Microbiology Review Questions PDF

Summary

This document contains review questions on microbiology, focusing on antimicrobial drugs, drug resistance, and testing methods. The questions are a mix of multiple-choice and true/false.

Full Transcript

14 Review Questions 587

resistant, HIV is typically treated with a to various antimicrobial drugs. However, the
combination of several antiretroviral drugs, zones of inhibition measured must be correlated
which may include reverse transcriptase to known standards to determine susceptibility
inhibitors, protease inhibitors, integrase and resistance, and do not provide information
inhibitors, and drugs that interfere with viral on bactericidal versus bacteriostatic activity, or
binding and fusion to initiate infection. allow for direct comparison of drug potencies.
Antibiograms are useful for monitoring local
14.5 Drug Resistance trends in antimicrobial resistance/susceptibility
Antimicrobial resistance is on the rise and is the and for directing appropriate selection of empiric
result of selection of drug-resistant strains in antibacterial therapy.
clinical environments, the overuse and misuse of There are several laboratory methods available
antibacterials, the use of subtherapeutic doses of for determining the minimum inhibitory
antibacterial drugs, and poor patient compliance concentration (MIC) of an antimicrobial drug
with antibacterial drug therapies. against a specific microbe. The minimal
Drug resistance genes are often carried on bactericidal concentration (MBC) can also be
plasmids or in transposons that can undergo determined, typically as a follow-up experiment
vertical transfer easily and between microbes to MIC determination using the tube dilution
through horizontal gene transfer. method.
Common modes of antimicrobial drug resistance
14.7 Current Strategies for Antimicrobial
include drug modification or inactivation,
prevention of cellular uptake or efflux, target
Discovery
modification, target overproduction or enzymatic Current research into the development of
bypass, and target mimicry. antimicrobial drugs involves the use of high-
Problematic microbial strains showing extensive throughput screening and combinatorial
antimicrobial resistance are emerging; many of chemistry technologies.
these strains can reside as members of the New technologies are being developed to
normal microbiota in individuals but also can discover novel antibiotics from soil
cause opportunistic infection. The transmission microorganisms that cannot be cultured by
of many of these highly resistant microbial standard laboratory methods.
strains often occurs in clinical settings, but can Additional strategies include searching for
also be community-acquired. antibiotics from sources other than soil,
identifying new antibacterial targets, using
14.6 Testing the Effectiveness of
combinatorial chemistry to develop novel drugs,
Antimicrobials developing drugs that inhibit resistance
The Kirby-Bauer disk diffusion test helps mechanisms, and developing drugs that target
determine the susceptibility of a microorganism virulence factors and hold infections in check.

Review Questions
Multiple Choice
1. A scientist discovers that a soil bacterium he has C. synthetic
been studying produces an antimicrobial that D. natural
kills gram-negative bacteria. She isolates and
purifies the antimicrobial compound, then 2. Which of the following antimicrobial drugs is
chemically converts a chemical side chain to a synthetic?
hydroxyl group. When she tests the antimicrobial A. sulfanilamide
properties of this new version, she finds that this B. penicillin
antimicrobial drug can now also kill gram- C. actinomycin
positive bacteria. The new antimicrobial drug D. neomycin
with broad-spectrum activity is considered to be
which of the following? 3. Which of the following combinations would most
A. resistant likely contribute to the development of a
B. semisynthetic superinfection?
588 14 Review Questions

A. long-term use of narrow-spectrum activity of DNA gyrase?
antimicrobials A. polymyxin B
B. long-term use of broad-spectrum B. clindamycin
antimicrobials C. nalidixic acid
C. short-term use of narrow-spectrum D. rifampin
antimicrobials
D. short-term use of broad-spectrum 10. Which of the following is not an appropriate
antimicrobials target for antifungal drugs?
A. ergosterol
4. Which of the following routes of administration B. chitin
would be appropriate and convenient for home C. cholesterol
administration of an antimicrobial to treat a D. β(1→3) glucan
systemic infection?
A. oral 11. Which of the following drug classes specifically
B. intravenous inhibits neuronal transmission in helminths?
C. topical A. quinolines
D. parenteral B. avermectins
C. amantadines
5. Which clinical situation would be appropriate for D. imidazoles
treatment with a narrow-spectrum antimicrobial
drug? 12. Which of the following is a nucleoside analog
A. treatment of a polymicrobic mixed commonly used as a reverse transcriptase
infection in the intestine inhibitor in the treatment of HIV?
B. prophylaxis against infection after a A. acyclovir
surgical procedure B. ribavirin
C. treatment of strep throat caused by C. adenine-arabinoside
culture identified Streptococcus pyogenes D. azidothymidine
D. empiric therapy of pneumonia while
waiting for culture results 13. Which of the following is an antimalarial drug
that is thought to increase ROS levels in target
6. Which of the following terms refers to the ability cells?
of an antimicrobial drug to harm the target A. artemisinin
microbe without harming the host? B. amphotericin b
A. mode of action C. praziquantel
B. therapeutic level D. pleconaril
C. spectrum of activity
D. selective toxicity 14. Which of the following resistance mechanisms
describes the function of β-lactamase?
7. Which of the following is not a type of β-lactam A. efflux pump
antimicrobial? B. target mimicry
A. penicillins C. drug inactivation
B. glycopeptides D. target overproduction
C. cephalosporins
D. monobactams 15. Which of the following resistance mechanisms is
commonly effective against a wide range of
8. Which of the following does not bind to the 50S antimicrobials in multiple classes?
ribosomal subunit? A. efflux pump
A. tetracyclines B. target mimicry
B. lincosamides C. target modification
C. macrolides D. target overproduction
D. chloramphenicol
16. Which of the following resistance mechanisms is
9. Which of the following antimicrobials inhibits the the most nonspecific to a particular class of

