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Chapter 1: The Science of Microbiology

INTRODUCTION
Microbiology is the study of microorganisms, a large and diverse group of microscopic organisms that exist as single cells or cell clusters; it also
includes viruses, which are microscopic but not cellular. Microorganisms have a tremendous impact on all life and the physical and chemical makeup
of our planet. They are responsible for cycling the chemical elements essential for life, including carbon, nitrogen, sulfur, hydrogen, and oxygen; more
photosynthesis is carried out by microorganisms than by green plants. Furthermore, there are 100 million times as many bacteria in the oceans (13 ×
1028) as there are stars in the known universe. The rate of viral infections in the oceans is about 1 × 1023 infections per second, and these infections
remove 20–40% of all bacterial cells each day. It has been estimated that 5 × 1030 microbial cells exist on earth; excluding cellulose, these cells
constitute about 90% of the biomass of the entire biosphere. Humans also have an intimate relationship with microorganisms; 50–60% of the cells in
our bodies are microbes (see Chapter 10). The bacteria present in the average human gut weigh about 1 kg, and a human adult will excrete his or her
own weight in fecal bacteria each year. The number of genes contained within this gut flora outnumber that contained within our genome by 150­fold;
even in our own genome, 8% of the DNA is derived from remnants of viral genomes.

BIOLOGIC PRINCIPLES ILLUSTRATED BY MICROBIOLOGY
Nowhere is biologic diversity demonstrated more dramatically than by microorganisms, cells, or viruses that are not directly visible to the unaided
eye. In form and function, be it biochemical property or genetic mechanism, analysis of microorganisms takes us to the limits of biologic
understanding. Thus, the need for originality—one test of the merit of a scientific hypothesis—can be fully met in microbiology. A useful hypothesis
should provide a basis for generalization, and microbial diversity provides an arena in which this challenge is ever present.

Prediction, the practical outgrowth of science, is a product created by a blend of technique and theory. Biochemistry, molecular biology, and
genetics provide the tools required for analysis of microorganisms. Microbiology, in turn, extends the horizons of these scientific disciplines. A
biologist might describe such an exchange as mutualism, that is, one that benefits all contributing parties. Lichens are an example of microbial
mutualism. Lichens consist of a fungus and phototropic partner, either an alga (a eukaryote) or a cyanobacterium (a prokaryote) (Figure 1­1). The
phototropic component is the primary producer, and the fungus provides the phototroph with an anchor and protection from the elements. In
biology, mutualism is called symbiosis, a continuing association of different organisms. If the exchange operates primarily to the benefit of one party,
the association is described as parasitism, a relationship in which a host provides the primary benefit to the parasite. Isolation and characterization
of a parasite—such as a pathogenic bacterium or virus—often require effective mimicry in the laboratory of the growth environment provided by host
cells. This demand sometimes represents a major challenge to investigators.

FIGURE 1­1

Diagram of a lichen, consisting of cells of a phototroph, either an alga or a cyanobacterium, entwined within the hyphae of the fungal partner.
(Reproduced with permission from Nester EW, Anderson DG, Roberts CE, et al: Microbiology: A Human Perspective, 6th ed. McGraw­Hill, 2009, p. 293. ©
McGraw­Hill Education.)

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FIGURE 1­1

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Diagram of a lichen, consisting of cells of a phototroph, either an alga or a cyanobacterium, entwined within the hyphae of the fungal partner.
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(Reproduced with permission from Nester EW, Anderson DG, Roberts CE, et al: Microbiology: A Human Perspective, 6th ed. McGraw­Hill, 2009, p. 293. ©
McGraw­Hill Education.)

The terms mutualism, symbiosis, and parasitism relate to the science of ecology, and the principles of environmental biology are implicit in
microbiology. Microorganisms are the products of evolution, the biologic consequence of natural selection operating on a vast array of genetically
diverse organisms. It is useful to keep the complexity of natural history in mind before generalizing about microorganisms, the most heterogeneous
subset of all living creatures.

A major biologic division separates the eukaryotes, organisms containing a membrane­bound nucleus from prokaryotes, organisms in which DNA is
not physically separated from the cytoplasm. As described in this chapter and in Chapter 2, further major distinctions can be made between eukaryotes
and prokaryotes. Eukaryotes, for example, are distinguished by their relatively large size and by the presence of specialized membrane­bound
organelles such as mitochondria.

As described more fully later in this chapter, eukaryotic microorganisms—or, phylogenetically speaking, the Eukarya—are unified by their distinct cell
structure and phylogenetic history. Among the groups of eukaryotic microorganisms are the algae, the protozoa, the fungi, and the slime molds. A
class of microorganisms that share characteristics common to both prokaryotes and eukaryotes are the archaebacteria and are described in Chapter 3.

VIRUSES
The unique properties of viruses set them apart from living creatures. Viruses lack many of the attributes of cells, including the ability to self­replicate.
Only when it infects a cell does a virus acquire the key attribute of a living system—reproduction. Viruses are known to infect a wide variety of plant and
animal hosts as well as protists, fungi, and bacteria. However, most viruses are restricted to infecting specific types of cells of only one host species, a
property known as “tropism”. Recently, viruses called virophages have been discovered that infect other viruses. Host–virus interactions tend to be
highly specific, and the biologic range of viruses mirrors the diversity of potential host cells. Further diversity of viruses is exhibited by their broad array
of strategies for replication and survival.

