidly progressive soft tissue infection by streptococci
that produce the pyrogenic exotoxin A has many clinical
manifestations similar to those of staphylococcal toxic shock
syndrome. The pyrogenic exotoxin A also is a super antigen
that acts in a manner similar to TSST-1.

B. Exotoxins Associated with Diarrheal Diseases
and Food Poisoning
Exotoxins associated with diarrheal diseases are frequently
called enterotoxins. (See also Table 48-3.) Characteristics of
some important enterotoxins are discussed below.
V cholerae has produced epidemic diarrheal disease
(cholera) in many parts of the world (see Chapter 17) and
is another toxin-produced disease of historical and current
importance. After entering the host via contaminated food
or drink, V cholerae penetrates the intestinal mucosa and
attaches to microvilli of the brush border of gut epithelial cells.
V cholerae, usually of the serotype O1 (and O139), can produce an enterotoxin with a MW of 84,000. The toxin consists
of two subunits—A, which is split into two peptides, A1 and
A2, linked by a disulfide bond, and B. Subunit B has five identical peptides and rapidly binds the toxin to cell membrane
ganglioside molecules. Subunit A enters the cell membrane
and causes a large increase in adenylate cyclase activity and
in the concentration of cAMP. The net effect is rapid secretion
of electrolytes into the small bowel lumen, with impairment
of sodium and chloride absorption and loss of bicarbonate. Life-threatening massive diarrhea (eg, 20–30 L/day)
can occur, and acidosis develops. The deleterious effects of
cholera are due to fluid loss and acid–base imbalance; treatment, therefore, is by electrolyte and fluid replacement.
Some strains of S aureus produce enterotoxins while
growing in meat, dairy products, or other foods. In typical

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157

cases, the food has been recently prepared but not properly
refrigerated. There are at least seven distinct types of the
staphylococcal enterotoxin. After the preformed toxin is
ingested, it is absorbed in the gut, where it stimulates vagus
nerve receptors. The stimulus is transmitted to the vomiting center in the central nervous system. Vomiting, often
projectile, results within hours. Diarrhea is less frequent.
Staphylococcal food poisoning is the most common form of
food poisoning. S aureus enterotoxins are super antigens.
Enterotoxins are also produced by some strains of
Y enterocolitica (see Chapter 19), Vibrio parahaemolyticus
(see Chapter 17), Aeromonas species (see Chapter 17), and
other bacteria, but the role of these toxins in pathogenesis is
not as well defined. The enterotoxin produced by C perfringens is discussed in Chapter 11.

C. Lipopolysaccharides of Gram-Negative Bacteria
The LPS (endotoxin) of gram-negative bacteria are bacterial cell wall components that are often liberated when the
bacteria lyse. The substances are heat-stable, have MWs
between 3000 and 5000 (lipooligosaccharides, LOS) and
several million (lipopolysaccharides) and can be extracted
(eg, with phenol-water). They have three main regions (see
Figure 2-19).
The pathophysiologic effects of LPS are similar regardless of their bacterial origin except for those of Bacteroides
species, which have a different structure and are less toxic
(see Chapter 21). LPS in the bloodstream is initially bound
to circulating proteins, which then interact with receptors
on macrophages neutrophils and other cells of the reticuloendothelial system. Proinflammatory cytokines such as
IL-1, IL-6, IL-8, TNF-α, and other cytokines are released,
and the complement and coagulation cascades are activated.
The following can be observed clinically or experimentally:
fever, leukopenia, and hypoglycemia; hypotension and shock
resulting in impaired perfusion of essential organs (eg, brain,
heart, kidney); intravascular coagulation; and death from
massive organ dysfunction.
Injection of LPS produces fever after 60–90 minutes,
the time needed for the body to release IL-1. Injection of
IL-1 produces fever within 30 minutes. Repeated injection of
IL-1 produces the same fever response each time, but repeated
injection of LPS causes a steadily diminishing fever response
because of tolerance partly caused by reticuloendothelial
blockade and partly caused by IgM antibodies to LPS.
Injection of LPS produces early leukopenia, as does bacteremia with gram-negative organisms. Secondary leukocytosis occurs later. The early leukopenia coincides with the onset
of fever caused by liberation of IL-1. LPS enhances glycolysis
in many cell types and can lead to hypoglycemia.
Hypotension occurs early in gram-negative bacteremia
or after injection of LPS. There may be widespread arteriolar and venular constriction followed by peripheral vascular dilatation, increased vascular permeability, decrease in
venous return, lowered cardiac output, stagnation in the

