Chapter 13 Diversity of Microbes, Fungi, and Protists PDF

Summary

This chapter details the diversity of microbes, fungi, and protists, exploring their evolutionary history, characteristics, and roles in various aspects of life. It discusses prokaryotic and eukaryotic origins, encompassing bacterial diseases and the roles of prokaryotes in bioremediation.

Full Transcript

CHAPTER 13
Diversity of Microbes, Fungi, and
Protists

FIGURE 13.1 Living things are very diverse, from simple, single-celled bacteria to complex, multicellular organisms.
(credit "ringworm": modification of work by Dr. Lucille K. Georg, CDC; credit "Trypanosomes": modification of work by
Dr. Myron G. Schultz, CDC; credit “tree mold”: modification of work by Janice Haney Carr, Robert Simmons, CDC;
credit "coral fungus": modification of work by Cory Zanker; credit "bacterium": modification of work by Dr. David Cox,
CDC; credit "cup fungus": modification of work by "icelight"/Flickr; credit "MRSA": modification of work by Janice
Haney Carr, CDC; credit "moldy grapefruit": modification of work by Joseph Smilanick)

CHAPTER OUTLINE
13.1 Prokaryotic Diversity
13.2 Eukaryotic Origins
13.3 Protists
13.4 Fungi

INTRODUCTION Until the late twentieth century, scientists most commonly grouped living things
into five kingdoms—animals, plants, fungi, protists, and bacteria—based on several criteria, such
as absence or presence of a nucleus and other membrane-bound organelles, absence or presence
of cell walls, multicellularity, and mode of nutrition. In the late twentieth century, the pioneering
work of Carl Woese and others compared nucleotide sequences of small-subunit ribosomal RNA
(SSU rRNA), which resulted in a dramatically different way to group organisms on Earth. Based on
differences in the structure of cell membranes and in rRNA, Woese and his colleagues proposed
288 13 Diversity of Microbes, Fungi, and Protists

that all life on Earth evolved along three lineages, called domains. The three domains are called
Bacteria, Archaea, and Eukarya.

Two of the three domains—Bacteria and Archaea—are prokaryotic, meaning that they lack both a
nucleus and true membrane-bound organelles. However, they are now considered, on the basis of
membrane structure and rRNA, to be as different from each other as they are from the third
domain, the Eukarya. Prokaryotes were the first inhabitants on Earth, perhaps appearing
approximately 3.9 billion years ago. Today they are ubiquitous—inhabiting the harshest
environments on the planet, from boiling hot springs to permanently frozen environments in
Antarctica, as well as more benign environments such as compost heaps, soils, ocean waters, and
the guts of animals (including humans). The Eukarya include the familiar kingdoms of animals,
plants, and fungi. They also include a diverse group of kingdoms formerly grouped together as
protists.

13.1 Prokaryotic Diversity
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the evolutionary history of prokaryotes
Describe the basic structure of a typical prokaryote
Identify bacterial diseases that caused historically important plagues and epidemics
Describe the uses of prokaryotes in food processing and bioremediation

Prokaryotes are present everywhere. They cover every imaginable surface where there is
sufficient moisture, and they live on and inside of other living things. There are more prokaryotes
inside and on the exterior of the human body than there are human cells in the body. Some
prokaryotes thrive in environments that are inhospitable for most other living things. Prokaryotes
recycle nutrients—essential substances (such as carbon and nitrogen)—and they drive the
evolution of new ecosystems, some of which are natural while others are man-made. Prokaryotes
have been on Earth since long before multicellular life appeared.

Prokaryotic Diversity
The advent of DNA sequencing provided immense insight into the relationships and origins of
prokaryotes that were not possible using traditional methods of classification. A major insight
identified two groups of prokaryotes that were found to be as different from each other as they
were from eukaryotes. This recognition of prokaryotic diversity forced a new understanding of the
classification of all life and brought us closer to understanding the fundamental relationships of all
living things, including ourselves.

Early Life on Earth
When and where did life begin? What were the conditions on Earth when life began? Prokaryotes
were the first forms of life on Earth, and they existed for billions of years before plants and animals
appeared. Earth is about 4.54 billion years old. This estimate is based on evidence from the dating
of meteorite material, since surface rocks on Earth are not as old as Earth itself. Most rocks
available on Earth have undergone geological changes that make them younger than Earth itself.
Some meteorites are made of the original material in the solar disk that formed the objects of the
solar system, and they have not been altered by the processes that altered rocks on Earth. Thus,
the age of meteorites is a good indicator of the age of the formation of Earth. The original estimate
of 4.54 billion years was obtained by Clair Patterson in 1956. His meticulous work has since been
corroborated by ages determined from other sources, all of which point to an Earth age of about
4.54 billion years.

