Microbiology (Tortora, Funke, Case 13th Ed. 2019) PDF

Summary

This document is about microbial diseases of the respiratory system. It describes the anatomical defenses of the upper respiratory system against airborne pathogens and the possible infection process. It also details the structure and function of the respiratory system, including the upper and lower respiratory systems.

Full Transcript

24 Microbial Diseases
of the Respiratory System

W
ith every breath, we inhale several
microorganisms; therefore, the upper
respiratory system is a major portal
of entry for pathogens. In fact, respiratory system
infections are the most common type of infection—and
among the most damaging. Some pathogens that enter
via the respiratory route can infect other parts of the body,
causing such diseases as measles, mumps, and rubella.
The upper respiratory system has several anatomical
defenses against airborne pathogens. Coarse hairs in the
nose filter large dust particles from the air. The nose is lined
with a mucous membrane that contains numerous mucus-
secreting cells and cilia. The upper portion of the throat also
contains a ciliated mucous membrane. The mucus moistens
inhaled air and traps dust and microorganisms. The cilia help
remove these particles by moving them toward the mouth for
elimination.
At the junction of the nose and throat are masses of
lymphoid tissue, the tonsils, which contribute immunity to
certain infections. Because the nose and throat are connected
to the sinuses, nasolacrimal apparatus, and middle ear,
infections commonly spread from one region to another.
Microbes that escape these defenses may be able to cause
infection. Such an infection caused by the Chlamydophila
psittaci shown in the photograph is described in the
Clinical Case in this chapter.
▶ When infecting a host cell, chlamydial bacteria produce
infectious elementary bodies (small, brown) and noninfectious-
reticulate bodies (red).

In the Clinic
As a nurse educator in a large urban hospital, you are asked to provide flu classes
for patients and staff. Differentiate influenza from the common cold. What prevention
measures will you recommend to your students?
Hint: Read about the common cold on page 693 and influenza on page 709.
Answers to In the Clinic questions are found online @MasteringMicrobiology.

688
 CHAPTER 24   Microbial Diseases of the Respiratory System 689

Figure 24.1 Structures of the upper
­respiratory system.
Q Name the upper respiratory
system’s defenses against disease.

Sinus Sinus

Middle ear
Nasal cavity
Auditory
(eustachian)
tube
Oral cavity Opening of
Tongue auditory tube
Tonsils
Epiglottis Pharynx
(throat)
Larynx Spine
(voice box) (backbone)
Trachea (windpipe) Esophagus

Structure and Function of the called the ciliary escalator (see Figure 16.3, page 450). If micro-
organisms actually reach the lungs, phagocytic cells called
Respiratory System alveolar macrophages usually locate, ingest, and destroy most of
LEARNING OBJECTIVE them. IgA antibodies in such secretions as respiratory mucus,
saliva, and tears also help protect mucosal surfaces of the
24-1 Describe how microorganisms are prevented from entering
respiratory system from many pathogens. Thus, the body has
the respiratory system.
several mechanisms for removing the pathogens that cause air-
It’s convenient to think of the respiratory system as being com- borne infections.
posed of two divisions: the upper respiratory system and the
lower respiratory system. The upper respiratory system con- CHECK YOUR UNDERSTANDING
sists of the nose, the pharynx (throat), larynx (voice box), and ✓ 24-1 What is the function of hairs in the nasal passages?
the structures associated with them, including the middle ear
and the auditory (eustachian) tubes (Figure 24.1). Ducts from the
sinuses (air-filled spaces in certain skull bones) and the nasolacri-
mal ducts from the lacrimal (tear-forming) apparatus empty into
CLINICAL CASE It’s for the Birds

F
the nasal cavity (see Figure 16.2, page 450). The auditory tubes or the past 2 days, Caille Nguyen has had a fever and feels
from the middle ear empty into the upper portion of the throat. out of sorts. In fact, her entire family is sick. Her three
The lower respiratory system consists of the trachea children, Gabbie, Steven, and Tre, also have fevers. Caille’s
(windpipe), bronchial tubes, and alveoli (Figure 24.2). Alveoli husband, Art, and Gabbie and Steven have no appetite and
are air sacs that make up the lung tissue; within them, oxy- are beginning to lose weight. Everyone has a dry cough. At
gen and carbon dioxide are exchanged between the lungs and first Caille thinks the children are just sad because of the loss
blood. Our lungs contain more than 300 million alveoli, with of Bitsy, their beloved cockatiel. The family had purchased
the cockatiel from a local pet store 2 months earlier.
an area for gas exchange of 70 or more square meters in an
Unfortunately, Bitsy had an increasingly difficult time breathing
average adult. The double-layered membrane enclosing the
and could not stand erect; she had to be euthanized by a local
lungs is the pleura, or pleural membranes. A ciliated mucous veterinarian the week before.
membrane lines the lower respiratory system down to the
What could be causing the Nguyen family’s symptoms? Read
smaller bronchial tubes and helps prevent microorganisms
on to find out.
from reaching the alveoli.
Particles trapped in the larynx, trachea, and larger bron- 689 706 707 709 711 715
chial tubes are moved up toward the throat by a ciliary action
690 PART FOUR Microorganisms and Human Disease

Branch
from the
Pharynx pulmonary
(throat) Bronchiole artery
Blood
Larynx Branch from capillaries
(voice box) the pulmonary
Trachea vein
(windpipe)
Right lung Left lung

Bronchus

Bronchiole

Pleura Alveoli
Heart
Diaphragm
(breathing
muscle)

Figure 24.2 Structures of the lower respiratory system.
Q Name the lower respiratory system’s defenses against disease.

Normal Microbiota of the microorganisms of the normal microbiota suppress their
growth by competing with them for nutrients and producing
Respiratory System inhibitory substances.
The lung microbiome is described in the Exploring the
LEARNING OBJECTIVE
Microbiome box.
24-2 Characterize the normal microbiota of the upper and lower
respiratory systems. CHECK YOUR UNDERSTANDING
A number of potentially pathogenic microorganisms are part ✓ 24-2 Normally, the lower respiratory tract is nearly sterile.
of the normal microbiota in the respiratory system. However, What is the primary mechanism responsible?
they usually do not cause illness because the predominant

Microbial Diseases of the Upper Respiratory System
LEARNING OBJECTIVE opening by which the mucus leaves the sinus becomes blocked,
24-3 Differentiate pharyngitis, laryngitis, tonsillitis, sinusitis, and internal pressure can cause pain or a sinus headache. These dis-
epiglottitis. eases are almost always self-limiting, meaning that recovery will
usually occur even without medical intervention.
As most of us know from personal experience, the respiratory
Probably the most threatening infectious disease of the
system is the site of many common infections. We will soon
upper respiratory system is epiglottitis, inflammation of the
discuss pharyngitis, inflammation of the mucous membranes
epiglottis. The epiglottis is a flaplike structure of cartilage that
of the throat, or sore throat. When the larynx is the site of
prevents ingested material from entering the larynx (see F­ igure
infection, we suffer from laryngitis, which affects our ability
24.1). Epiglottitis is a rapidly developing disease that can
to speak. The microbes that cause pharyngitis also can cause
result in death within a few hours. It is caused by opportunis-
inflamed tonsils, or tonsillitis.
tic pathogens, usually Haemophilus influenzae type b. The Hib
The nasal sinuses are cavities in certain cranial bones that
­vaccine, although directed primarily at meningitis (page 622),
open into the nasal cavity. They have a mucous membrane lining
has significantly reduced the incidence of epiglottitis in the
that is continuous with that of the nasal cavity. Infection of a sinus
vaccinated population.
involving heavy nasal discharge of mucus is called sinusitis. If the
 CHAPTER 24   Microbial Diseases of the Respiratory System 691
EXPLORING THE MICROBIOME Discovering the Microbiome
of the Lungs