Viral particles are generally small (eg, adenovirus has a diameter of 90 nm) and consist of a nucleic acid molecule, either DNA or RNA, enclosed in a
protein coat, or capsid (sometimes itself surrounded by an envelope of lipids, proteins, and carbohydrates). Proteins—frequently glycoproteins—
comprising the capsid and/or making up part of the lipid envelope (e.g., HIV gp120) determine the specificity of interaction of a virus with its host cell.
The capsid protects the nucleic acid cargo. The surface proteins, whether they are externally exposed on the capsid or associated with the envelope
facilitates attachment and penetration of the host cell by the virus. Once inside the cell, viral nucleic acid redirects the host’s enzymatic machinery to
functions associated with replication and assembly of the virus. In some cases, genetic information from the virus can be incorporated as DNA into a
host chromosome (a provirus). In other instances, the viral genetic information can serve as a basis for cellular manufacture and release of copies of
the virus. This process calls for replication of the viral nucleic acid and production of specific viral proteins. Maturation consists of assembling newly
synthesized nucleic acid and protein subunits into mature viral particles, which are then liberated into the extracellular environment. Some very small
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transmission.

Some viruses are large and complex. For example, Mimivirus, a DNA virus infecting Acanthamoeba, a free­living soil ameba, has a diameter of 400–500
facilitates attachment and penetration of the host cell by the virus. Once inside the cell, viral nucleic acid redirects the host’s enzymatic machinery to
functions associated with replication and assembly of the virus. In some cases, genetic information from the virus can be incorporated Naresuan
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host chromosome (a provirus). In other instances, the viral genetic information can serve as a basis for cellular manufacture and release of copies of
the virus. This process calls for replication of the viral nucleic acid and production of specific viral proteins. Maturation consists of assembling newly
synthesized nucleic acid and protein subunits into mature viral particles, which are then liberated into the extracellular environment. Some very small
viruses require the assistance of another virus in the host cell for their replication. The delta agent, also known as hepatitis D virus (HDV), has a RNA
genome that is too small to code for even a single capsid protein (the only HDV­encoded protein is delta antigen) and needs help from hepatitis B virus
for packaging and transmission.

Some viruses are large and complex. For example, Mimivirus, a DNA virus infecting Acanthamoeba, a free­living soil ameba, has a diameter of 400–500
nm and a genome that encodes 979 proteins, including the first four aminoacyl tRNA synthetases ever found outside of cellular organisms. This virus
also encodes enzymes for polysaccharide biosynthesis, a process typically performed by the infected cell. An even larger marine virus has recently
been discovered (Megavirus); its genome (1,259,197­bp) encodes 1120 putative proteins and is larger than that of some bacteria (see Table 7­1).
Because of their large size, these viruses resemble bacteria when observed in stained preparations by light microscopy; however, they do not undergo
cell division or contain ribosomes.

Several transmissible plant diseases are caused by viroids—small, single­stranded, covalently closed circular RNA molecules existing as highly base­
paired rod­like structures. They range in size from 246 to 375 nucleotides in length. The extracellular form of the viroid is naked RNA—there is no
capsid of any kind. The RNA molecule contains no protein­encoding genes, and the viroid is therefore totally dependent on host functions for its
replication. Viroid RNA is replicated by the DNA­dependent RNA polymerase of the plant host; preemption of this enzyme may contribute to viroid
pathogenicity.

The RNAs of viroids have been shown to contain inverted repeated base sequences (also known as insertion sequences) at their 3′ and 5′ ends, a
characteristic of transposable elements (see Chapter 7) and retroviruses. Thus, it is likely that they have evolved from transposable elements or
retroviruses by the deletion of internal sequences.

The general properties of animal viruses pathogenic for humans are described in Chapter 29. Bacterial viruses, known as bacterial phages, are
described in Chapter 7.

PRIONS
A number of remarkable discoveries in the past three decades have led to the molecular and genetic characterization of the transmissible agent
causing scrapie, a degenerative central nervous system disease of sheep. Studies have identified a specific protein in preparations from scrapie­
infected brains of sheep that can reproduce the symptoms of scrapie in previously uninfected sheep (Figure 1­2). Attempts to identify additional
components, such as nucleic acid, have been unsuccessful. To distinguish this agent from viruses and viroids, the term prion was introduced to
emphasize its proteinaceous and infectious nature. The protein that prions are made of (PrP) is found throughout the body, even in healthy people
and in animals, and is encoded by the host’s chromosomal DNA. The normal form of the prion protein is called PrPc. PrPc is a sialoglycoprotein with a
molecular mass of 35,000–36,000 Da and a mainly α­helical secondary structure that is sensitive to proteases and soluble in detergent. Several
topological forms exist: one cell surface form anchored by a glycolipid, and two transmembrane forms. The disease scrapie manifests itself when a
conformational change occurs in the prion protein, changing it from its normal or cellular form PrPc to the infectious disease­causing isoform, PrPSc
(Figure 1­3); this in turn alters the way the proteins interconnect. The exact three­dimensional structure of PrPSc is unknown; however, it has a higher
proportion of β­sheet structures in place of the normal α­helix structures. Aggregations of PrPSc form highly structured amyloid fibers, which
accumulate to form plaques. It is unclear if these aggregates are the cause of the cell damage or are simply a side effect of the underlying disease
process. One model of prion replication suggests that PrPc exists only as fibrils, and that the fibril ends bind PrPc and convert it to PrPSc.