Early Earth had a very different atmosphere than it does today. Evidence indicates that during the
first 2 billion years of Earth’s existence, the atmosphere was anoxic, meaning that there was no
oxygen. Therefore, only those organisms that can grow without oxygen—anaerobic
organisms—were able to live. Organisms that convert solar energy into chemical energy are called

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 13.1 Prokaryotic Diversity 289

phototrophs. Phototrophic organisms that required an organic source of carbon appeared within one billion years of
the formation of Earth. Then, cyanobacteria, also known as blue-green algae, evolved from these simple
phototrophs one billion years later. Cyanobacteria are able to use carbon dioxide as a source of carbon.
Cyanobacteria (Figure 13.2) began the oxygenation of the atmosphere. The increase in oxygen concentration
allowed the evolution of other life forms.

FIGURE 13.2 This hot spring in Yellowstone National Park flows toward the foreground. Cyanobacteria in the spring are green, and as water
flows down the heat gradient, the intensity of the color increases because cell density increases. The water is cooler at the edges of the
stream than in the center, causing the edges to appear greener. (credit: Graciela Brelles-Mariño)

Before the atmosphere became oxygenated, the planet was subjected to strong radiation; thus, the first organisms
would have flourished where they were more protected, such as in ocean depths or beneath the surface of Earth. At
this time, too, strong volcanic activity was common on Earth, so it is likely that these first organisms—the first
prokaryotes—were adapted to very high temperatures. These are not the typical temperate environments in which
most life flourishes today; thus, we can conclude that the first organisms that appeared on Earth likely were able to
withstand harsh conditions.

Microbial mats may represent the earliest forms of life on Earth, and there is fossil evidence of their presence,
starting about 3.5 billion years ago. A microbial mat is a large biofilm, a multi-layered sheet of prokaryotes (Figure
13.3a), including mostly bacteria, but also archaea. Microbial mats are a few centimeters thick, and they typically
grow on moist surfaces. Their various types of prokaryotes carry out different metabolic pathways, and for this
reason, they reflect various colors. Prokaryotes in a microbial mat are held together by a gummy-like substance that
they secrete.

The first microbial mats likely obtained their energy from hydrothermal vents. A hydrothermal vent is a fissure in
Earth’s surface that releases geothermally heated water. With the evolution of photosynthesis about 3 billion years
ago, some prokaryotes in microbial mats came to use a more widely available energy source—sunlight—whereas
others were still dependent on chemicals from hydrothermal vents for food.

FIGURE 13.3 (a) This microbial mat grows over a hydrothermal vent in the Pacific Ocean. Chimneys such as the one indicated by the arrow
allow gases to escape. (b) This photo shows stromatolites that are nearly 1.5 billion years old, found in Glacier National Park, Montana.
(credit a: modification of work by Dr. Bob Embley, NOAA PMEL; credit b: modification of work by P. Carrara, NPS)
290 13 Diversity of Microbes, Fungi, and Protists

Fossilized microbial mats represent the earliest record of life on Earth. A stromatolite is a sedimentary structure
formed when minerals are precipitated from water by prokaryotes in a microbial mat (Figure 13.3b). Stromatolites
form layered rocks made of carbonate or silicate. Although most stromatolites are artifacts from the past, there are
places on Earth where stromatolites are still forming. For example, living stromatolites have been found in the Anza-
Borrego Desert State Park in San Diego County, California. Efforts to understand the earliest microbial mats may also
have implications on the search for life elsewhere. Nora Noffke, who identified many of the features used in dating
and categorizing microbially produced sedimentary structures, emphasizes that similar formations could be used to
find evidence of life on Mars. When analyzing photos taken by the NASA Curiosity rover, Noffke showcased the
similarities between fossilized microbial mats found on the two planets.

Some prokaryotes are able to thrive and grow under conditions that would kill a plant or animal. Bacteria and
archaea that grow under extreme conditions are called extremophiles, meaning “lovers of extremes.”
Extremophiles have been found in extreme environments of all kinds, including the depths of the oceans, hot
springs, the Arctic and the Antarctic, very dry places, deep inside Earth, harsh chemical environments, and high
radiation environments. Extremophiles give us a better understanding of prokaryotic diversity and open up the
possibility of the discovery of new therapeutic drugs or industrial applications. They have also opened up the
possibility of finding life in other places in the solar system, which have harsher environments than those typically
found on Earth. Many of these extremophiles cannot survive in moderate environments.

LINK TO LEARNING
Read this transcript (https://openstax.org/l/extremophiles) of NASA scientist Richard Hoover discussing the
implications that the existence extremophiles on Earth have on the possibility of finding life on other planets in our
solar system, such as Mars.