U
ntil as recently as 2009, many do not use oxygen, they all share the ability environment or whether the microbiota are
scientists and medical professionals to avoid oxygen’s toxic effects by producing evenly dispersed throughout the lungs or
believed that healthy lungs are sterile, antioxidant enzymes, including peroxidase concentrated in specific areas. Depending
based on findings from studies using and superoxide dismutase. on how discoveries proceed, we may one
traditional culture techniques. However, Patients with chronic pulmonary day have lung disease therapies that use
genetic studies related to the Human diseases such as asthma, cystic fibrosis, probiotics.
Microbiome Project show this isn’t the case. or chronic obstructive pulmonary disease
It would actually be remarkable if the alveoli (COPD) have a predominance of gram-
didn’t routinely come into contact with at negative bacteria compared to individuals
least some microbes, considering that the without chronic lung disease. One study
average adult inhales over 10,000 liters of also found that nitric-oxide-metabolizing
microbe-filled air every day. bacteria (Nitrosomonas spp.) were present
The most common bacterial genera in the lungs of asthma patients. This is
present in healthy lungs are Prevotella, notable in that airway inflammation in
Veillonella, Streptococcus, and asthma patients is often diagnosed by
Pseudomonas. These bacteria are also measuring exhaled nitric oxide. Higher-
common members of the oral microbiome. than-normal levels indicate that the
This suggests that, surprisingly, the primary airways may be inflamed. It could be that
source of the lung microbiota is likely the the Nitrosomonas bacteria in lungs are
mouth rather than inhaled air. Prevotella, responsible for this phenomenon that
Veillonella, and Streptococcus are all clinicians use as a diagnostic tool.
anaerobic bacteria. It may seem illogical for Lung microbiome research is new,
species that don’t use oxygen to live in the so many unanswered questions remain.
lower respiratory system, the site of gas For instance, researchers don’t yet know
exchange. However, although these bacteria whether core species change with age or

Staphylococcus sp. in the trachea.

gram-positive bacterial group consists solely of Streptococcus
CHECK YOUR UNDERSTANDING
pyogenes, the same bacterium responsible for many skin and
✓ 24-3 Which one of the following is most likely to be associated soft tissue infections, such as impetigo, erysipelas, and acute
with a headache: pharyngitis, laryngitis, sinusitis, or epiglottitis?
bacterial endocarditis.
Pharyngitis is characterized by local inflammation and a
Bacterial Diseases of the fever (Figure 24.3). Frequently, tonsillitis occurs, and the lymph
nodes in the neck become enlarged and tender. Another fre-
Upper Respiratory System quent complication is otitis media (see page 693).
The pathogenicity of GAS is enhanced by their resistance to
LEARNING OBJECTIVE
phagocytosis. They are also able to produce special enzymes,
24-4 List the causative agent, symptoms, prevention, called streptokinases, which lyse fibrin clots, and streptolysins,
preferred treatment, and laboratory identification tests
which are cytotoxic to tissue cells, red blood cells, and protec-
for streptococcal pharyngitis, scarlet fever, diphtheria,
tive leukocytes.
cutaneous diphtheria, and otitis media.
At one time, the diagnosis of pharyngitis was based on
Airborne pathogens make their first contact with the body’s ­c ulturing bacteria from a throat swab. Results took overnight
mucous membranes as they enter the upper respiratory system. or longer, but, beginning in the early 1980s, rapid antigen
Many respiratory or systemic diseases initiate infections here. detection tests that were capable of detecting GAS directly
on throat swabs became available. A physician can perform a
Streptococcal Pharyngitis (Strep Throat) rapid test in the office. These rapid tests have high specificity.
Streptococcal pharyngitis (strep throat) is an upper respi- However, negative samples should be cultured because of the
ratory infection caused by group A streptococci (GAS). This varying sensitivity of these tests. (Specificity and sensitivity are
691
692 PART FOUR Microorganisms and Human Disease

children in the United States. The disease begins with a sore
throat and fever, followed by general malaise and swelling of
the neck. The organism responsible is Corynebacterium diph-
theriae, a gram-positive, non–endospore-forming rod. Its mor-
phology is pleomorphic, frequently club-shaped, and it stains
unevenly (Figure 24.4).
Part of the normal immunization program for children in
the United States is the DTaP vaccine, which protects against
diphtheria, tetanus, and pertussis. In this name, the D repre-
sents diphtheria toxoid, an inactivated toxin that causes the
body to produce antibodies against the diphtheria toxin.
C. diphtheriae has adapted to a generally immunized pop-
ulation, and relatively nonvirulent strains are found in the
throats of many symptomless carriers. The bacterium is well
suited to droplet transmission and is very resistant to drying.
A tough grayish membrane that forms in the throat in
Figure 24.3 Streptococcal pharyngitis. Note the inflammation.
response to the infection is characteristic of diphtheria (from the
Q How is strep throat diagnosed? Greek word for leather). It contains fibrin, dead tissue, and bacte-
rial cells and can totally block the passage of air to the lungs.
Although the bacteria don’t invade tissues, those that have
discussed in Chapter 18, page 507.) Actually, the majority of
been lysogenized by a phage can produce a powerful exotoxin,
patients seen for sore throats do not have a streptococcal infec-
which then circulates in the bloodstream and interferes with
tion. Some cases are caused by other bacteria, but most are
protein synthesis. Historically, diphtheria was the first disease
caused by viruses—for which antibiotic therapy is ineffective.
for which a toxic cause was identified. Only 0.01 mg of this
GAS should be confirmed and treated in children older than
highly virulent toxin can be fatal. Thus, if antitoxin therapy is
3 years to prevent development of rheumatic fever. Fortunately,
to be effective, it must be administered before the toxin enters
GAS have remained sensitive to penicillin.
the tissue cells. When such organs as the heart and kidneys are
Pharyngitis is now most commonly transmitted by respi-
affected by the toxin, the disease can rapidly be fatal. In other
ratory secretions, but epidemics of streptococcal pharyngitis
cases the nerves can be involved, and partial paralysis results.
spread by unpasteurized milk were once frequent.

Scarlet Fever
When the Streptococcus pyogenes strain causing streptococcal Clubbed cells
pharyngitis produces an erythrogenic (reddening) toxin, the
resulting infection is called scarlet fever. When the strain pro-
duces this toxin, it has been lysogenized by a bacteriophage
(see Figure 13.12, page 375). Recall that this means the genetic
information of a bacteriophage (bacterial virus) has been
incorporated into the chromosome of the bacterium, so the
characteristics of the bacterium have been altered. The toxin
causes a pinkish red skin rash, which is probably the skin’s Palisade
hypersensitivity reaction to the circulating toxin, and a high arrangement

fever. The tongue has a spotted, strawberry-like appearance
and then, as it loses its upper membrane, becomes very red and
enlarged. Classically, scarlet fever has been considered to be
TEM
associated with streptococcal pharyngitis, but it might accom- 1 mm
pany a streptococcal skin infection. Figure 24.4 Corynebacterium diphtheriae, the cause of
It is usually a mild illness, but scarlet fever needs antibiotic diphtheria. This image shows the club-shaped morphology; the
treatment to prevent later development of rheumatic fever. dividing cells are often observed folding together to form V- and
Y-shaped figures. Also notice the side-by-side palisade arrangement.
Diphtheria Q Are corynebacteria gram-positive or gram-negative?
Another bacterial infection of the upper respiratory system is
diphtheria. Until 1935, it was the leading infectious killer of
 CHAPTER 24   Microbial Diseases of the Respiratory System 693