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microcirculation, peripheral vasoconstriction, shock, and
impaired organ perfusion and its consequences. Disseminated
intravascular coagulation (DIC) also contributes to these vascular changes.
LPS is among the many different agents that can activate
the alternative pathway of the complement cascade, precipitating a variety of complement-mediated reactions (eg,
anaphylatoxins, chemotactic responses, membrane damage)
and a drop in serum levels of complement components (C3,
C5–C9).
Disseminated intravascular coagulation is a frequent
complication of gram-negative bacteremia and can also
occur in other infections. LPS activates factor XII (Hageman
factor)—the first step of the intrinsic clotting system—and
sets into motion the coagulation cascade, which culminates
in the conversion of fibrinogen to fibrin. At the same time,
plasminogen can be activated by LPS to plasmin (a proteolytic enzyme), which can attack fibrin with the formation
of fibrin split products. Reduction in platelet and fibrinogen
levels and detection of fibrin split products are evidence of
DIC. Heparin can sometimes prevent the lesions associated
with DIC.
LPS causes platelets to adhere to vascular endothelium
and occlusion of small blood vessels, causing ischemic or
hemorrhagic necrosis in various organs.
Endotoxin levels can be assayed by the limulus test: A
lysate of amebocytes from the horseshoe crab (limulus) gels
or coagulates in the presence of 0.0001 µg/mL of endotoxin.
This test is rarely used in clinical laboratories because it is difficult to perform accurately.

D. Peptidoglycan of Gram-Positive Bacteria
The peptidoglycan of gram-positive bacteria is made up of
cross-linked macromolecules that surround the bacterial
cells (see Chapter 2 and Figure 2-15). Vascular changes leading to shock may also occur in infections caused by grampositive bacteria that contain no LPS. Gram-positive bacteria
have considerably more cell wall–associated peptidoglycan
than do gram-negative bacteria. Peptidoglycan released during infection may yield many of the same biologic activities
as LPS, although peptidoglycan is invariably much less potent
than LPS.

but have been difficult to prove, especially those of individual enzymes. For example, antibodies against the tissue-degrading enzymes of streptococci do not modify the features
of streptococcal disease.
In addition to lecithinase, C perfringens produces the
proteolytic enzyme collagenase, which degrades collagen,
the major protein of fibrous connective tissue, and promotes
spread of infection in tissue.
S aureus produces coagulase, which works in conjunction with blood factors to coagulate plasma. Coagulase
contributes to the formation of fibrin walls around staphylococcal lesions, which helps them persist in tissues. Coagulase
also causes deposition of fibrin on the surfaces of individual
staphylococci, which may help protect them from phagocytosis or from destruction within phagocytic cells.
Hyaluronidases are enzymes that hydrolyze hyaluronic
acid, a constituent of the ground substance of connective tissue. They are produced by many bacteria (eg, staphylococci,
streptococci, and anaerobes) and aid in their spread through
tissues.
Many hemolytic streptococci produce streptokinase
(fibrinolysin), a substance that activates a proteolytic enzyme
of plasma. This enzyme is then able to dissolve coagulated
plasma and probably aids in the rapid spread of streptococci
through tissues. Streptokinase has been used in treatment of
acute myocardial infarction to dissolve fibrin clots.
Many bacteria produce substances that are cytolysins—
that is, they dissolve red blood cells (hemolysins) or kill tissue cells or leukocytes (leukocidins). Streptolysin O, for
example, is produced by group A streptococci and is lethal
for mice and hemolytic for red blood cells from many animals. Streptolysin O is oxygen labile and can therefore be
oxidized and inactivated, but it is reactivated by reducing
agents. It is antigenic. The same streptococci also produce
oxygen-stable, serum-inducible streptolysin S, which is not
antigenic. Clostridia produce various hemolysins, including
the lecithinase described earlier. Hemolysins are produced by
most strains of S aureus; staphylococci also produce leukocidins. Most gram-negative rods isolated from sites of disease
produce hemolysins. For example, whereas E coli strains that
cause urinary tract infections typically produce hemolysins,
strains that are part of the normal gastrointestinal flora may
or may not produce hemolysins.