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 14 Review Questions 589

antimicrobials? used to determine the minimum inhibitory
A. drug modification concentration of an antimicrobial drug against a
B. target mimicry particular microbe?
C. target modification A. Etest
D. efflux pump B. microbroth dilution test
C. Kirby-Bauer disk diffusion test
17. Which of the following types of drug-resistant D. macrobroth dilution test
bacteria do not typically persist in individuals as
a member of their intestinal microbiota? 20. The utility of an antibiogram is that it shows
A. MRSA antimicrobial susceptibility trends
B. VRE A. over a large geographic area.
C. CRE B. for an individual patient.
D. ESBL-producing bacteria C. in research laboratory strains.
D. in a localized population.
18. In the Kirby-Bauer disk diffusion test, the
_______ of the zone of inhibition is measured 21. Which of the following has yielded compounds
and used for interpretation. with the most antimicrobial activity?
A. diameter A. water
B. microbial population B. air
C. circumference C. volcanoes
D. depth D. soil

19. Which of the following techniques cannot be

True/False
22. Narrow-spectrum antimicrobials are commonly 25. If drug A produces a larger zone of inhibition
used for prophylaxis following surgery. than drug B on the Kirby-Bauer disk diffusion
test, drug A should always be prescribed.
23. β-lactamases can degrade vancomycin.
26. The rate of discovery of antimicrobial drugs has
24. Echinocandins, known as “penicillin for fungi,”
decreased significantly in recent decades.
target β(1→3) glucan in fungal cell walls.

Fill in the Blank
27. The group of soil bacteria known for their ability effective against the influenza virus by
to produce a wide variety of antimicrobials is preventing viral escape from host cells are called
called the ________. ________.

28. The bacterium known for causing 31. Staphylococcus aureus, including MRSA strains,
pseudomembranous colitis, a potentially deadly may commonly be carried as a normal member
superinfection, is ________. of the ________ microbiota in some people.

29. Selective toxicity antimicrobials are easier to 32. The method that can determine the MICs of
develop against bacteria because they are multiple antimicrobial drugs against a microbial
________ cells, whereas human cells are strain using a single agar plate is called the
eukaryotic. ________.

30. Antiviral drugs, like Tamiflu and Relenza, that are

Short Answer
33. Where do antimicrobials come from naturally? the patient’s health history should the clinician
Why? ask about and why?

34. Why was Salvarsan considered to be a “magic 36. When is using a broad-spectrum antimicrobial
bullet” for the treatment of syphilis? drug warranted?

35. When prescribing antibiotics, what aspects of 37. If human cells and bacterial cells perform
590 14 Review Questions

transcription, how are the rifamycins specific for niclosamide aid its effectiveness as a treatment
bacterial infections? for tapeworm infection?

38. What bacterial structural target would make an 41. Why does the length of time of antimicrobial
antibacterial drug selective for gram-negative treatment for tuberculosis contribute to the rise
bacteria? Provide one example of an of resistant strains?
antimicrobial compound that targets this
42. What is the difference between multidrug
structure.
resistance and cross-resistance?
39. How does the biology of HIV necessitate the
43. How is the information from a Kirby-Bauer disk
need to treat HIV infections with multiple drugs?
diffusion test used for the recommendation of
40. Niclosamide is insoluble and thus is not readily the clinical use of an antimicrobial drug?
absorbed from the stomach into the
44. What is the difference between MIC and MBC?
bloodstream. How does the insolubility of

Critical Thinking
45. In nature, why do antimicrobial-producing
microbes commonly also have antimicrobial
resistance genes?

46. Why are yeast infections a common type of
superinfection that results from long-term use of
broad-spectrum antimicrobials?

47. Too often patients will stop taking antimicrobial
drugs before the prescription is finished. What
are factors that cause a patient to stop too soon,
and what negative impacts could this have?

48. In considering the cell structure of prokaryotes
compared with that of eukaryotes, propose one
possible reason for side effects in humans due
to treatment of bacterial infections with protein
synthesis inhibitors.

49. Which of the following molecules is an example of a
nucleoside analog? 50. Why can’t drugs used to treat influenza, like
amantadines and neuraminidase inhibitors, be
used to treat a wider variety of viral infections?