FIGURE 1­2

Prion. Prions isolated from the brain of a scrapie­infected hamster. This neurodegenerative disease is caused by a prion. (Reproduced with permission
from Stanley B. Prusiner.)

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FIGURE 1­2
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Prion. Prions isolated from the brain of a scrapie­infected hamster. This neurodegenerative disease is caused by a prion. (Reproduced with permission
from Stanley B. Prusiner.)

FIGURE 1­3

Proposed mechanism by which prions replicate. The normal and abnormal prion proteins differ in their tertiary structure. (Reproduced with
permission from Nester EW, Anderson DG, Roberts CE, et al: Microbiology: A Human Perspective, 6th ed. McGraw­Hill, 2009, p. 342. © McGraw­Hill
Education.)

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FIGURE 1­3

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Proposed mechanism by which prions replicate. The normal and abnormal prion proteins differ in their tertiary structure. (Reproduced with
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permission from Nester EW, Anderson DG, Roberts CE, et al: Microbiology: A Human Perspective, 6th ed. McGraw­Hill, 2009, p. 342. © McGraw­Hill
Education.)

There are several prion diseases of importance (Table 1­1 and see Chapter 42). Kuru, Creutzfeldt­Jakob disease (CJD), Gerstmann­Sträussler­
Scheinker disease, and fatal familial insomnia affect humans. Bovine spongiform encephalopathy (BSE), which is thought to result from the ingestion
of feeds and bone meal prepared from rendered sheep offal, has been responsible for the deaths of more than 184,000 cattle in Great Britain since its
discovery in 1985. A new variant of CJD (vCJD) has been associated with human ingestion of prion­infected beef in the United Kingdom and in France. A
common feature of all of these diseases is the conversion of a host­encoded sialoglycoprotein to a protease­resistant form as a consequence of
infection. Recently, an α­synuclein prion was discovered that caused a neurodegenerative disease called multiple system atrophy in humans.

TABLE 1­1
Common Human and Animal Prion Diseases

Type Name Etiology

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Acquired Variant Creutzfeldt­Jakob diseasea Associated with ingestion or inoculation of prion­infected material
of feeds and bone meal prepared from rendered sheep offal, has been responsible for the deaths of more than 184,000 cattle in Great Britain since its
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discovery in 1985. A new variant of CJD (vCJD) has been associated with human ingestion of prion­infected beef in the United Kingdom and in France. A
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common feature of all of these diseases is the conversion of a host­encoded sialoglycoprotein to a protease­resistant form as a consequence of
infection. Recently, an α­synuclein prion was discovered that caused a neurodegenerative disease called multiple system atrophy in humans.

TABLE 1­1
Common Human and Animal Prion Diseases

Type Name Etiology

Human prion diseases

Acquired Variant Creutzfeldt­Jakob diseasea Associated with ingestion or inoculation of prion­infected material

Kuru

Iatrogenic Creutzfeldt­Jakob diseaseb

Sporadic Creutzfeldt­Jakob disease Source of infection unknown

Familial Gerstmann­Sträussler­Scheinker Associated with specific mutations within the gene encoding PrP

Fatal familial insomnia

Creutzfeldt­Jakob disease

Animal prion diseases

Cattle Bovine spongiform encephalopathy Exposure to prion­contaminated meat and bone meal

Sheep Scrapie Ingestion of scrapie­contaminated material

Deer, elk Chronic wasting disease Ingestion of prion­contaminated material

Mink Transmissible mink encephalopathy Source of infection unknown

Cats Feline spongiform encephalopathya Exposure to prion­contaminated meat and bone meal

PrP, prion protein.

aAssociated with exposure to bovine spongiform encephalopathy­contaminated materials.

b Associated with prion­contaminated biologic materials, such as dura mater grafts, corneal transplants, and cadaver­derived human growth hormone, or by prion­

contaminated surgical instruments.

Reproduced with permission from the American Society for Microbiology. Priola SA: How animal prions cause disease in humans. Microbe 2008;3(12):568.

Human prion diseases are unique in that they manifest as sporadic, genetic, and infectious diseases. The study of prion biology is an important
emerging area of biomedical investigation, and much remains to be learned.

The general features of the nonliving members of the microbial world are given in Table 1­2.

TABLE 1­2
Distinguishing Characteristics of Viruses, Viroids, and Prions

Viruses Viroids Prions
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Consist of either DNA or RNA surrounded by a protein coat Consist only of RNA; no protein coat Consist only of protein; no DNA or RNA
Human prion diseases are unique in that they manifest as sporadic, genetic, and infectious diseases. The study of prion biology is an important
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The general features of the nonliving members of the microbial world are given in Table 1­2.