Enzymes
Many species of bacteria produce enzymes that are not
intrinsically toxic but do play important roles in the infectious process. Some of these enzymes are discussed below.

A. Tissue-Degrading Enzymes
Many bacteria produce tissue-degrading enzymes. The
best-characterized are enzymes from C perfringens (see
Chapter 11), and, to a lesser extent, anaerobic bacteria
(see Chapter 21), S aureus (see Chapter 13), and group A
streptococci (see Chapter 14). The roles of tissue-degrading
enzymes in the pathogenesis of infections appear obvious

B. IgA1 Proteases
Immunoglobulin A is the secretory antibody on mucosal
surfaces. It has two primary forms, IgA1 and IgA2, that differ near the center, or hinge region of the heavy chains of the
molecules (see Chapter 8). IgA1 has a series of amino acids in
the hinge region that are not present in IgA2. Some bacteria
that cause disease produce enzymes, IgA1 proteases, that split
IgA1 at specific proline–threonine or proline–serine bonds
in the hinge region and inactivate its antibody activity. IgA1
protease is an important virulence factor of the pathogens N
gonorrhoeae, N meningitidis, H influenzae, and S pneumoniae.

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The enzymes are also produced by some strains of Prevotella
melaninogenica, some streptococci associated with dental
disease, and a few strains of other species that occasionally
cause disease. Nonpathogenic species of the same genera do
not have genes coding for the enzyme and do not produce it.
Production of IgA1 protease allows pathogens to inactivate
the primary antibody found on mucosal surfaces and thereby
eliminate protection of the host by the antibody.

Antiphagocytic Factors
Many bacterial pathogens are rapidly killed after they are
ingested by polymorphonuclear cells or macrophages. Some
pathogens evade phagocytosis or leukocyte microbicidal mechanisms by adsorbing normal host components to their surfaces.
For example, S aureus has surface protein A, which binds to
the Fc portion of IgG. Other pathogens have surface factors
that impede phagocytosis (eg, S pneumoniae, N meningitidis)
many other bacteria have polysaccharide capsules. S pyogenes
(group A streptococci) has M protein. N gonorrhoeae (gonococci) has pili. Most of these antiphagocytic surface structures
show much antigenic heterogeneity. For example, there are
more than 90 pneumococcal capsular polysaccharide types
and more than 150 M protein types of group A streptococci.
Antibodies against one type of the antiphagocytic factor (eg,
capsular polysaccharide, M protein) protect the host from disease caused by bacteria of that type but not from those with
other antigenic types of the same factor.
A few bacteria (eg, Capnocytophaga and Bordetella
species) produce soluble factors or toxins that inhibit chemotaxis by leukocytes and thus evade phagocytosis by a different
mechanism.

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159

K (capsule) types. The antigenic type of the bacteria may be
a marker for virulence, related to the clonal nature of pathogens, although it may not actually be the virulence factor (or
factors). V cholerae O antigen type 1 and O antigen type 139
typically produce cholera toxin, but very few of the many
other O types produce the toxin. Only some of the group
A streptococcal M protein types are associated with a high
incidence of poststreptococcal glomerulonephritis. N meningitidis capsular polysaccharide types A and C are associated
with epidemic meningitis. In the examples cited earlier and
in other typing systems that use surface antigens in serologic
classification, antigenic types for a given isolate of the species
remain constant during infection and on subculture of the
bacteria.
Some bacteria and other microorganisms have the ability to make frequent shifts in the antigenic form of their
surface structures in vitro and presumably in vivo. One wellknown example is Borrelia recurrentis, which causes relapsing fever. A second widely studied example is N gonorrhoeae
(see Chapter 20). The gonococcus has three surface-exposed
antigens that switch forms at very high rates of about
one in every 1000: lipooligosaccharide, 6–8 types; pili,
innumerable types; and Opa, 10–12 types for each strain.
The number of antigenic forms is so large that each strain of
N gonorrhoeae appears to be antigenically distinct from every
other strain. Switching of forms for each of the three antigens
appears to be under the control of different genetic mechanisms. It is presumed that frequent switching of antigenic
forms allows gonococci to evade the host’s immune system;
gonococci that are not attacked by the immune system survive and cause disease.