51. Can an Etest be used to find the MBC of a drug?
Explain.

52. Who should be responsible for discovering and
developing new antibiotics? Support your
answer with reasoning.

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CHAPTER 15
Microbial Mechanisms of Pathogenicity

FIGURE 15.1 Although medical professionals rely heavily on signs and symptoms to diagnose disease and prescribe treatment, many
diseases can produce similar signs and symptoms. (credit left: modification of work by U.S. Navy)

CHAPTER OUTLINE
15.1 Characteristics of Infectious Disease
15.2 How Pathogens Cause Disease
15.3 Virulence Factors of Bacterial and Viral Pathogens
15.4 Virulence Factors of Eukaryotic Pathogens

INTRODUCTION Jane woke up one spring morning feeling not quite herself. Her throat felt a bit dry and she was
sniffling. She wondered why she felt so lousy. Was it because of a change in the weather? The pollen count? Was she
coming down with something? Did she catch a bug from her coworker who sneezed on her in the elevator yesterday?

The signs and symptoms we associate with illness can have many different causes. Sometimes they are the direct
result of a pathogenic infection, but in other cases they result from a response by our immune system to a pathogen
or another perceived threat. For example, in response to certain pathogens, the immune system may release
pyrogens, chemicals that cause the body temperature to rise, resulting in a fever. This response creates a less-than-
favorable environment for the pathogen, but it also makes us feel sick.

Medical professionals rely heavily on analysis of signs and symptoms to determine the cause of an ailment and
prescribe treatment. In some cases, signs and symptoms alone are enough to correctly identify the causative agent
of a disease, but since few diseases produce truly unique symptoms, it is often necessary to confirm the identity of
the infectious agent by other direct and indirect diagnostic methods.

15.1 Characteristics of Infectious Disease
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Distinguish between signs and symptoms of disease
Explain the difference between a communicable disease and a noncommunicable disease
Compare different types of infectious diseases, including iatrogenic, nosocomial, and zoonotic diseases
Identify and describe the stages of an acute infectious disease in terms of number of pathogens present
and severity of signs and symptoms
592 15 Microbial Mechanisms of Pathogenicity

CLINICAL FOCUS
Part 1
Michael, a 10-year-old boy in generally good health, went to a birthday party on Sunday with his family. He ate
many different foods but was the only one in the family to eat the undercooked hot dogs served by the hosts.
Monday morning, he woke up feeling achy and nauseous, and he was running a fever of 38 °C (100.4 °F). His
parents, assuming Michael had caught the flu, made him stay home from school and limited his activities. But
after 4 days, Michael began to experience severe headaches, and his fever spiked to 40 °C (104 °F). Growing
worried, his parents finally decide to take Michael to a nearby clinic.

What signs and symptoms is Michael experiencing?
What do these signs and symptoms tell us about the stage of Michael’s disease?

Jump to the next Clinical Focus box.

A disease is any condition in which the normal structure or functions of the body are damaged or impaired. Physical
injuries or disabilities are not classified as disease, but there can be several causes for disease, including infection
by a pathogen, genetics (as in many cancers or deficiencies), noninfectious environmental causes, or inappropriate
immune responses. Our focus in this chapter will be on infectious diseases, although when diagnosing infectious
diseases, it is always important to consider possible noninfectious causes.

Signs and Symptoms of Disease
An infection is the successful colonization of a host by a microorganism. Infections can lead to disease, which
causes signs and symptoms resulting in a deviation from the normal structure or functioning of the host.
Microorganisms that can cause disease are known as pathogens.

The signs of disease are objective and measurable, and can be directly observed by a clinician. Vital signs, which are
used to measure the body’s basic functions, include body temperature (normally 37 °C [98.6 °F]), heart rate
(normally 60–100 beats per minute), breathing rate (normally 12–18 breaths per minute), and blood pressure
(normally between 90/60 and 120/80 mm Hg). Changes in any of the body’s vital signs may be indicative of disease.
For example, having a fever (a body temperature significantly higher than 37 °C or 98.6 °F) is a sign of disease
because it can be measured.

In addition to changes in vital signs, other observable conditions may be considered signs of disease. For example,
the presence of antibodies in a patient’s serum (the liquid portion of blood that lacks clotting factors) can be
observed and measured through blood tests and, therefore, can be considered a sign. However, it is important to
note that the presence of antibodies is not always a sign of an active disease. Antibodies can remain in the body long
after an infection has resolved; also, they may develop in response to a pathogen that is in the body but not
currently causing disease.

Unlike signs, symptoms of disease are subjective. Symptoms are felt or experienced by the patient, but they cannot
be clinically confirmed or objectively measured. Examples of symptoms include nausea, loss of appetite, and pain.
Such symptoms are important to consider when diagnosing disease, but they are subject to memory bias and are
difficult to measure precisely. Some clinicians attempt to quantify symptoms by asking patients to assign a
numerical value to their symptoms. For example, the Wong-Baker Faces pain-rating scale asks patients to rate their
pain on a scale of 0–10. An alternative method of quantifying pain is measuring skin conductance fluctuations.
1
These fluctuations reflect sweating due to skin sympathetic nerve activity resulting from the stressor of pain.