The number of diphtheria cases reported in the United
States each year is currently five or fewer. The disease occurs
mainly in unvaccinated children and travelers to developing
countries. When diphtheria was more common, repeated con- Bulging
eardrum
tacts with toxigenic strains reinforced the immunity, which
otherwise weakens with time. Many adults lack immunity
because immunity wanes over time. A booster dose of vaccine
should be administered every 10 years to maintain protective
antibody levels. Some surveys indicate effective immune levels
in as few as 20% of the adult population. In the United States,
when any trauma in adults requires tetanus toxoid, it is usually
combined with diphtheria toxoid (Td vaccine).
Diphtheria is also expressed as cutaneous diphtheria. In this
form of the disease, C. diphtheriae infects the skin, usually at a
wound or similar skin lesion, and there is minimal systemic cir- Figure 24.5 Acute otitis media, with bulging eardrum.
culation of the toxin. In cutaneous infections, the bacteria cause Q What is the most common bacterium causing middle ear
slow-healing ulcerations that are covered by a gray membrane. infections?
Cutaneous diphtheria is fairly common in tropical countries.
are other S. pneumoniae, nonencapsulated H. influenzae, Morax-
In the past, diphtheria was spread mainly to healthy carri-
ella catarrhalis (more-ax-EL-lah ka-tar-RA-lis) and S. pyogenes. In
ers by droplet infection. Respiratory cases have been known to
about 30% of cases, no bacteria can be detected. Viral infec-
arise from contact with cutaneous diphtheria.
tions may be responsible in these instances; respiratory syncy-
Laboratory diagnosis by bacterial identification is difficult,
tial viruses (see page 708) are the most common isolate.
requiring several selective and differential media. Identifica-
Otitis media affects 85% of children before the age of 3 and
tion is complicated by the need to differentiate toxin-forming
accounts for nearly half of office visits to pediatricians—an
isolates from strains that are not toxigenic; both may be found
estimated 8 million cases each year in the United States. It is
in the same patient.
estimated that ear infections account for about one-fourth of
Even though antibiotics such as erythromycin and penicil-
the prescriptions for antibiotics; however, antibiotics should
lin control the growth of the bacteria, they do not neutralize
be prescribed only if the infection is caused by a bacterium.
the diphtheria toxin. Thus antibiotics should be used only in
Broad-spectrum penicillins, such as amoxicillin, are usually
conjunction with antitoxin.
the first choice for children.
CHECK YOUR UNDERSTANDING
✓ 24-4 Among streptococcal pharyngitis, scarlet fever, or Viral Disease of the
­diphtheria, which two diseases are usually caused by the
same genus of bacteria? Upper Respiratory System
LEARNING OBJECTIVE
24-5 List the causative agents and treatments for the common cold.
Otitis Media
One of the more uncomfortable complications of the com- Probably the most prevalent disease of humans, at least those
mon cold, or of any infection of the nose or throat, is infec- living in the temperate zones, is a viral disease affecting the
tion of the middle ear, otitis media, or earache. The pathogens upper respiratory system—the common cold.
cause the formation of pus, which builds up pressure against
the eardrum and causes it to become inflamed and painful The Common Cold
(­Figure 24.5). The condition is most frequent in early child- More than one virus is involved in the etiology of the common
hood because the auditory tube connecting the middle ear to cold. In fact, there are hundreds—more than 200 different
the throat is small and more horizontal than in adults and so is viruses that are members of several different families of viruses
more easily blocked by infection (see Figure 24.1). are known to cause colds. Identification procedures that
A number of bacteria can cause otitis media. Until this require isolation and culturing often fail to identify the cause
century, S. pneumoniae was the most common cause of otitis of a cold. However, new techniques that use PCR to look for
media. The conjugate vaccine to prevent S. pneumoniae pneu- the viral DNA or RNA make culturing unnecessary and fre-
monia has reduced the incidence of otitis media caused by the quently turn up previously unknown cold viruses. Most cold
strains in the vaccine. The bacteria most frequently involved viruses are rhinoviruses (30–50%); coronaviruses (10–15%)
 Microbial Diseases of
694 PART FOUR Microorganisms and Human Disease
DISEASES IN FOCUS 24.1

the Upper Respiratory System

T
he differential diagnosis for the appears in the throat. Gram-positive rods
following diseases is usually based were cultured from the membrane. Use the
on clinical symptoms, and throat table below to make a differential diagnosis
swabs may be used to culture bacteria. For and identify infections that could cause
example, a patient presents with fever and a these symptoms. For the solution, go to
red, sore throat. Later a grayish membrane @MasteringMicrobiology Grayish membrane in the throat is a
characteristic of this disease.

Disease Pathogen Symptoms Treatment
BACTERIAL DISEASES
Epiglottitis Haemophilus influenzae Inflammation of the epiglottis Antibiotics; maintain airway
Prevention: Hib vaccine
Streptococcal Pharyngitis Streptococci, especially Inflamed mucous membranes of Penicillin
(strep throat) Streptococcus pyogenes the throat

Scarlet Fever Erythrogenic toxin-producing Streptococcal exotoxin causes Penicillin
strains of Streptococcus pyogenes reddening of skin and tongue and
peeling of affected skin
Diphtheria Corynebacterium diphtheriae Grayish membrane forms in throat; Erythromycin and antitoxin
cutaneous form also occurs Prevention: DTaP vaccine
Otitis Media Several agents, especially Accumulations of pus in middle ear Broad-spectum antibiotics
Streptococcus pneumoniae, cause painful pressure on eardrum if bacterial
Haemophilus influenzae, and Prevention: pneumococcal
S. pyogenes vaccine
VIRAL DISEASE
Common Cold Rhinoviruses, coronaviruses; Familiar symptoms of coughing, Supportive
Enterovirus sneezing, runny nose

are also important. However, 20–30% of viruses that cause colder weather in temperate zones. It is not known whether closer
colds are classified by researchers as previously unknown. indoor contact promotes epidemic-type transmission or whether
We tend to accumulate immunities against cold viruses dur- physiological changes increase susceptibility.
ing our lifetime, which may be a reason why older people usually A single rhinovirus deposited on the nasal mucosa is often
have fewer colds. Immunity is based on the ratio of IgA antibod- sufficient to cause a cold. However, there is surprisingly little
ies to single serotypes and has a good short-term effectiveness. agreement on how the cold virus is transmitted to a site in the
Isolated populations may develop a group immunity, and colds nose. Experiments with guinea pigs and the influenza virus
disappear among them until a new set of viruses is introduced. show that viruses tend to be carried on airborne droplets of
The symptoms of the common cold are familiar to all of water vapor. In the dry air (low humidity) typical of low tem-
us. They include sneezing, excessive nasal secretion, and con- peratures, the droplets are smaller and remain airborne longer,
gestion. The infection can easily spread from the throat to the facilitating person-to-person transmission. At the same time,
sinuses, the lower respiratory system, and the middle ear, lead- the cooler air causes the cilia of the ciliary escalator to work
ing to complications of laryngitis and otitis media. The uncom- more slowly, allowing inhaled viruses to spread in the upper
plicated cold usually is not accompanied by fever. It is generally respiratory system.
in the interest of a cold-causing virus not to make the cold Research has shown that during the first 3 days of a cold,
sufferer too ill—the host needs to move around, shedding the nasal mucus contains a high concentration of cold viruses that
virus to others, especially in mucus. multiply in nasal cells. (If mucus is green, the reason is that it
Rhinoviruses thrive at a temperature slightly below that of contains many white blood cells with iron-containing compo-
normal body temperature, such as might be found in the upper nents directed at destroying pathogens.) The viruses in mucus
respiratory system, which is open to the outside environment. No remain viable on surfaces touched by contaminated fingers
one knows exactly why the number of colds seems to increase with for at least several hours. The conventional wisdom is that the
694
 CHAPTER 24   Microbial Diseases of the Respiratory System 695