Bacterial Secretion Systems

Intracellular Pathogenicity
Some bacteria (eg, M tuberculosis, Listeria monocytogenes,
Brucella species, and Legionella species) live and grow in the
hostile environment within polymorphonuclear cells, macrophages, or monocytes. The bacteria accomplish this feat by
several mechanisms: they may avoid entry into phagolysosomes and live within the cytosol of the phagocyte; they may
prevent phagosome–lysosome fusion and live within the phagosome; or they may be resistant to lysosomal enzymes and
survive within the phagolysosome.
Many bacteria can live within nonphagocytic cells (see
previous section, Invasion of Host Cells and Tissues).

Antigenic Heterogeneity
The surface structures of bacteria (and of many other microorganisms) have considerable antigenic heterogeneity. Often
these antigens are used as part of a serologic classification
system for the bacteria. The classification of the 2000 or so
different salmonellae is based principally on the types of the
O (LPS side chain) and H (flagellar) antigens. Similarly, there
are more than 150 E coli O types and more than 100 E coli

Bacterial secretion systems are important in the pathogenesis
of infection and are essential for the interaction of bacteria
with the eukaryotic cells of the host. The gram-negative bacteria have cell walls with cytoplasmic membranes and outer
membranes; a thin layer of peptidoglycan is present. Grampositive bacteria have a cytoplasmic membrane and a very
thick layer of peptidoglycan (see Chapter 2). Some gramnegative bacteria and some gram-positive bacteria have
capsules as well. The complexity and rigidity of the cell wall
structures necessitate mechanisms for the translocation of
proteins across the membranes. These secretion systems are
involved in cellular functions such as the transport of proteins
that make pili or flagella and in the secretion of enzymes or
toxins into the extracellular environment. The differences in
cell wall structure between gram-negative and gram-positive
bacteria result in some differences in the secretion systems.
The basic mechanisms of the different bacterial secretion systems are discussed in Chapter 2. (Note: The specific bacterial
secretion systems were named in the order of their discovery
and not by their mechanisms of action.)
Both gram-negative and gram-positive bacteria have a
general secretion pathway (Sec) as the major mechanism for

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protein secretion. This pathway is involved in the insertion
of most of the bacterial membrane proteins and provides the
major pathway for proteins crossing the bacterial cytoplasmic
membrane. Gram-negative organisms have an additional six
mechanisms, secretion systems (SS) 1–6 (sometimes denoted
I–VI), for protein secretion. These can be further characterized as Sec dependent (types 2 and 5) and Sec independent
(types 1, 3, 4, 6). Type 2 SS use the general Sec to transport the
proteins to the periplasm and then create an outer membrane
channel made by a special pore-forming protein complex.
This type 2 SS is used to secrete portions of bacterial A B type
toxins, such as cholera toxin. Similarly, the type 5 SS, uses
the general Sec to export an autotransporter to the periplasm;
from there it transports itself across the outer membrane. An
example of this type of SS includes the IgA proteases secreted
by Haemophilus influenzae. The sec-independent pathways
include the type 1 secretion system or ABC secretion system
(ATP binding cassette) and the type 3 secretion system. The
type 1 and type 3 pathways do not interact with proteins that
have been transported across the cytoplasmic membrane by
the Sec system. Instead, these systems translocate proteins
across both the cytoplasmic and outer membranes. The type
3, which is activated upon contact with a eukaryotic host cell,
promotes transport of proteins directly from inside the bacterium to the inside of the host cell using a needlelike structure
called an injectosome; when in the host cell cytoplasm, the
transported proteins can manipulate host cell function. The
type 4 sec