A specific group of signs and symptoms characteristic of a particular disease is called a syndrome. Many syndromes
are named using a nomenclature based on signs and symptoms or the location of the disease. Table 15.1 lists some
of the prefixes and suffixes commonly used in naming syndromes.

1 F. Savino et al. “Pain Assessment in Children Undergoing Venipuncture: The Wong–Baker Faces Scale Versus Skin Conductance
Fluctuations.” PeerJ 1 (2013):e37; https://peerj.com/articles/37/

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 15.1 Characteristics of Infectious Disease 593

Nomenclature of Symptoms

Affix Meaning Example

cyto- cell cytopenia: reduction in the number of blood cells

hepat- of the liver hepatitis: inflammation of the liver

-pathy disease neuropathy: a disease affecting nerves

-emia of the blood bacteremia: presence of bacteria in blood

-itis inflammation colitis: inflammation of the colon

-lysis destruction hemolysis: destruction of red blood cells

-oma tumor lymphoma: cancer of the lymphatic system

-osis diseased or abnormal condition leukocytosis: abnormally high number of white blood cells

-derma of the skin keratoderma: a thickening of the skin
TABLE 15.1

Clinicians must rely on signs and on asking questions about symptoms, medical history, and the patient’s recent
activities to identify a particular disease and the potential causative agent. Diagnosis is complicated by the fact that
different microorganisms can cause similar signs and symptoms in a patient. For example, an individual presenting
with symptoms of diarrhea may have been infected by one of a wide variety of pathogenic microorganisms. Bacterial
pathogens associated with diarrheal disease include Vibrio cholerae, Listeria monocytogenes, Campylobacter jejuni,
and enteropathogenic Escherichia coli (EPEC). Viral pathogens associated with diarrheal disease include norovirus
and rotavirus. Parasitic pathogens associated with diarrhea include Giardia lamblia and Cryptosporidium parvum.
Likewise, fever is indicative of many types of infection, from the common cold to the deadly Ebola hemorrhagic
fever.

Finally, some diseases may be asymptomatic or subclinical, meaning they do not present any noticeable signs or
symptoms. For example, most individual infected with herpes simplex virus remain asymptomatic and are unaware
that they have been infected.

CHECK YOUR UNDERSTANDING
Explain the difference between signs and symptoms.

Classifications of Disease
The World Health Organization’s (WHO) International Classification of Diseases (ICD) is used in clinical fields to
classify diseases and monitor morbidity (the number of cases of a disease) and mortality (the number of deaths due
to a disease). In this section, we will introduce terminology used by the ICD (and in health-care professions in
general) to describe and categorize various types of disease.

An infectious disease is any disease caused by the direct effect of a pathogen. A pathogen may be cellular
(bacteria, parasites, and fungi) or acellular (viruses, viroids, and prions). Some infectious diseases are also
communicable, meaning they are capable of being spread from person to person through either direct or indirect
mechanisms. Some infectious communicable diseases are also considered contagious diseases, meaning they are
easily spread from person to person. Not all contagious diseases are equally so; the degree to which a disease is
contagious usually depends on how the pathogen is transmitted. For example, measles is a highly contagious viral
594 15 Microbial Mechanisms of Pathogenicity

disease that can be transmitted when an infected person coughs or sneezes and an uninfected person breathes in
droplets containing the virus. Gonorrhea is not as contagious as measles because transmission of the pathogen
(Neisseria gonorrhoeae) requires close intimate contact (usually sexual) between an infected person and an
uninfected person.

Diseases that are contracted as the result of a medical procedure are known as iatrogenic diseases. Iatrogenic
diseases can occur after procedures involving wound treatments, catheterization, or surgery if the wound or surgical
site becomes contaminated. For example, an individual treated for a skin wound might acquire necrotizing fasciitis
(an aggressive, “flesh-eating” disease) if bandages or other dressings became contaminated by Clostridium
perfringens or one of several other bacteria that can cause this condition.

Diseases acquired in hospital settings are known as nosocomial diseases. Several factors contribute to the
prevalence and severity of nosocomial diseases. First, sick patients bring numerous pathogens into hospitals, and
some of these pathogens can be transmitted easily via improperly sterilized medical equipment, bed sheets, call
buttons, door handles, or by clinicians, nurses, or therapists who do not wash their hands before touching a patient.
Second, many hospital patients have weakened immune systems, making them more susceptible to infections.
Compounding this, the prevalence of antibiotics in hospital settings can select for drug-resistant bacteria that can
cause very serious infections that are difficult to treat.

Certain infectious diseases are not transmitted between humans directly but can be transmitted from animals to
humans. Such a disease is called zoonotic disease (or zoonosis). According to WHO, a zoonosis is a disease that
occurs when a pathogen is transferred from a vertebrate animal to a human; however, sometimes the term is
defined more broadly to include diseases transmitted by all animals (including invertebrates). For example, rabies is
a viral zoonotic disease spread from animals to humans through bites and contact with infected saliva. Many other
zoonotic diseases rely on insects or other arthropods for transmission. Examples include yellow fever (transmitted
through the bite of mosquitoes infected with yellow fever virus) and Rocky Mountain spotted fever (transmitted
through the bite of ticks infected with Rickettsia rickettsii).