virus is most likely transmitted through finger contact with Because colds are caused by viruses, antibiotics are of no
the nostrils and eyes (tear ducts communicate with the nose). use in treatment. Symptoms can be relieved by cough suppres-
Transmission also occurs when the cold viruses in airborne sants and antihistamines, but these medications do not speed
droplets from coughing and sneezing land on suitable tissues recovery. There is still considerable truth in the medical adage
in the nose and eyes. that an untreated cold will run its normal course to recovery in
Enterovirus D68 (EV-D68) causes coldlike symptoms. In a week, whereas with treatment it will take 7 days.
2014, the United States experienced a nationwide outbreak of The diseases affecting the upper respiratory system are
EV-D68 associated with severe respiratory illness. Small num- summarized in Diseases in Focus 24.1.
bers of EV-D68 have been reported regularly since 1987. Chil-
dren and teenagers are most likely to get infected with EV-D68 CHECK YOUR UNDERSTANDING
and become ill because they do not yet have immunity from pre- ✓ 24-5 Which viruses, rhinoviruses or coronaviruses, cause
vious exposures to these viruses. Some children may have diffi- about half of the cases of the common cold?
culty breathing, although most people recover within a few days.

Microbial Diseases of the Lower Respiratory System
Many of the same bacteria and viruses that infect the upper bacterium, is responsible for damage to the ciliated cells, and
respiratory system can also infect the lower respiratory system. pertussis toxin enters the bloodstream and is associated with
As the bronchi become involved, bronchitis or bronchiolitis systemic symptoms of the disease.
develops (see Figure 24.2). A severe complication of bronchi- Primarily a childhood disease, pertussis can be quite
tis is pneumonia, in which the pulmonary alveoli become severe. The initial stage, called the catarrhal stage, resembles a
involved. common cold. Prolonged sieges of coughing characterize the
paroxysmal stage, or second stage. (The name pertussis is derived
from the Latin per, meaning thoroughly, and tussis, meaning
Bacterial Diseases of the cough.) When ciliary action is compromised, mucus accumu-
Lower Respiratory System lates, and the infected person desperately attempts to cough
up these mucus accumulations. The violence of the coughing
LEARNING OBJECTIVES
24-6 List the causative agent, symptoms, prevention, preferred
treatment, and laboratory identification tests for pertussis B. pertussis
and tuberculosis.
24-7 Compare and contrast the seven bacterial pneumonias
discussed in this chapter.
24-8 List the etiology, method of transmission, and symptoms
of melioidosis.
Cilium
Bacterial diseases of the lower respiratory system include tuber-
culosis and the many types of pneumonia caused by bacteria.
Lesser-known diseases such as psittacosis and Q fever also fall
into this category.

Pertussis (Whooping Cough)
Infection by the bacterium Bordetella pertussis results in pertussis,
or whooping cough. B. pertussis is a small, obligately aerobic,
SEM
gram-negative coccobacillus. The virulent strains possess a 2 mm

capsule. The bacteria attach specifically to ciliated cells in the Figure 24.6 Ciliated cells of the respiratory system infected
trachea, first impeding their ciliary action and then progres- with Bordetella pertussis. Cells of B. pertussis (orange) can be seen
sively destroying the cells (Figure 24.6). This prevents the cili- growing on the cilia; they will eventually cause the loss of the ciliated cells.
ary escalator system from moving mucus. B. pertussis produces Q W
 hat is the name of the toxin produced by Bordetella pertussis
several toxins. Tracheal cytotoxin, a fixed cell wall fraction of the that causes the loss of cilia?
B I G P I CTU R E Bioterrorism
Biological agents were first tapped by armies, and now by terrorists. Today,
technology and ease of travel increase the potential damage.
History of Bioweapons Biological Weapons Banned in the
Biological weapons (bioweapons)—pathogens intentionally used for Twentieth Century
hostile purposes—are not new. The “ideal” bioweapon is one that The Geneva Conventions are internationally agreed upon standards
disseminates by aerosol, spreads efficiently from human to human, for conducting war. Written in the 1920s, they prohibited deploying
causes debilitating disease, and has no readily available treatment. bioweapons—but did not specify that possessing or creating them
The earliest recorded use of a bioweapon occurred in 1346 was illegal. As such, most powerful nations in the twentieth century
during the Siege of Kaffa, in what is now known as Feodosia, continued to create bioweapons, and the growing stockpiles posed an
Ukraine. There the Tartar army catapulted their own dead soldiers’ ever-growing threat. In 1975, the Biological Weapons Convention
plague-ridden bodies over city walls to infect opposing troops. banned both possession and development of biological weapons. The
Survivors from that attack went on to introduce the “Black Death” majority of the world’s nations ratified the treaty, which stipulated that
to the rest of Europe, sparking the plague pandemic of 1348–1350. any existing bioweapons be destroyed and related research halted.
In the eighteenth century, blankets contaminated with smallpox
were intentionally introduced into Native American populations by SEM
1 mm SEM
the British during the French and Indian War. And during the Sino- 0.4 mm

Japanese War (1937–1945), Japanese planes dropped canisters of
fleas carrying Yersinia pestis bacteria, the causative agent of
plague, on China. In 1975, Bacillus anthracis endospores were
accidentally released from a bioweapon production facility in
Sverdlovsk.

TEM
2 mm

(Clockwise from top left): Bacillus anthracis, Ebolavirus, and Vibrio cholerae
are just a few microbes identified as potential bioterrorism agents.

Emergence of Bioterrorism
Unfortunately, the history of biowarfare doesn’t end with the
A citadel in Ukraine, location of the first known biowarfare attack ratification of the Biological Weapons Convention. Since then, the
in history. main actors engaging in biowarfare have not been nations but
rather radical groups and individuals. One of the most publicized
bioterrorism incidents occurred in 2001, when five people died
Selected Diseases Identified as Potential Bioweapons from, and many more were infected with, anthrax that an army
researcher sent through the mail in letters.
Bacterial Viral

Anthrax (Bacillus anthracis) Nonbacterial meningitis
(Arenaviruses)

Psittacosis (Chlamydophila Hantavirus disease
psittaci)

Botulism (Clostridium botulinum Hemorrhagic fevers (Ebola,
toxin) Marburg, Lassa)

Tularemia (Francisella tularensis) Monkeypox

Cholera (Vibrio cholerae) Nipah virus infection

Plague (Yersinia pestis) Smallpox
Map showing location of 2001 bioterrorism anthrax attacks.
696
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@MasteringMicrobiology

Public Health Authorities Try to Meet the Threat of Bioterrorism
One of the problems with bioweapons is that they contain living Vaccination: A Key Defense
organisms, so their impact is difficult to control or even predict.
When the use of biological agents is considered a possibility,
However, public health authorities have created some protocols to
military personnel and first -responders (health care personnel and
deal with potential bioterrorism incidents.
others) are vaccinated—if a vaccine for the suspected agent
exists. New vaccines are being developed, and existing vaccines
are being stockpiled for use where needed.
The current plan to protect civilians in the event of an attack
with a microbe is illustrated by the smallpox preparedness plan.
This killer disease has been eradicated from the population, but
unfortunately, a cache of the virus remains preserved in research
facilities, meaning that it might one day be weaponized. It’s not
practical to vaccinate all people against the disease. Instead, the
U.S. government’s strategy following a confirmed smallpox
outbreak includes “ring containment and voluntary vaccination.”
A “ring” of vaccinated/protected individuals is built around the
bioterrorism infection case and their contacts to prevent further
transmission.
Biological hazard symbol.