Biofilms
Until a couple of decades ago, microbiologists thought of prokaryotes as isolated entities living apart. This model,
however, does not reflect the true ecology of prokaryotes, most of which prefer to live in communities where they
can interact. A biofilm is a microbial community held together in a gummy-textured matrix, consisting primarily of
polysaccharides secreted by the organisms, together with some proteins and nucleic acids. Biofilms grow attached
to surfaces. Some of the best-studied biofilms are composed of prokaryotes, although fungal biofilms have also
been described.

Biofilms are present almost everywhere. They cause the clogging of pipes and readily colonize surfaces in industrial
settings. They have played roles in recent, large-scale outbreaks of bacterial contamination of food. Biofilms also
colonize household surfaces, such as kitchen counters, cutting boards, sinks, and toilets.

Interactions among the organisms that populate a biofilm, together with their protective environment, make these
communities more robust than are free-living, or planktonic, prokaryotes. Overall, biofilms are very difficult to
destroy, because they are resistant to many of the common forms of sterilization.

Characteristics of Prokaryotes
There are many differences between prokaryotic and eukaryotic cells. However, all cells have four common
structures: a plasma membrane that functions as a barrier for the cell and separates the cell from its environment;
cytoplasm, a jelly-like substance inside the cell; genetic material (DNA and RNA); and ribosomes, where protein
synthesis takes place. Prokaryotes come in various shapes, but many fall into three categories: cocci (spherical),
bacilli (rod-shaped), and spirilla (spiral-shaped) (Figure 13.4).

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 13.1 Prokaryotic Diversity 291

FIGURE 13.4 Many prokaryotes fall into three basic categories based on their shape: (a) cocci, or spherical; (b) bacilli, or rod-shaped; and
(c) spirilla, or spiral-shaped. (credit a: modification of work by Janice Haney Carr, Dr. Richard Facklam, CDC; credit c: modification of work
by Dr. David Cox, CDC; scale-bar data from Matt Russell)

The Prokaryotic Cell
Recall that prokaryotes (Figure 13.5) are unicellular organisms that lack organelles surrounded by membranes.
Therefore, they do not have a nucleus but instead have a single chromosome—a piece of circular DNA located in an
area of the cell called the nucleoid. Most prokaryotes have a cell wall lying outside the plasma membrane. The
composition of the cell wall differs significantly between the domains Bacteria and Archaea (and their cell walls also
differ from the eukaryotic cell walls found in plants and fungi.) The cell wall functions as a protective layer and is
responsible for the organism’s shape. Some other structures are present in some prokaryotic species, but not in
others. For example, the capsule found in some species enables the organism to attach to surfaces and protects it
from dehydration. Some species may also have flagella (singular, flagellum) used for locomotion, and pili (singular,
pilus) used for attachment to surfaces and to other bacteria for conjugation. Plasmids, which consist of small,
circular pieces of DNA outside of the main chromosome, are also present in many species of bacteria.

FIGURE 13.5 The features of a typical bacterium cell are shown.

Both Bacteria and Archaea are types of prokaryotic cells. They differ in the lipid composition of their cell membranes
and in the characteristics of their cell walls. Both types of prokaryotes have the same basic structures, but these are
built from different chemical components that are evidence of an ancient separation of their lineages. The archaeal
plasma membrane is chemically different from the bacterial membrane; some archaeal membranes are lipid
monolayers instead of phosopholipid bilayers.

The Cell Wall
The cell wall is a protective layer that surrounds some prokaryotic cells and gives them shape and rigidity. It is
located outside the cell membrane and prevents osmotic lysis (bursting caused by increasing volume). The chemical
compositions of the cell walls vary between Archaea and Bacteria, as well as between bacterial species. Bacterial
cell walls contain peptidoglycan, composed of polysaccharide chains cross-linked to peptides. Bacteria are divided
into two major groups: Gram-positive and Gram-negative, based on their reaction to a procedure called Gram
292 13 Diversity of Microbes, Fungi, and Protists

staining. The different bacterial responses to the staining procedure are caused by cell wall structure. Gram-positive
organisms have a thick wall consisting of many layers of peptidoglycan. Gram-negative bacteria have a thinner cell
wall composed of a few layers of peptidoglycan and additional structures, surrounded by an outer membrane
(Figure 13.6).

VISUAL CONNECTION

FIGURE 13.6 Bacteria are divided into two major groups: Gram-positive and Gram-negative. Both groups have a cell wall composed of
peptidoglycans: In Gram-positive bacteria, the wall is thick, whereas in Gram-negative bacteria, the wall is thin. In Gram-negative bacteria,
the cell wall is surrounded by an outer membrane.