In contrast to communicable infectious diseases, a noncommunicable infectious disease is not spread from one
person to another. One example is tetanus, caused by Clostridium tetani, a bacterium that produces endospores
that can survive in the soil for many years. This disease is typically only transmitted through contact with a skin
wound; it cannot be passed from an infected person to another person. Similarly, Legionnaires disease is caused by
Legionella pneumophila, a bacterium that lives within amoebae in moist locations like water-cooling towers. An
individual may contract Legionnaires disease via contact with the contaminated water, but once infected, the
individual cannot pass the pathogen to other individuals.

In addition to the wide variety of noncommunicable infectious diseases, noninfectious diseases (those not caused
by pathogens) are an important cause of morbidity and mortality worldwide. Noninfectious diseases can be caused
by a wide variety factors, including genetics, the environment, or immune system dysfunction, to name a few. For
example, sickle cell anemia is an inherited disease caused by a genetic mutation that can be passed from parent to
offspring (Figure 15.2). Other types of noninfectious diseases are listed in Table 15.2.

Types of Noninfectious Diseases

Type Definition Example

Inherited A genetic disease Sickle cell anemia

Congenital Disease that is present at or before birth Down syndrome

Degenerative Progressive, irreversible loss of function Parkinson disease (affecting central nervous
system)
TABLE 15.2

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 15.1 Characteristics of Infectious Disease 595

Types of Noninfectious Diseases

Type Definition Example

Nutritional Impaired body function due to lack of Scurvy (vitamin C deficiency)
deficiency nutrients

Endocrine Disease involving malfunction of glands Hypothyroidism – thyroid does not produce
that release hormones to regulate body enough thyroid hormone, which is important for
functions metabolism

Neoplastic Abnormal growth (benign or malignant) Some forms of cancer

Idiopathic Disease for which the cause is unknown Idiopathic juxtafoveal retinal telangiectasia
(dilated, twisted blood vessels in the retina of the
eye)
TABLE 15.2

FIGURE 15.2 Blood smears showing two diseases of the blood. (a) Malaria is an infectious, zoonotic disease caused by the protozoan
pathogen Plasmodium falciparum (shown here) and several other species of the genus Plasmodium. It is transmitted by mosquitoes to
humans. (b) Sickle cell disease is a noninfectious genetic disorder that results in abnormally shaped red blood cells, which can stick
together and obstruct the flow of blood through the circulatory system. It is not caused by a pathogen, but rather a genetic mutation. (credit
a: modification of work by Centers for Disease Control and Prevention; credit b: modification of work by Ed Uthman)

LINK TO LEARNING
Lists of common infectious diseases can be found at the following Centers for Disease Control and Prevention
(https://openstax.org/l/22CDCdis) (CDC), World Health Organization (https://openstax.org/l/22WHOdis) (WHO), and
International Classification of Diseases (https://openstax.org/l/22WHOclass) websites.

CHECK YOUR UNDERSTANDING
Describe how a disease can be infectious but not contagious.
Explain the difference between iatrogenic disease and nosocomial disease.

Periods of Disease
The five periods of disease (sometimes referred to as stages or phases) include the incubation, prodromal, illness,
decline, and convalescence periods (Figure 15.3). The incubation period occurs in an acute disease after the initial
596 15 Microbial Mechanisms of Pathogenicity

entry of the pathogen into the host (patient). It is during this time the pathogen begins multiplying in the host.
However, there are insufficient numbers of pathogen particles (cells or viruses) present to cause signs and
symptoms of disease. Incubation periods can vary from a day or two in acute disease to months or years in chronic
disease, depending upon the pathogen. Factors involved in determining the length of the incubation period are
diverse, and can include strength of the pathogen, strength of the host immune defenses, site of infection, type of
infection, and the size infectious dose received. During this incubation period, the patient is unaware that a disease
is beginning to develop.

FIGURE 15.3 The progression of an infectious disease can be divided into five periods, which are related to the number of pathogen
particles (red) and the severity of signs and symptoms (blue).

The prodromal period occurs after the incubation period. During this phase, the pathogen continues to multiply and
the host begins to experience general signs and symptoms of illness, which typically result from activation of the
immune system, such as fever, pain, soreness, swelling, or inflammation. Usually, such signs and symptoms are too
general to indicate a particular disease. Following the prodromal period is the period of illness, during which the
signs and symptoms of disease are most obvious and severe.

The period of illness is followed by the period of decline, during which the number of pathogen particles begins to
decrease, and the signs and symptoms of illness begin to decline. However, during the decline period, patients may
become susceptible to developing secondary infections because their immune systems have been weakened by the
primary infection. The final period is known as the period of convalescence. During this stage, the patient generally
returns to normal functions, although some diseases may inflict permanent damage that the body cannot fully
repair.