New Technologies and Techniques to
Identify Bioweapons
Monitoring public health, and reporting incidence of
diseases of note, is the first step in any bioterrorism
defense plan. The faster a potential incident is
uncovered, the greater the chance for containment.
Rapid tests are being investigated to detect genetic
changes in hosts due to bioweapons even before
symptoms develop. Early-warning systems, such as
DNA chips or recombinant cells that fluoresce in the
presence of a bioweapon, are also being developed.

Examining mail for B. anthracis.

KEY CONCEPTS
Vaccination is critical to preventing spread of infectious diseases,
especially those that can be weaponized. (See Chapter 18,
“Principles and Effects of Vaccinations,” pages 500–501.)
Many organisms that could be used for weapons require BSL-3
facilities. (See Chapter 6, “Special Culture Techniques,”
pages 161–162.)
Pro Strips Rapid Screening System, developed by ADVNT Biotechnologies
LLC, is the first advanced multi-agent biowarfare detection kit that Tracking pathogen genomics provides information on its source.
tests for anthrax, ricin toxin, botulinum toxin, plague, and SEB (See Chapter 9, “Forensic Microbiology,” pages 258–260.)
(staphylococcal enterotoxin B).
697
698 PART FOUR Microorganisms and Human Disease

in small children can actually result in broken ribs. Gasping
for air between coughs causes a whooping sound, hence the
informal name of the disease. Coughing episodes occur several
times a day for 1 to 6 weeks. The convalescence stage, the third
stage, may last for months. Because infants are less capable of
coping with the effort of coughing to maintain an airway, irre- Corded
versible damage to the brain occasionally occurs. growth
Diagnosis of pertussis is primarily based on clinical signs
and symptoms. The pathogen can be cultured from a throat
swab inserted through the nose on a thin wire and held in the
throat while the patient coughs. Culture of the fastidious patho- LM
2.5 mm
gen requires care. As alternatives to culture, PCR methods can
also be used to test the swabs for presence of the pathogen, a Figure 24.7 Mycobacterium tuberculosis. The filamentous, red-
procedure that is required to diagnose the disease in infants. stained funguslike growth shown here in a smear from lung tissue is
Treatment of pertussis with antibiotics, most commonly responsible for the organism’s name. Under other conditions, it grows
as slender, individual bacilli. A waxy component of the cell, cord factor,
erythromycin or other macrolides, is not effective after onset of
is responsible for this ropelike arrangement. An injection of cord factor
the paroxysmal coughing stage but may reduce transmission. causes pathogenic effects exactly like those caused by tubercle bacilli.

Q What characteristic of this bacterium suggests use of the
CHECK YOUR UNDERSTANDING prefix myco-?
✓ 24-6 Another name for pertussis is whooping cough. This
symptom is caused by the pathogens’ attack on which cells?
Other mycobacterial diseases also affect people in the
late stages of HIV infection. A majority of the isolates are of a
Tuberculosis related group of organisms known as the M. avium-intracellulare
In Europe during the seventeenth through the nineteenth centu- (a-ve-um
ˉ ˉ in-trah-SEI-u-lar)
ˉ complex. In the general population,
ries, tuberculosis (TB) was responsible for an estimated 20–30% infections by these pathogens are uncommon.
of all deaths. This probably exerted a strong selection pressure for Mycobacteria stained with carbolfuchsin dye cannot be
genes that protected against TB in this population. However, in decolorized with acid-alcohol and are therefore classified as
recent decades co-infection with HIV has been a prominent cause acid-fast (see page 66). This characteristic reflects the unusual
of increasing susceptibility to infection and also of rapid progres- composition of the cell wall, which contains large amounts of
sion from infection to active disease. Other factors are the increas- lipids. These lipids might also be responsible for the resistance
ing populations of susceptible individuals in prisons and other of mycobacteria to environmental stresses, such as drying. In
crowded facilities, as well as the elderly or undernourished. fact, these bacteria can survive for weeks in dried sputum and
Tuberculosis is an infectious disease caused by the bacte- are very resistant to chemical antimicrobials used as antisep-
rium Mycobacterium tuberculosis, a slender rod and an obligate tics and disinfectants (see Table 7.7, page 198).
aerobe. The rods grow slowly (20-hour or longer generation Tuberculosis is a particularly good illustration of the eco-
time), sometimes form filaments, and tend to grow in clumps logical balance between host and parasite in infectious dis-
(Figure 24.7). On the surface of liquid media, their growth ease. A host is not usually aware of tuberculosis pathogens that
appears moldlike, which suggested the genus name Mycobacte- invade the body and are defeated, which occurs 90% of the
rium (myco means fungus). time. If immune defenses fail, however, the host becomes very
ˉ
Another mycobacterial species, Mycobacterium bovis (BO-vis), much aware of the resulting disease.
is a pathogen mainly of cattle. M. bovis is the cause of bovine A tragic demonstration of individual variation in resis-
tuberculosis, which is transmitted to humans via contami- tance was the Lübeck disaster in Germany in 1926. By error,
nated milk or food. Bovine tuberculosis accounts for fewer 249 babies were inoculated with virulent tuberculosis bacte-
than 1% of TB cases in the United States. It seldom spreads ria instead of the attenuated vaccine strain. Even though all
from human to human, but before the days of pasteurized received the same inoculum, there were only 76 deaths, and
milk and the development of control methods such as tuber- the remainder did not become seriously ill.
culin testing of cattle herds, this disease was a frequent form Tuberculosis is most commonly acquired by inhaling the
of tuberculosis in humans. M. bovis infections cause TB that bacillus. Only very fine particles containing one to three bacilli
primarily affects the bones or lymphatic system. At one time, reach the lungs, where they are usually phagocytized by a
a common manifestation of this type of TB was hunchbacked macrophage in the alveoli (see Figure 24.2). The macrophages
deformation of the spine. of a healthy individual become activated by the presence of
 CHAPTER 24  Microbial Diseases of the Respiratory System 699

the bacilli and usually destroy them. About three-fourths of in which the body’s defenses fail and the disease progresses to
TB cases affect the lungs, but other organs can also become a fatal conclusion. However, most healthy people will defeat
infected. a potential infection with activated macrophages, especially if
the infecting dose is low.
Pathogenesis of Tuberculosis
1 1–2 2 3 3If4the
4 5 5infection
6 6 7 7 8 8 9progresses,
the host isolates the pathogens
9 1010
The pathogenesis of TB is shown in Figure 24.8. An important
in a walled-off lesion called a tubercle (meaning lump or
factor in the pathogenicity of the mycobacteria probably is that
knob), a characteristic that gives the disease its name.
the mycolic acids of the cell wall strongly stimulate an inflam-
matory response in the host. The figure depicts the situation

Interior of 1 Tubercle bacilli that reach the alveoli of the lung are
alveolus ingested by macrophages, but often some survive.
Blood capillary
Infection is present, but no symptoms of disease.
Alveolar walls
Interior of alveolus
Ingested tubercle
bacillus

Alveolar macrophage

Bronchiole
2 Tubercle bacilli multiplying in macrophages cause
a chemotactic response that brings additional
macrophages and other defensive cells to the area.
Infiltrating macrophage These form a surrounding layer and, in turn, an early
(not activated) tubercle. Most of the surrounding macrophages are
not successful in destroying bacteria but release
Early tubercle enzymes and cytokines that cause a lung-
damaging inflammation.