TABLE 1­2
Distinguishing Characteristics of Viruses, Viroids, and Prions

Viruses Viroids Prions

Obligate intracellular agents Obligate intracellular agents Abnormal form of a cellular protein

Consist of either DNA or RNA surrounded by a protein coat Consist only of RNA; no protein coat Consist only of protein; no DNA or RNA

Reproduced with permission from Nester EW, Anderson DG, Roberts CE, et al: Microbiology: A Human Perspective, 6th ed. McGraw­Hill, 2009, p. 13. © McGraw­Hill
Education.

PROKARYOTES
The primary distinguishing characteristics of the prokaryotes are their relatively small size, usually on the order of 1 µm in diameter, and the absence
of a nuclear membrane. The DNA of almost all bacteria is a circle which if extended linearly would be about 1 mM; this is the prokaryotic chromosome.
Bacteria are haploid (if multiple copies of the chromosome are present they are all the same). Most prokaryotes have only a single large chromosome
that is organized into a structure known as a nucleoid. The chromosomal DNA must be folded more than 1000­fold just to fit within the confines of a
prokaryotic cell. Substantial evidence suggests that the folding may be orderly and may bring specified regions of the DNA into proximity. The
nucleoid can be visualized by electron microscopy as well as by light microscopy after treatment of the cell to make the nucleoid visible. Thus, it would
be a mistake to conclude that subcellular differentiation, clearly demarcated by membranes in eukaryotes, is lacking in prokaryotes. Indeed, some
prokaryotes form membrane­bound subcellular structures with specialized function such as the chromatophores of photosynthetic bacteria (see
Chapter 2).

Prokaryotic Diversity

The small size and haploid organization of the prokaryotic chromosome limits the amount of genetic information it can contain. Recent data based on
genome sequencing indicate that the number of genes within a prokaryote may vary from 468 in Mycoplasma genitalium to 7825 in Streptomyces
coelicolor, and many of these genes must be dedicated to essential functions such as energy generation, macromolecular synthesis, and cellular
replication. Any one prokaryote carries relatively few genes that allow physiologic accommodation of the organism to its environment. The range of
potential prokaryotic environments is unimaginably broad, and it follows that the prokaryotic group encompasses a heterogeneous range of
specialists, each adapted to a rather narrowly circumscribed niche.

The range of prokaryotic niches is illustrated by consideration of strategies used for generation of metabolic energy. Light from the sun is the chief
source of energy for life. Some prokaryotes such as the purple bacteria convert light energy to metabolic energy in the absence of oxygen production.
Other prokaryotes, exemplified by the blue­green bacteria (Cyanobacteria), produce oxygen that can provide energy through respiration in the
absence of light. Aerobic organisms depend on respiration with oxygen for their energy. Some anaerobic organisms can use electron acceptors
other than oxygen in respiration. Many anaerobes carry out fermentations in which energy is derived by metabolic rearrangement of chemical
growth substrates. The tremendous chemical range of potential growth substrates for aerobic or anaerobic growth is mirrored in the diversity of
prokaryotes that have adapted to their utilization.

Prokaryotic Communities

A useful survival strategy for specialists is to enter into consortia, arrangements in which the physiologic characteristics of different organisms
contribute to survival of the group as a whole. If the organisms within a physically interconnected community are directly derived from a single cell, the
community is a clone that may contain up to 108 or greater cells. The biology of such a community differs substantially from that of a single cell. For
example, the high cell number virtually ensures the presence within the clone of at least one cell carrying a variant of any gene on the chromosome.
Thus, genetic variability—the wellspring of the evolutionary process called natural selection—is ensured within a clone. The high number of cells
within clones is also likely to provide physiologic protection to at least some members of the group. Extracellular polysaccharides, for example, may
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Chapter 1: The Science of Microbiology, Page 7 / 13
number of cells within a clone may allow cells within the interior to survive exposure to a lethal agent at a concentration that might kill single cells.
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Many bacteria exploit a cell–cell communication mechanism called quorum sensing to regulate the transcription of genes involved in diverse
physiologic processes, including bioluminescence, plasmid conjugal transfer, and the production of virulence determinants. Quorum sensing
A useful survival strategy for specialists is to enter into consortia, arrangements in which the physiologic characteristics of different organisms
contribute to survival of the group as a whole. If the organisms within a physically interconnected community are directly derived fromNaresuan
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example, the high cell number virtually ensures the presence within the clone of at least one cell carrying a variant of any gene on the chromosome.
Thus, genetic variability—the wellspring of the evolutionary process called natural selection—is ensured within a clone. The high number of cells
within clones is also likely to provide physiologic protection to at least some members of the group. Extracellular polysaccharides, for example, may
afford protection against potentially lethal agents such as antibiotics or heavy metal ions. Large amounts of polysaccharides produced by the high
number of cells within a clone may allow cells within the interior to survive exposure to a lethal agent at a concentration that might kill single cells.