Infectious diseases can be contagious during all five of the periods of disease. Which periods of disease are more
likely to associated with transmissibility of an infection depends upon the disease, the pathogen, and the
mechanisms by which the disease develops and progresses. For example, with meningitis (infection of the lining of
brain), the periods of infectivity depend on the type of pathogen causing the infection. Patients with bacterial
meningitis are contagious during the incubation period for up to a week before the onset of the prodromal period,
whereas patients with viral meningitis become contagious when the first signs and symptoms of the prodromal
period appear. With many viral diseases associated with rashes (e.g., chickenpox, measles, rubella, roseola),
patients are contagious during the incubation period up to a week before the rash develops. In contrast, with many
respiratory infections (e.g., colds, influenza, diphtheria, strep throat, and pertussis) the patient becomes contagious
with the onset of the prodromal period. Depending upon the pathogen, the disease, and the individual infected,

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 15.2 How Pathogens Cause Disease 597

transmission can still occur during the periods of decline, convalescence, and even long after signs and symptoms of
the disease disappear. For example, an individual recovering from a diarrheal disease may continue to carry and
shed the pathogen in feces for some time, posing a risk of transmission to others through direct contact or indirect
contact (e.g., through contaminated objects or food).

CHECK YOUR UNDERSTANDING
Name some of the factors that can affect the length of the incubation period of a particular disease.

Acute and Chronic Diseases
The duration of the period of illness can vary greatly, depending on the pathogen, effectiveness of the immune
response in the host, and any medical treatment received. For an acute disease, pathologic changes occur over a
relatively short time (e.g., hours, days, or a few weeks) and involve a rapid onset of disease conditions. For example,
influenza (caused by Influenzavirus) is considered an acute disease because the incubation period is approximately
1–2 days. Infected individuals can spread influenza to others for approximately 5 days after becoming ill. After
approximately 1 week, individuals enter the period of decline.

For a chronic disease, pathologic changes can occur over longer time spans (e.g., months, years, or a lifetime). For
example, chronic gastritis (inflammation of the lining of the stomach) is caused by the gram-negative bacterium
Helicobacter pylori. H. pylori is able to colonize the stomach and persist in its highly acidic environment by
2
producing the enzyme urease, which modifies the local acidity, allowing the bacteria to survive indefinitely.
3
Consequently, H. pylori infections can recur indefinitely unless the infection is cleared using antibiotics. Hepatitis B
virus can cause a chronic infection in some patients who do not eliminate the virus after the acute illness. A chronic
infection with hepatitis B virus is characterized by the continued production of infectious virus for 6 months or
longer after the acute infection, as measured by the presence of viral antigen in blood samples.

In latent diseases, as opposed to chronic infections, the causal pathogen goes dormant for extended periods of
time with no active replication. Examples of diseases that go into a latent state after the acute infection include
herpes (herpes simplex viruses [HSV-1 and HSV-2]), chickenpox (varicella-zoster virus [VZV]), and mononucleosis
(Epstein-Barr virus [EBV]). HSV-1, HSV-2, and VZV evade the host immune system by residing in a latent form within
cells of the nervous system for long periods of time, but they can reactivate to become active infections during times
of stress and immunosuppression. For example, an initial infection by VZV may result in a case of childhood
chickenpox, followed by a long period of latency. The virus may reactivate decades later, causing episodes of
shingles in adulthood. EBV goes into latency in B cells of the immune system and possibly epithelial cells; it can
reactivate years later to produce B-cell lymphoma.

CHECK YOUR UNDERSTANDING
Explain the difference between latent disease and chronic disease.

15.2 How Pathogens Cause Disease
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Summarize Koch’s postulates and molecular Koch’s postulates, respectively, and explain their
significance and limitations
Explain the concept of pathogenicity (virulence) in terms of infectious and lethal dose
Distinguish between primary and opportunistic pathogens and identify specific examples of each
Summarize the stages of pathogenesis
Explain the roles of portals of entry and exit in the transmission of disease and identify specific examples
of these portals

2 J.G. Kusters et al. Pathogenesis of Helicobacter pylori Infection. Clinical Microbiology Reviews 19 no. 3 (2006):449–490.
3 N.R. Salama et al. “Life in the Human Stomach: Persistence Strategies of the Bacterial Pathogen Helicobacter pylori.” Nature Reviews
Microbiology 11 (2013):385–399.
598 15 Microbial Mechanisms of Pathogenicity

For most infectious diseases, the ability to accurately identify the causative pathogen is a critical step in finding or
prescribing effective treatments. Today’s physicians, patients, and researchers owe a sizable debt to the physician
Robert Koch (1843–1910), who devised a systematic approach for confirming causative relationships between
diseases and specific pathogens.

Koch’s Postulates
In 1884, Koch published four postulates (Table 15.3) that summarized his method for determining whether a
particular microorganism was the cause of a particular disease. Each of Koch’s postulates represents a criterion that
must be met before a disease can be positively linked with a pathogen. In order to determine whether the criteria
are met, tests are performed on laboratory animals and cultures from healthy and diseased animals are compared
(Figure 15.4).