3 After a few weeks, disease symptoms appear as
Tubercle bacillus many of the macrophages die, releasing tubercle
bacilli and forming a caseous center in the tubercle.
Caseous center The aerobic tubercle bacilli do not grow well in this
Activated macrophages location. However, many remain dormant (latent TB)
and serve as a basis for later reactivation of the
Lymphocyte disease. The disease may be arrested at this stage,
and the lesions become calcified.

4 In some individuals, disease symptoms appear as a
Outer layer of mature mature tubercle is formed. The disease progresses as
tubercle the caseous center enlarges in the process called
liquefaction. The caseous center now enlarges and
Tuberculous cavity forms an air-filled tuberculous cavity in which the
aerobic bacilli multiply outside the macrophages.
Tubercle bacillus

5 Liquefaction continues until the tubercle ruptures,
allowing bacilli to spill into a bronchiole and thus
be disseminated throughout the lung and then to
the circulatory and lymphatic systems.
Rupture of
alveolar wall

Figure 24.8 The pathogenesis of tuberculosis. This figure represents the progression
of the disease when the defenses of the body fail. In most otherwise healthy individuals, the
infection is arrested, and fatal tuberculosis does not develop.

Q Almost a third of Earth’s population is infected with Mycobacterium tuberculosis—does
a study of this figure show why this is not the same as a third of Earth’s population
having tuberculosis?
 700 PART FOUR Microorganisms and Human Disease

1 2 3 4When
5 6 the
7 8disease
9 10 is arrested at this point, the lesions
slowly heal, becoming calcified. These show up clearly on
X-ray films and are called Ghon’s complexes. (Computed
tomography [CT] is more sensitive than X rays in detecting
lesions of TB.) The bacteria may remain viable for years, in
which case the disease is called latent TB. Such individuals
are infected with M. tuberculosis but do not have TB. The
only sign of TB infection is a positive reaction to the
tuberculin skin test or TB blood test. Persons with latent
TB infection are not infectious and cannot spread TB
infection to others.
1 2 3 4 Macrophages
5 6 7 8 9 10ingest and surround the tubercle bacilli,
forming a barrier outer layer.
1 2 3 4 5 6If the
7 8body’s
9 10defenses fail at this stage, the tubercle breaks
down and releases virulent bacilli into the airways of the Figure 24.9 A positive tuberculin skin test on an arm.
lung and then the cardiovascular and lymphatic systems.
Q What does a positive tuberculin skin test indicate?
Coughing, the more obvious symptom of the lung infec-
tion, also spreads the infection by bacterial aerosols. Sputum
may become bloodstained as tissues are damaged, and even- The initial step in laboratory diagnosis of active cases is a
tually blood vessels may become so eroded that they rupture, microscopic examination of smears, such as sputum. According
resulting in fatal hemorrhaging. The disseminated infection is to recent medical opinion, the commonly used 125-year-old
called miliary tuberculosis (the name is derived from the numer- microscopic exam routinely misses half of all cases. Confirm-
ous millet seed–sized tubercles formed in the infected tissues). ing a diagnosis of TB by isolating the bacterium poses difficul-
The body’s remaining defenses are overwhelmed, and the patient ties because the pathogen grows very slowly. A colony might
suffers weight loss and a general loss of vigor. At one time, TB take 3 to 6 weeks to form, and completing a reliable identifica-
was also known as consumption. tion series may add another 3 to 6 weeks.
Blood tests measure release of IFN-γ from white blood
Diagnosis of Tuberculosis cells after exposure to mycobacterial antigen in a test tube.
People infected with tuberculosis respond with cell-mediated They are the preferred tests for a person who has received BCG
immunity against the bacterium. This form of immune vaccinations.
response, rather than humoral immunity, develops because the Nucleic acid amplification tests (NAATs) can detect M. tuber-
pathogen is located mostly within macrophages. This immu- culosis 1 to 2 weeks sooner than cultures and at the same time
nity, involving sensitized T cells, is the basis for the tuberculin can determine resistance to a major TB antibiotic, rifampin.
skin test (Figure 24.9), a screening test for infection. A positive Evidence indicates that, compared to the skin test, these
test does not necessarily indicate active disease. In this test, rapid tests have higher specificity and less cross-reactivity with
a purified protein derivative of the tuberculosis bacterium, BCG vaccination (see the discussion of TB vaccines, following).
derived by precipitation from broth cultures, is injected cuta- They do not distinguish latent from active infection. These
neously. If the injected person has been infected with TB in the assays seem likely to replace the tuberculin skin test for many
past, sensitized T cells react with these proteins, and a delayed uses, especially where cross-reactivity with BCG vaccination is
hypersensitivity reaction occurs in about 48 hours. This reac- a problem. If they could be adopted worldwide at centers for TB
tion appears as an induration (hardening) and reddening of treatment, they would help avert millions of TB-related deaths.
the area around the injection site. In this test, known as the
Treatment of Tuberculosis
Mantoux test, dilutions of 0.1 ml of antigen are injected and the
reacting area of the skin is measured. The first effective antibiotic for TB treatment was streptomy-
A positive tuberculin test in the very young is a probable cin, which was introduced in 1944. Streptomycin is still in use,
indication of an active case of TB. In older individuals, it might and all of the currently used drugs were developed decades
indicate only hypersensitivity resulting from a previous infec- ago. Even the short course of treatment for TB (there are varia-
tion or vaccination, not a current active case. Nonetheless, it tions in the regimen, depending on sensitivity of the organism
is an indication that further examination is needed, such as and other factors) requires the patient to adhere to a mini-
a chest X-ray or CT examination to detect lung lesions and mum of 6 months of therapy. Multiple-drug therapy is needed
attempts to isolate the bacterium. to minimize the emergence of resistant strains. This typically
 CHAPTER 24  Microbial Diseases of the Respiratory System 701