Many bacteria exploit a cell–cell communication mechanism called quorum sensing to regulate the transcription of genes involved in diverse
physiologic processes, including bioluminescence, plasmid conjugal transfer, and the production of virulence determinants. Quorum sensing
depends on the production of one or more diffusible signal molecules (eg, acetylated homoserine lactone [AHL]) termed autoinducers or
pheromones that enable a bacterium to monitor its own cell population density (Figure 1­4). The cooperative activities leading to biofilm formation
are controlled by quorum sensing. It is an example of multicellular behavior in prokaryotes.

FIGURE 1­4

Quorum sensing. (Reproduced with permission from Nester EW, Anderson DG, Roberts CE, et al: Microbiology: A Human Perspective, 6th ed. McGraw­
Hill, 2009, p. 181. © McGraw­Hill Education.)

Another distinguishing characteristic of prokaryotes is their capacity to exchange small packets of genetic information. This information may be
carried on plasmids, small and specialized genetic elements that are capable of replication within at least one prokaryotic cell line. In some cases,
plasmids may be transferred from one cell to another and thus may carry sets of specialized genetic information through a population. Some plasmids
exhibit a broad host range that allows them to convey sets of genes to diverse organisms. Of particular concern are drug resistance plasmids that
may render diverse bacteria resistant to antibiotic treatment (Chapter 7).

The survival strategy of a single prokaryotic cell line may lead to a range of interactions with other organisms. These may include symbiotic
relationships illustrated by complex nutritional exchanges among organisms within the human gut. These exchanges benefit both the microorganisms
and their human host. Parasitic interactions can be quite deleterious to the host. Advanced symbiosis or parasitism can lead to loss of functions that
may not allow growth of the symbiont or parasite independent of its host.

The mycoplasmas, for example, are parasitic prokaryotes that have lost the ability to form a cell wall. Adaptation of these organisms to their parasitic
environment has resulted in incorporation of a substantial quantity of cholesterol into their cell membranes. Cholesterol, not found in other
prokaryotes, is assimilated from the metabolic environment provided by the host. Loss of function is exemplified also by obligate intracellular
parasites, the chlamydiae and rickettsiae. These bacteria are extremely small (0.2–0.5 µm in diameter) and depend on the host cell for many
essential metabolites and coenzymes. This loss of function is reflected by the presence of a smaller genome with fewer genes (see Table 7­1).

The most widely distributed examples of bacterial symbionts appear to be chloroplasts and mitochondria, the energy­yielding organelles of
eukaryotes. Evidence points to the conclusion that ancestors of these chloroplasts and mitochondria were endosymbionts, essentially
“domesticated bacteria” that established symbiosis within the cell membrane of the ancestral eukaryotic host. The presence of multiple copies of
these organelles may have contributed to the relatively large size of eukaryotic cells and to their capacity for specialization, a trait ultimately reflected
in the evolution of differentiated multicellular organisms.

Classification of the Prokaryotes
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of organisms requires their classification. An appropriate classification system allows a scientist to choose
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characteristics that allow swift and accurate categorization of a newly encountered organism. This categorical organization allows prediction of many
additional traits shared by other members of the category. In a hospital setting, successful classification of a pathogenic organism may provide the
eukaryotes. Evidence points to the conclusion that ancestors of these chloroplasts and mitochondria were endosymbionts, essentially
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“domesticated bacteria” that established symbiosis within the cell membrane of the ancestral eukaryotic host. The presence of multiple copies of
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these organelles may have contributed to the relatively large size of eukaryotic cells and to their capacity for specialization, a trait ultimately reflected
in the evolution of differentiated multicellular organisms.

Classification of the Prokaryotes

An understanding of any group of organisms requires their classification. An appropriate classification system allows a scientist to choose
characteristics that allow swift and accurate categorization of a newly encountered organism. This categorical organization allows prediction of many
additional traits shared by other members of the category. In a hospital setting, successful classification of a pathogenic organism may provide the
most direct route to its elimination. Classification may also provide a broad understanding of relationships among different organisms, and such
information may have great practical value. For example, elimination of a pathogenic organism will be relatively long­lasting if its habitat is occupied by
a nonpathogenic variant.

The principles of prokaryotic classification are discussed in Chapter 3. At the outset, it should be recognized that any prokaryotic characteristic might
serve as a potential criterion for classification. However, not all criteria are equally effective in grouping organisms. Possession of DNA, for example, is
a useless criterion for distinguishing organisms because all cells contain DNA. The presence of a broad host range plasmid is not a useful criterion
because such plasmids may be found in diverse hosts and need not be present all of the time. Useful criteria may be structural, physiologic,
biochemical, or genetic. Spores—specialized cell structures that may allow survival in extreme environments—are useful structural criteria for
classification because well­characterized subsets of bacteria form spores. Some bacterial groups can be effectively subdivided based upon their ability
to ferment specified carbohydrates. Such criteria may be ineffective when applied to other bacterial groups that may lack any fermentative capability. A
biochemical test, the Gram­stain, is an effective criterion for classification because response to the stain reflects fundamental differences in the
bacterial cell envelope that divide most bacteria into two major groups.