Koch’s Postulates

(1) The suspected pathogen must be found in every case of disease and not be found in healthy individuals.

(2) The suspected pathogen can be isolated and grown in pure culture.

(3) A healthy test subject infected with the suspected pathogen must develop the same signs and symptoms of
disease as seen in postulate 1.

(4) The pathogen must be re-isolated from the new host and must be identical to the pathogen from postulate 2.
TABLE 15.3

FIGURE 15.4 The steps for confirming that a pathogen is the cause of a particular disease using Koch’s postulates.

In many ways, Koch’s postulates are still central to our current understanding of the causes of disease. However,

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 15.2 How Pathogens Cause Disease 599

advances in microbiology have revealed some important limitations in Koch’s criteria. Koch made several
assumptions that we now know are untrue in many cases. The first relates to postulate 1, which assumes that
pathogens are only found in diseased, not healthy, individuals. This is not true for many pathogens. For example, H.
pylori, described earlier in this chapter as a pathogen causing chronic gastritis, is also part of the normal microbiota
of the stomach in many healthy humans who never develop gastritis. It is estimated that upwards of 50% of the
human population acquires H. pylori early in life, with most maintaining it as part of the normal microbiota for the
rest of their life without ever developing disease. Similarly, when Alice Katherine Evans discovered that Brucellis
bacteria found in cows was responsible for a common human disease, she noted that the infected cattle could pass
on the infection whether or not they displayed symptoms. This is an important distinction: Even without knowledge
of microbiology, many people would not consume milk from a visibly sick cow, but the concept of a healthy cow
being infectious is critical to understanding the risks posed by pathogens.

Koch’s second faulty assumption was that all healthy test subjects are equally susceptible to disease. We now know
that individuals are not equally susceptible to disease. Individuals are unique in terms of their microbiota and the
state of their immune system at any given time. The makeup of the resident microbiota can influence an individual’s
susceptibility to an infection. Members of the normal microbiota play an important role in immunity by inhibiting the
growth of transient pathogens. In some cases, the microbiota may prevent a pathogen from establishing an
infection; in others, it may not prevent an infection altogether but may influence the severity or type of signs and
symptoms. As a result, two individuals with the same disease may not always present with the same signs and
symptoms. In addition, some individuals have stronger immune systems than others. Individuals with immune
systems weakened by age or an unrelated illness are much more susceptible to certain infections than individuals
with strong immune systems.

Koch also assumed that all pathogens are microorganisms that can be grown in pure culture (postulate 2) and that
animals could serve as reliable models for human disease. However, we now know that not all pathogens can be
grown in pure culture, and many human diseases cannot be reliably replicated in animal hosts. Viruses and certain
bacteria, including Rickettsia and Chlamydia, are obligate intracellular pathogens that can grow only when inside a
host cell. If a microbe cannot be cultured, a researcher cannot move past postulate 2. Likewise, without a suitable
nonhuman host, a researcher cannot evaluate postulate 3 without deliberately infecting humans, which presents
obvious ethical concerns. AIDS is an example of such a disease because the human immunodeficiency virus (HIV)
only causes disease in humans.

CHECK YOUR UNDERSTANDING
Briefly summarize the limitations of Koch’s postulates.

Molecular Koch’s Postulates
In 1988, Stanley Falkow (1934–) proposed a revised form of Koch’s postulates known as molecular Koch’s
postulates. These are listed in the left column of Table 15.4. The premise for molecular Koch’s postulates is not in
the ability to isolate a particular pathogen but rather to identify a gene that may cause the organism to be
pathogenic.

Falkow’s modifications to Koch’s original postulates explain not only infections caused by intracellular pathogens
but also the existence of pathogenic strains of organisms that are usually nonpathogenic. For example, the
predominant form of the bacterium Escherichia coli is a member of the normal microbiota of the human intestine
and is generally considered harmless. However, there are pathogenic strains of E. coli such as enterotoxigenic E. coli
(ETEC) and enterohemorrhagic E. coli (O157:H7) (EHEC). We now know ETEC and EHEC exist because of the
acquisition of new genes by the once-harmless E. coli, which, in the form of these pathogenic strains, is now capable
of producing toxins and causing illness. The pathogenic forms resulted from minor genetic changes. The right-side
column of Table 15.4 illustrates how molecular Koch’s postulates can be applied to identify EHEC as a pathogenic
bacterium.
600 15 Microbial Mechanisms of Pathogenicity

Molecular Koch’s Postulates Applied to EHEC

Molecular Koch’s Postulates Application to EHEC

(1) The phenotype (sign or symptom of EHEC causes intestinal inflammation and diarrhea, whereas
disease) should be associated only with nonpathogenic strains of E. coli do not.
pathogenic strains of a species.

(2) Inactivation of the suspected gene(s) One of the genes in EHEC encodes for Shiga toxin, a bacterial
associated with pathogenicity should result toxin (poison) that inhibits protein synthesis. Inactivating this
in a measurable loss of pathogenicity. gene reduces the bacteria’s ability to cause disease.