includes four drugs, isoniazid, rifampin, ethambutol, and pyr- rifampin, is not due to a single gene. One new test, MTBDRsl,
azinamide, which are considered first-line drugs. If the strain does identify resistance to fluoroquinolones.
of M. tuberculosis is susceptible to the drugs, this regimen can
lead to a cure. The likelihood that resistance may develop is Tuberculosis Vaccines
increased because many patients fail to faithfully follow such a The BCG vaccine is a live culture of M. bovis that has been
prolonged regimen, which can involve 130 doses of the drugs. made avirulent by long cultivation on artificial media. (BCG
In addition to the first-line drugs, there are a number of stands for bacillus of Calmette and Guérin, the French scien-
­second-line drugs that can be used, mainly if resistance devel- tists who originally isolated the strain.) The BCG vaccine has
ops to alternatives. These include several aminoglycosides, been available since the 1920s and is one of the most widely
fluoroquinolones, streptomycin, and para-aminosalicylic acid used vaccines in the world. In 1990, it was estimated that
(PAS). These drugs are either less effective than first-line drugs, 70% of the world’s schoolchildren received it. In the United
have toxic side effects, or may be unavailable in some countries. States, however, the vaccine is currently recommended only
The prolonged treatment is necessary because the tubercle for certain children at high risk who have negative skin tests.
bacillus grows very slowly or is only dormant (the only drug People who have received the vaccine show a positive reaction
effective against the dormant bacillus is pyrazinamide), and to tuberculin skin tests. This has always been one argument
many antibiotics are effective only against growing cells. Also, against its widespread use in the United States. Another argu-
the bacillus may be hidden for long periods in macrophages or ment against the universal administration of BCG vaccine is its
other locations that are difficult to reach with antibiotics. very uneven effectiveness. Experience has shown that it is fairly
Not surprisingly, problems have arisen with cases of TB that effective when given to young children, but for adolescents
are caused by multi-drug-resistant (MDR) strains. These are and adults it sometimes has an effectiveness approaching zero.
defined as being resistant to the two most effective first-line Worse, it has been found that HIV-infected children, who need
drugs, isoniazid and rifampin. In addition, strains have arisen it most, frequently will develop a fatal infection from the BCG
that are also resistant to the most effective second-line drugs, vaccine. Recent work indicates that exposure to members of the
such as any fluoroquinolone, and to at least one of three inject- M. avium-intracellulare complex that is often encountered in the
able second-line drugs, such as the aminoglycosides amikacin environment may interfere with the effectiveness of the BCG
or kanamycin, as well as the polypeptide capreomycin. These vaccine—which might explain why the vaccine is more effec-
cases, defined as extensively drug-resistant (XDR), are vir- tive early in life, before much exposure to such environmental
tually untreatable and are emerging globally. An additional mycobacteria. A number of new vaccines are in the experimen-
consideration is that anywhere from 30–90% of persons with tal pipeline, but they will require large numbers of human
TB are also HIV positive—with the accompanying damage to samples and several years of follow-up to evaluate.
the immune system. In one study, all patients testing positive
for both HIV and XDR tuberculosis died within 3 months of Worldwide Incidence of Tuberculosis
diagnosis. Tuberculosis has emerged as a global pandemic (Figure 24.10a).
Obviously, there is a pressing need for new, effective drugs Estimates are that more than 10 million people develop active
to treat TB, especially XDR cases. In 2012, bedaquiline was tuberculosis every year and that infections result in nearly
approved to treat MDR TB. 2 million deaths annually. (Worldwide, the incidence of TB per
capita is falling at about 1% a year. However, the world pop-
Testing for Drug Susceptibility ulation is growing at about 2% a year—therefore, the total
Solid-media culture-based methods for drug susceptibility number of new TB cases is still rising.) Probably a third of the
testing can take as long as 4 to 8 weeks for finalized results. world’s population has latent TB. Also, HIV and tuberculosis
However, M. tuberculosis grows faster in liquid media. These are almost inseparable, and tuberculosis is the leading direct
assays are simultaneously useful for both diagnosis and deter- cause of death in much of the world affected by HIV.
mination of drug susceptibility. The Microscopic-Observation TB incidence in the United States steadily decreased for
Drug-Susceptibility Assay (MODS) is based on direct obser- decades (see Figure 14.11c, page 415). The incidence has been
vation of the typical cording growth (see Figure 24.7) of approximately three cases per 100,000 people for the past few
M. tuberculosis in liquid cultures, requires only 6 to 8 days, and years, with two-thirds of the cases occurring among foreign-
is relatively inexpensive. The determination of susceptibility born people (Figure 24.10b).
for rifampin can be considered a marker for potential resistance
to other drugs. Recall that NAATs also rapidly test for rifampin Bacterial Pneumonias
resistance. NAATs are needed to determine resistance to the The term pneumonia is applied to many pulmonary infections,
other first-line and second-line anti-TB drugs. The biggest most of which are caused by bacteria. Pneumonia caused by
problem is that most drug resistance, aside from resistance to Streptococcus pneumoniae is the most common, about two-thirds
702 PART FOUR Microorganisms and Human Disease

KEY

0–24.9
25–99
100–199
200–299
≥300
No data
Not applicable

(a) Estimated tuberculosis incidence worldwide in 2016, per 100,000 population

(b) Reported tuberculosis
Asian cases among American ethnic
groups in 2016
U.S.-born

Hispanic

Black

White

Asian
Foreign.-born

Hispanic

Black

White

0 500 1000 1500 2000 2500 3000
Reported number of cases

Figure 24.10 Distribution of tuberculosis. (a) Tuberculosis worldwide. (b) Tuberculosis
in the United States. Rates among American ethnic groups.
Source: World Health Organization (WHO), 2017; MMWR 65(11): 273–278, March 24, 2017.

Q How can tuberculosis be eliminated?

of cases, and is therefore referred to as typical pneumonia. Pneu- Pneumonias also are named after the portions of the lower
monias caused by other microorganisms, which can include respiratory tract they affect. For example, if the lobes of the
fungi, protozoa, viruses, and other bacteria, especially myco- lungs are infected, it is called lobar pneumonia; pneumonias
plasma, are termed atypical pneumonias. This distinction is caused by S. pneumoniae are usually of this type. Bronchopneu-
becoming increasingly blurred in practice. monia indicates that the alveoli of the lungs adjacent to the
 CHAPTER 24  Microbial Diseases of the Respiratory System 703

bronchi are infected. Pleurisy is often a complication of various
pneumonias, in which the pleural membranes become pain-
fully inflamed. (See Diseases in Focus 24.2.)

Pneumococcal Pneumonia
Pneumonia caused by S. pneumoniae is called pneumococcal
pneumonia. S. pneumoniae is a gram-positive, ovoid bacterium
(Figure 24.11). This microbe is also a common cause of otitis
media, meningitis, and sepsis. The cell pairs are surrounded by
a dense capsule that makes the pathogen resistant to phagocy- Capsules

tosis. These capsules are also the basis of serological differen-
tiation of pneumococci into at least 90 serotypes. Most human
infections are caused by only 23 variants, and these are the
basis of current vaccines.
Pneumococcal pneumonia involves both the bronchi and
the alveoli (see Figure 24.2). Symptoms include high fever, TEM
1 mm
breathing difficulty, and chest pain. (Atypical pneumonias
Figure 24.11 Streptococcus pneumoniae, the cause of
usually have a slower onset and less fever and chest pain.) The
pneumococcal pneumonia. Some of the cocci in the photo are
lungs have a reddish appearance because blood vessels are undergoing division and appear as extended ovals. The prominent
dilated. In response to the infection, alveoli fill with some red capsule appears as a bright outline.
blood cells, neutrophils (see Table 16.1, page 454), and fluid
Q What component of the cell is the primary antigen?
from surrounding tissues. The sputum is often rust colored
from blood coughed up from the lungs. Pneumococci can
invade the bloodstream, the pleural cavity surrounding the The pneumococcal polysaccharide vaccine, recommended
lung, and occasionally the meninges. No bacterial toxin has for people with asthma and for older adults, protects against
been clearly related to pathogenicity. 23 strains of the bacteria.
A presumptive diagnosis can be made by isolating the
pneumococci from the throat, sputum, and other fluids. Pneu- Haemophilus influenzae Pneumonia
mococci can be distinguished from other alpha-hemolytic Haemophilus influenzae is a gram-negative coccobacillus, and
streptococci by observing the inhibition of growth next to a a Gram stain of sputum will differentiate this type of pneu-
disk of optochin (ethylhydrocupreine hydrochloride) or by monia from pneumococcal pneumonia. Children under 5 and
performing a bile solubility test. A latex indirect agglutination adults over 65 are most at risk for infection. The Hib vaccine
test (see Figure 18.7, page 512) that detects a capsule antigen of has reduced the incidence in children by 99%. Diagnostic iden-
S. pneumoniae in the urine can be performed in a physician’s office tification of the pathogen uses special media that determine
and, with 93% accuracy, can make a d ­ iagnosis in 15 minutes. requirements for X and V factors (see page 305). Third-generation
There are many healthy carriers of the pneumococcus. Vir- cephalosporins are resistant to the b-lactamases produced by
ulence of the bacteria seems to be based mainly on the carrier’s many H. influenzae strains and are therefore usually the drugs
resistance, which can be lowered by stress. Many illnesses of of choice.
older adults terminate in pneumococcal pneumonia.
A recurrence of pneumococcal pneumonia is not uncom- Mycoplasmal Pneumonia
mon, but the serological types are usually different. Before The mycoplasmas, which do not have cell walls, do not grow
chemotherapy was available, the mortality rate was as high as under the conditions normally used to recover most bacterial
25%. This has now been lowered to 5–7%. About 90% of the pathogens. Because of this characteristic, pneumonias caused
900,000 infections that occur annually are in adults. by mycoplasmas are often confused with viral pneumonias.
Antibiotic resistance is an increasing problem. Treatment The bacterium Mycoplasma pneumoniae is the causative agent
usually begins with a broad-spectrum cephalosporin until of mycoplasmal pneumonia. This type of pneumonia was first
antibiotic-sensitivity testing is done (see Figure 20.17, page 578). discovered when such atypical infections responded to tetracy-
Possible drugs include a b-lactam, macrolide, or fluoroquinoline. clines, indicating that the pathogen was nonviral. Mycoplasmal
A conjugated pneumococcal vaccine has been effective in pneumonia is a common type of pneumonia in young adults
preventing infection by the 13 serotypes included in it. It has and children. It may account for as much as 20% of pneumo-
also had an indirect herd effect shown by reduction in other nias, although it is not a reportable disease. The symptoms,
diseases, such as otitis media, attributable to the pneumococcus. which persist for 3 weeks or longer, are low-grade fever, cough,
DISEASES IN FOCUS 24.2 Common Bacterial Pneumonias