Genetic criteria are increasingly used in bacterial classification, and many of these advances are made possible by the development of DNA­based
technologies. It is now possible to design DNA probe or DNA amplification assays (eg, polymerase chain reaction [PCR] assays) that swiftly identify
organisms carrying specified genetic regions with common ancestry. Comparison of DNA sequences for some genes has led to the elucidation of
phylogenetic relationships among prokaryotes. Ancestral cell lines can be traced, and organisms can be grouped based on their evolutionary
affinities. These investigations have led to some striking conclusions. For example, comparison of cytochrome c sequences suggests that all
eukaryotes, including humans, arose from one of three different groups of purple photosynthetic bacteria. This conclusion in part explains the
evolutionary origin of eukaryotes, but it does not fully take into account the generally accepted view that the eukaryotic cell was derived from the
evolutionary merger of different prokaryotic cell lines.

Bacteria and Archaebacteria: The Major Subdivisions Within the Prokaryotes

A major success in molecular phylogeny has been the demonstration that prokaryotes fall into two major groups. Most investigations have been
directed to one group, the bacteria. The other group, the archaebacteria, has received relatively little attention until recently, partly because many of its
representatives are difficult to study in the laboratory. Some archaebacteria, for example, are killed by contact with oxygen, and others grow at
temperatures exceeding that of boiling water. Before molecular evidence became available, the major subgroupings of archaebacteria had seemed
disparate. The methanogens carry out an anaerobic respiration that gives rise to methane, the halophiles demand extremely high salt concentrations
for growth, and the thermoacidophiles require high temperature and acidity for growth. It has now been established that these prokaryotes share
biochemical traits such as cell wall or membrane components that set the group entirely apart from all other living organisms. An intriguing trait
shared by archaebacteria and eukaryotes is the presence of introns within genes. The function of introns—segments of DNA that interrupts
informational DNA within genes—is not established. What is known is that introns represent a fundamental characteristic shared by the DNA of
archaebacteria and eukaryotes. This common trait has led to the suggestion that—just as mitochondria and chloroplasts appear to be evolutionary
derivatives of the bacteria—the eukaryotic nucleus may have arisen from an archaebacterial ancestor.

PROTISTS
The “true nucleus” of eukaryotes (from Gr karyon, “nucleus”) is only one of their distinguishing features. The membrane­bound organelles, the
microtubules, and the microfilaments of eukaryotes form a complex intracellular structure unlike that found in prokaryotes. The organelles
responsible for the motility of eukaryotic cells are flagella or cilia—complex multistranded structures that do not resemble the flagella of prokaryotes.
Gene expression in eukaryotes takes place through a series of events achieving physiologic integration of the nucleus with the endoplasmic reticulum,
a structure that has no counterpart in prokaryotes. Eukaryotes are set apart by the organization of their cellular DNA in chromosomes separated by a
distinctive mitotic apparatus during cell division.

In general, genetic
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for eukaryotic species. This term can be applied only metaphorically
to the prokaryotes, which exchange fragments of DNA through recombination. Currently, the term protist is used informally as a catch­all term for
unicellular eukaryotic microorganisms. Because protists as a whole are paraphyletic, newer classification systems often split up traditional
responsible for the motility of eukaryotic cells are flagella or cilia—complex multistranded structures that do not resemble the flagella of prokaryotes.
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Gene expression in eukaryotes takes place through a series of events achieving physiologic integration of the nucleus with the endoplasmic reticulum,
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a structure that has no counterpart in prokaryotes. Eukaryotes are set apart by the organization of their cellular DNA in chromosomes separated by a
distinctive mitotic apparatus during cell division.

In general, genetic transfer among eukaryotes depends on fusion of haploid gametes to form a diploid cell containing a full set of genes derived
from each gamete. The life cycle of many eukaryotes is almost entirely in the diploid state, a form not encountered in prokaryotes. Fusion of gametes
to form reproductive progeny is a highly specific event and establishes the basis for eukaryotic species. This term can be applied only metaphorically
to the prokaryotes, which exchange fragments of DNA through recombination. Currently, the term protist is used informally as a catch­all term for
unicellular eukaryotic microorganisms. Because protists as a whole are paraphyletic, newer classification systems often split up traditional
subdivisions or groups based on morphological or biochemical characteristics.

Traditionally, microbial eukaryotes—protists—are placed in one of the four following major groups: algae, protozoa, fungi, and slime molds. These
traditional subdivisions, largely based on superficial commonalities, have been largely replaced by classification schemes based on phylogenetics.
Molecular methods used by modern taxonomists have been used to generate data supporting the redistribution of some members of these groups
into diverse and sometimes distantly related phyla. For example, the water molds are now considered to be closely related to photosynthetic
organisms such as brown algae and diatoms.