(3) Reversion of the inactive gene should By adding the gene that encodes the toxin back into the genome
restore the disease phenotype. (e.g., with a phage or plasmid), EHEC’s ability to cause disease is
restored.
TABLE 15.4

As with Koch’s original postulates, the molecular Koch’s postulates have limitations. For example, genetic
manipulation of some pathogens is not possible using current methods of molecular genetics. In a similar vein,
some diseases do not have suitable animal models, which limits the utility of both the original and molecular
postulates.

CHECK YOUR UNDERSTANDING
Explain the differences between Koch’s original postulates and the molecular Koch’s postulates.

Pathogenicity and Virulence
The ability of a microbial agent to cause disease is called pathogenicity, and the degree to which an organism is
pathogenic is called virulence. Virulence is a continuum. On one end of the spectrum are organisms that are
avirulent (not harmful) and on the other are organisms that are highly virulent. Highly virulent pathogens will almost
always lead to a disease state when introduced to the body, and some may even cause multi-organ and body system
failure in healthy individuals. Less virulent pathogens may cause an initial infection, but may not always cause
severe illness. Pathogens with low virulence would more likely result in mild signs and symptoms of disease, such as
low-grade fever, headache, or muscle aches. Some individuals might even be asymptomatic.

An example of a highly virulent microorganism is Bacillus anthracis, the pathogen responsible for anthrax. B.
anthracis can produce different forms of disease, depending on the route of transmission (e.g., cutaneous injection,
inhalation, ingestion). The most serious form of anthrax is inhalation anthrax. After B. anthracis spores are inhaled,
they germinate. An active infection develops and the bacteria release potent toxins that cause edema (fluid buildup
in tissues), hypoxia (a condition preventing oxygen from reaching tissues), and necrosis (cell death and
inflammation). Signs and symptoms of inhalation anthrax include high fever, difficulty breathing, vomiting and
coughing up blood, and severe chest pains suggestive of a heart attack. With inhalation anthrax, the toxins and
bacteria enter the bloodstream, which can lead to multi-organ failure and death of the patient. If a gene (or genes)
involved in pathogenesis is inactivated, the bacteria become less virulent or nonpathogenic.

Virulence of a pathogen can be quantified using controlled experiments with laboratory animals. Two important
indicators of virulence are the median infectious dose (ID50) and the median lethal dose (LD50), both of which are
typically determined experimentally using animal models. The ID50 is the number of pathogen cells or virions
required to cause active infection in 50% of inoculated animals. The LD50 is the number of pathogenic cells, virions,
or amount of toxin required to kill 50% of infected animals. To calculate these values, each group of animals is
inoculated with one of a range of known numbers of pathogen cells or virions. In graphs like the one shown in Figure
15.5, the percentage of animals that have been infected (for ID50) or killed (for LD50) is plotted against the
concentration of pathogen inoculated. Figure 15.5 represents data graphed from a hypothetical experiment

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 15.2 How Pathogens Cause Disease 601

measuring the LD50 of a pathogen. Interpretation of the data from this graph indicates that the LD50 of the pathogen
for the test animals is 104 pathogen cells or virions (depending upon the pathogen studied).

FIGURE 15.5 A graph like this is used to determine LD50 by plotting pathogen concentration against the percent of infected test animals
that have died. In this example, the LD50 = 104 pathogenic particles.

Table 15.5 lists selected foodborne pathogens and their ID50 values in humans (as determined from epidemiologic
data and studies on human volunteers). Keep in mind that these are median values. The actual infective dose for an
individual can vary widely, depending on factors such as route of entry; the age, health, and immune status of the
host; and environmental and pathogen-specific factors such as susceptibility to the acidic pH of the stomach. It is
also important to note that a pathogen’s infective dose does not necessarily correlate with disease severity. For
example, just a single cell of Salmonella enterica serotype Typhimurium can result in an active infection. The
resultant disease, Salmonella gastroenteritis or salmonellosis, can cause nausea, vomiting, and diarrhea, but has a
mortality rate of less than 1% in healthy adults. In contrast, S. enterica serotype Typhi has a much higher ID50,
typically requiring as many as 1,000 cells to produce infection. However, this serotype causes typhoid fever, a much
more systemic and severe disease that has a mortality rate as high as 10% in untreated individuals.

4
ID50 for Selected Foodborne Diseases

Pathogen ID50

Viruses

Hepatitis A virus 10–100

Norovirus 1–10

Rotavirus 10–100

Bacteria

Escherichia coli, enterohemorrhagic (EHEC, serotype O157) 10–100

E. coli, enteroinvasive (EIEC) 200–5,000
TABLE 15.5
602 15 Microbial Mechanisms of Pathogenicity

4
ID50 for Selected Foodborne Diseases

Pathogen ID50

E. coli, enteropathogenic (EPEC) 10,000,000–10,000,000,000

E. coli, enterotoxigenic (ETEC) 10,000,000–10,000,000,000

Salmonella enterica serovar Typhi