P
neumonia is a leading cause of illness A 27-year-old man with a history of
and death among children worldwide and asthma is hospitalized with a 4-day history
the seventh leading case of death in the of progressive cough and 2 days of spiking
United States. Pneumonia can be caused by a fevers. Gram-positive cocci in pairs are
variety of viruses, bacteria, and fungi. To prove cultured from a blood sample. Use the table
that a bacterium is causing the pneumonia, below to identify infections that could cause
the bacterium is isolated from cultures of these symptoms. For the solution, go to
blood or, in some cases, lung aspirates. @MasteringMicrobiology.

An optochin-inhibition test of the cultured
bacteria on blood agar.

Disease Pathogen Symptoms Reservoir Diagnosis Treatment

Pneumococcal Streptococcus Infected alveoli of lung fill Humans Positive optochin Macrolides
Pneumonia pneumoniae with fluids; interferes with inhibition test or bile Prevention:
oxygen uptake solubility test; presence pneumococcal
of capsular antigen vaccine

Haemophilus Haemophilus Symptoms resemble Humans Isolation; special Cephalosporins
influenzae influenzae pneumococcal pneumonia media for nutritional Prevention: Hib
Pneumonia requirements vaccine

Mycoplasmal Mycoplasma Mild but persistent Humans Isolation of bacteria Tetracyclines
Pneumonia pneumoniae respiratory symptoms; low
fever, cough, headache

Legionellosis Legionella Potentially fatal pneumonia Water Culture on selective Azithromycin
pneumophila media

Psittacosis Chlamydophila Symptoms, if any, are fever, Birds Bacterial culture or PCR Tetracyclines
(Ornithosis) psittaci headache, chills

Chlamydial Chlamydophila Mild respiratory illness; Humans PCR Azithromycin
Pneumonia pneumoniae resembles mycoplasmal
pneumonia

Q Fever Coxiella Mild respiratory disease Large mammals; Increasing antibody titer Doxycycline and
burnetii lasting 1–2 weeks; can be transmitted chloroquine
occasional complications via unpasteurized
such as endocarditis occur milk

and headache. Occasionally, they are severe enough to lead to be required for the slow-growing organisms to develop. Rapid
hospitalization. Other terms for the disease are primary atypical PCR tests are becoming available; however, they are expensive
(that is, the most common pneumonia not caused by the pneu- and have not been clinically validated.
mococcus) and walking pneumonia. Treatment with antibiotics such as tetracycline usually has-
When isolates from throat swabs and sputum grow on a tens the disappearance of symptoms but does not eliminate the
medium containing horse serum and yeast extract, some form bacteria, which the patient continues to carry for several weeks.
distinctive colonies with a “fried-egg” appearance (Figure 24.12).
The colonies are so small that they must be observed Legionellosis
with magnification. The mycoplasmas are highly varied Legionellosis, or Legionnaires’ disease, first received pub-
in appearance because they lack cell walls (see Figure 11.24, lic attention in 1976, when a series of deaths occurred among
page 316). members of the American Legion who had attended a meet-
Diagnosis based on recovering the pathogens might not be ing in Philadelphia. Because no obvious bacterial cause could
useful in treatment because as long as 3 or more weeks may be found, the deaths were attributed to viral pneumonia.
704
 CHAPTER 24  Microbial Diseases of the Respiratory System 705

Men over 50 are the most likely to contract legionellosis, espe-
cially smokers or the chronically ill. (See the Clinical Focus
box on page 708.)
L. pneumophila is also responsible for Pontiac fever, which is
essentially another form of legionellosis. Its symptoms include
fever, muscular aches, and usually a cough. The condition is
mild and self-limiting. During outbreaks of legionellosis, both
forms may occur.
The best diagnostic method is culture on a selective charcoal–
yeast extract medium. Serological tests to detect O antigen in
urine are available. However, these tests detect only one sero-
group. Azithromycin and other macrolide antibiotics are the
drugs of choice for treatment.
LM
175 mm Psittacosis (Ornithosis)
Figure 24.12 Colonies of Mycoplasma pneumoniae, the cause The term psittacosis is derived from the disease’s association
of mycoplasmal pneumonia. with psittacine birds, such as parakeets and other parrots. It was
Q Could you see these colonies without magnification? later found that the disease can also be contracted from many
other birds, such as pigeons, chickens, ducks, and turkeys.
Therefore, the more general term ornithosis has come into use.
Close investigation, mostly with techniques directed at locat- The causative agent is Chlamydophila psittaci (SIT-tah-se),
ˉ a
ing a suspected rickettsial agent, eventually identified a previ- gram-negative, obligate intracellular bacterium. The taxonomy
ously unknown bacterium, an aerobic gram-negative rod now of this organism has recently been revised. The genus name
known as Legionella pneumophila, which is capable of replica- has been changed from Chlamydia to Chlamydophila. This taxo-
tion within macrophages. Over 44 species of Legionella have nomic change has also been made with C. pneumoniae (see the
now been identified; not all of them cause disease. discussion of chlamydial pneumonia that follows). We will
The disease is characterized by a high fever of 40.5°C, continue to use the generic terms chlamydial and chlamydiae.
cough, and general symptoms of pneumonia. No person-to- One way chlamydiae differ from rickettsias, which are also
person transmission seems to be involved. Recent studies have obligate intracellular bacteria, is that chlamydiae form tiny
shown that the bacterium can be readily isolated from natu- ­elementary bodies as one part of their life cycle (see Figure
ral waters. In addition, the microbes can grow in the water of 11.15, page 310). Unlike most rickettsias, elementary bodies
air-conditioning cooling towers, perhaps indicating that some are resistant to environmental stress; therefore, they can be
epidemics in hotels, urban business districts, and hospitals transmitted through air and do not require a bite to transfer
were caused by airborne transmission. Recent outbreaks have the infective agent directly from one host to another.
been traced to whirlpool spas, humidifiers, showers, decorative Psittacosis is a form of pneumonia that usually causes fever,
fountains, and even potting soil. coughing, headache, and chills. Subclinical infections are very
The organism has also been found to inhabit the water lines common, and stress appears to enhance susceptibility to the
of many hospitals. Most hospitals keep the temperature of hot disease. Disorientation, or even delirium in some cases, indi-
water lines relatively low (43–55°C) as a safety measure, and in cates that the nervous system can be involved.
cooler parts