Algae

The term algae has long been used to denote all organisms that produce O2 as a product of photosynthesis. One former subgroup of these organisms
—the blue­green algae, or cyanobacteria—are prokaryotic and no longer are termed algae. This classification is reserved exclusively for a large diverse
group of photosynthetic eukaryotic organisms. Formerly, all algae were thought to contain chlorophyll in the photosynthetic membrane of their
chloroplast, a subcellular organelle that is similar in structure to cyanobacteria. Modern taxonomic approaches have recognized that some algae lack
chlorophyll and have a free­living heterotrophic or parasitic life style. Many algal species are unicellular microorganisms. Other algae may form
extremely large multicellular structures. Kelps of brown algae sometimes are several hundred meters in length. Several algae produce toxins that are
poisonous to humans and other animals. Dinoflagellates, a unicellular alga, are responsible for algal blooms, or red tides, in the ocean (Figure 1­5).
Red tides caused by the dinoflagellate Gonyaulax species are serious because this organism produces potent neurotoxins such as saxitoxin and
gonyautoxins, which accumulate in shellfish (eg, clams, mussels, scallops, and oysters) that feed on this organism. Ingestion of these shellfish by
humans results in symptoms of paralytic shellfish poisoning and can lead to death. Some algae (eg, Prototheca and Helicosporidium) are parasites
of metazoans or plants. Protothecosis is a disease of dogs, cats, cattle, and rarely humans caused by a type of algae, Prototheca, that lacks
chlorophyll. The two most common species are P. wickerhamii and P. zopfii; most human cases, which are associated with a defective immune system,
are caused by P. wickerhamii.

FIGURE 1­5

The dinoflagellate Gymnodinium scanning electron micrograph (4000×). (Reproduced with permission from Dr. David Phillips/Visuals Unlimited.)

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are caused by P. wickerhamii.
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FIGURE 1­5
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The dinoflagellate Gymnodinium scanning electron micrograph (4000×). (Reproduced with permission from Dr. David Phillips/Visuals Unlimited.)

Protozoa

Protozoa is an informal term for single­celled nonphotosynthetic eukaryotes that are either free­living or parasitic. Protozoa are abundant in aqueous
environments and soil. They range in size from as little as 1µm to several millimeters, or more. All protozoa are heterotrophic, deriving nutrients
from other organisms, either by ingesting them whole or by consuming their organic tissue or waste products. Some protozoans take in food by
phagocytosis, engulfing organic particles with pseudopodia (eg, amoeba), or taking in food through a mouth­like aperture called a cytostome.
Other protozoans absorb dissolved nutrients through their cell membranes, a process called osmotrophy.

Historically, the major groups of protozoa included: flagellates, motile cells possessing whip­like organelles of locomotion; amoebae, cells that
move by extending pseudopodia; and ciliates, cells possessing large numbers of short hair­like organelles of motility. Intermediate forms are known
that have flagella at one stage in their life cycle and pseudopodia at another stage. A fourth major group of protozoa, the sporozoa, are strict parasites
that are usually nonmotile; most of these reproduce sexually and asexually in alternate generations by means of spores. Recent taxonomic studies
have shown that only the ciliates are monophyletic, that is, a distinct lineage of organisms sharing common ancestry. The other classes of protozoa
are all polyphyletic groups made up of organisms that, despite similarities in appearance (eg, flagellates) or way of life (eg, endoparasitic), are not
necessarily closely related to one another. Protozoan parasites of humans are discussed in Chapter 46.

Fungi

The fungi are nonphotosynthetic protists that may or may not grow as a mass of branching, interlacing filaments (“hyphae”) known as a mycelium. If a
fungus grows simply as a single cell it is called a yeast. If mycelial growth occurs, it is called a mold. Most fungi of medical importance grow
dimorphically, that is, they exist as a mold at room temperature but as a yeast at body temperature. Remarkably, the largest known contiguous fungal
mycelium covered an area of 2400 acres (9.7 km2) at a site in eastern Oregon. Although the hyphae exhibit cross walls, the cross walls are perforated
and allow free passage of nuclei and cytoplasm. The entire organism is thus a coenocyte (a multinucleated mass of continuous cytoplasm) confined
within a series of branching tubes. These tubes, made of polysaccharides such as chitin, are homologous with cell walls.

The fungi probably represent an evolutionary offshoot of the protozoa; they are unrelated to the actinomycetes, mycelial bacteria that they
superficially resemble. The major subdivisions (phyla) of fungi are Chytridiomycota, Zygomycota (the zygomycetes), Ascomycota (the ascomycetes),
Basidiomycota (the basidiomycetes), and the “deuteromycetes” (or imperfect fungi). The evolution of the ascomycetes from the phycomycetes is seen
in a transitional group, whose members form a zygote but then transform this directly into an ascus. The basidiomycetes are believed to have evolved
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Slime Molds
within a series of branching tubes. These tubes, made of polysaccharides such as chitin, are homologous with cell walls.
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The fungi probably represent an evolutionary offshoot of the protozoa; they are unrelated to the actinomycetes, mycelial bacteria that they
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superficially resemble. The major subdivisions (phyla) of fungi are Chytridiomycota, Zygomycota (the zygomycetes), Ascomycota (the ascomycetes),
Basidiomycota (the basidiomycetes), and the “deuteromycetes” (or imperfect fungi). The evolution of the ascomycetes from the phycomycetes is seen
in a transitional group, whose members form a zygote but then transform this directly into an ascus. The basidiomycetes are believed to have evolved
in turn from the ascomycetes. The classification of fungi and their medical significance are discussed further in Chapter 45.

Slime Molds

These organisms are characterized by the presence, as a stage in their life cycle, of an ameboid multinucleate mass of cytoplasm called a
plasmodium. The plasmodium of a slime mold is analogous to the mycelium of a true fungus. Both are coenocytic. Whereas in the latter, cytoplasmic
flow is confined to the branching network of chitinous tubes, in the former, the cytoplasm can flow in all directions. This flow causes the plasmodium
to migrate in the direction of its food source, frequently bacteria. In response to a chemical signal, 3′, 5′­cyclic AMP, the plasmodium, which reaches
macroscopic size, differentiates into a stalked body that can produce individual motile cells. These cells, flagellated or ameboid, initiate a new round in
the life cycle of the slime mold (Figure 1­6). The cycle frequently is initiated by sexual fusion of single cells.

FIGURE 1­6

Slime molds. A : Life cycle of an acellular slime mold. B : Fruiting body of a cellular slime mold. (Reproduced with permission from Carolina Biological
Supply/DIOMEDIA.)

The growth of slime molds depends on nutrients provided by bacterial or, in some cases, plant cells. Reproduction of the slime molds via plasmodia
can depend on intercellular recognition and fusion of cells from the same species. The life cycle of the slime molds illustrates a central theme of this
chapter—the interdependency of living forms. Full understanding of any microorganism requires both knowledge of the other organisms with which it
coevolved and an appreciation of the range of physiologic responses that may contribute to survival.

CHAPTER SUMMARY
Microorganisms are a large and diverse group of organisms existing as single cells or clusters; they also include viruses, which are microscopic but
not cellular.

A virus consists of a nucleic acid molecule, either DNA or RNA, enclosed in a protein coat, or capsid, sometimes enclosed by an envelope
composed of lipids, proteins, and carbohydrates.

A prion is an infectious protein, which is capable of causing chronic neurologic diseases.

Prokaryotes consist of bacteria and archaebacteria.

Prokaryotes are haploid.

Microbial eukaryotes, or protists, are members of four major groups: algae, protozoa, fungi, and slime molds.

Eukaryotes have a true nucleus and are diploid.

REFERENCES
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Abrescia
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McGraw DH, Grimes
Hill. All Rights JM, et al:
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universe. Rev Biochem 2012;81:795. [PubMed: 22482909]
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Adi SM, Simpson AGB, Lane CE, et al: The revised classification of eukaryotes. J Eukaryot Microbiol 2012;59:429. [PubMed: 23020233]
 Prokaryotes are haploid.
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Microbial eukaryotes, or protists, are members of four major groups: algae, protozoa, fungi, and slime molds. Access Provided by:

Eukaryotes have a true nucleus and are diploid.

REFERENCES

Abrescia NGA, Bamford DH, Grimes JM, et al: Structure unifies the viral universe. Annu Rev Biochem 2012;81:795. [PubMed: 22482909]

Adi SM, Simpson AGB, Lane CE, et al: The revised classification of eukaryotes. J Eukaryot Microbiol 2012;59:429. [PubMed: 23020233]

Arslan D, Legendre M, Seltzer V, et al: Distant Mimivirus relative with a larger genome highlights the fundamental features of Megaviridae. Proc Natl
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Belay ED: Transmissible spongiform encephalopathies in humans. Annu Rev Microbiol 1999;53:283. [PubMed: 10547693]

Colby DW, Prusiner SB: De novo generation of prion strains. Nat Rev Microbiol 2011;9:771. [PubMed: 21947062]

Diener TO: Viroids and the nature of viroid diseases. Arch Virol 1999;15(Suppl):203.

Fournier PE, Raoult D: Prospects for the future using genomics and proteomics in clinical microbiology. Annu Rev Microbiol 2011;65:169. [PubMed:
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Katz LA: Origin and diversification of eukaryotes. Annu Rev Microbiol 2012;63:411.

Lederberg J (editor): Encyclopedia of Microbiology , 4 vols. Academic Press, 1992.

Olsen GJ, Woese CR: The winds of (evolutionary) change: Breathing new life into microbiology. J Bacteriol 1994;176:1. [PubMed: 8282683]

Priola SA: How animal prions cause disease in humans. Microbe 2008;3:568.

Prusiner SB: Biology and genetics of prion diseases. Annu Rev Microbiol 1994;48:655. [PubMed: 7826022]

Prusiner SB, Woerman AL, Mordes DA, et al: Evidence for α­synuclein prions causing multiple system atrophy in humans with parkinsonism. Proc
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Schloss PD, Handlesman J: Status of the microbial census. Microbiol Mol Biol Rev 2004;68:686. [PubMed: 15590780]

Sleigh MA: Protozoa and Other Protists. Chapman & Hall, 1990.

Whitman WB, Coleman DC, Wiebe WJ: Prokaryotes: The unseen majority. Proc Natl Acad Sci U S A 1998;95:6578. [PubMed: 9618454]

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