Which of the following statements is true?

a. Gram-positive bacteria have a single cell wall formed from peptidoglycan.
b. Gram-positive bacteria have an outer membrane.
c. The cell wall of Gram-negative bacteria is thick, and the cell wall of Gram-positive bacteria is thin.
d. Gram-negative bacteria have a cell wall made of peptidoglycan, while Gram-positive bacteria have a cell wall
made of phospholipids.

Archaeal cell walls do not contain peptidoglycan. There are four different types of archaeal cell walls. One type is
composed of pseudopeptidoglycan. The other three types of cell walls contain polysaccharides, glycoproteins, and
surface-layer proteins known as S-layers.

Reproduction
Reproduction in prokaryotes is primarily asexual and takes place by binary fission. Recall that the DNA of a
prokaryote exists usually as a single, circular chromosome. Prokaryotes do not undergo mitosis. Rather, the
chromosome loop is replicated, and the two resulting copies attached to the plasma membrane move apart as the
cell grows in a process called binary fission. The prokaryote, now enlarged, is pinched inward at its equator, and the
two resulting cells, which are clones, separate. Binary fission does not provide an opportunity for genetic
recombination, but prokaryotes can alter their genetic makeup in three ways.

Binary fission as a way of reproduction does not provide an opportunity for genetic recombination and increased
genetic variability. However, prokaryotes can alter their genetic makeup by three mechanisms of obtaining
exogenous DNA. In a process called transformation, the cell takes in DNA found in its environment that is shed by
other prokaryotes, alive or dead. A pathogen is an organism that causes a disease. If a nonpathogenic bacterium
takes up DNA from a pathogen and incorporates the new DNA in its own chromosome, it too may become
pathogenic. In transduction, bacteriophages, the viruses that infect bacteria, move DNA from one bacterium to
another. Archaea have a different set of viruses that infect them and translocate genetic material from one individual
to another. During conjugation, DNA is transferred from one prokaryote to another by means of a pilus that brings
the organisms into contact with one another. The DNA transferred is usually a plasmid, but parts of the chromosome
can also be moved.

Cycles of binary fission can be very rapid, on the order of minutes for some species. This short generation time
coupled with mechanisms of genetic recombination result in the rapid evolution of prokaryotes, allowing them to

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 13.1 Prokaryotic Diversity 293

respond to environmental changes (such as the introduction of an antibiotic) very quickly.

How Prokaryotes Obtain Energy and Carbon
Prokaryotes are metabolically diverse organisms. Prokaryotes fill many niches on Earth, including being involved in
nutrient cycles such as the nitrogen and carbon cycles, decomposing dead organisms, and growing and multiplying
inside living organisms, including humans. Different prokaryotes can use different sources of energy to assemble
macromolecules from smaller molecules. Phototrophs obtain their energy from sunlight. Chemotrophs obtain their
energy from chemical compounds.

Bacterial Diseases in Humans
Devastating pathogen-borne diseases and plagues, both viral and bacterial in nature, have affected and continue to
affect humans. It is worth noting that all pathogenic prokaryotes are Bacteria; there are no known pathogenic
Archaea in humans or any other organism. Pathogenic organisms evolved alongside humans. In the past, the true
cause of these diseases was not understood, and some cultures thought that diseases were a spiritual punishment
or were mistaken about material causes. Over time, people came to realize that staying apart from afflicted persons,
improving sanitation, and properly disposing of the corpses and personal belongings of victims of illness reduced
their own chances of getting sick.

Historical Perspective
There are records of infectious diseases as far back as 3,000 B.C. A number of significant pandemics caused by
Bacteria have been documented over several hundred years. Some of the largest pandemics led to the decline of
cities and cultures. Many were zoonoses that appeared with the domestication of animals, as in the case of
tuberculosis. A zoonosis is a disease that infects animals but can be transmitted from animals to humans.

Infectious diseases remain among the leading causes of death worldwide. Their impact is less significant in many
developed countries, but they are important determiners of mortality in developing countries. The development of
antibiotics did much to lessen the mortality rates from bacterial infections, but access to antibiotics is not universal,
and the overuse of antibiotics has led to the development of resistant strains of bacteria. Public sanitation efforts
that dispose of sewage and provide clean drinking water have done as much or more than medical advances to
prevent deaths caused by bacterial infections.

In 430 B.C., the plague of Athens killed one-quarter of the Athenian troops that were fighting in the Great
Peloponnesian War. The disease killed a quarter of the population of Athens in over 4 years and weakened Athens’
dominance and power. The source of the plague may have been identified recently when researchers from the
University of Athens were able to analyze DNA from teeth recovered from a mass grave. The scientists identified
1
nucleotide sequences from a pathogenic bacterium that causes typhoid fever.

From 541 to 750 A.D., an outbreak called the plague of Justinian (likely a bubonic plague) eliminated, by some
estimates, one-quarter to one-half of the human population. The population in Europe declined by 50 percent
during this outbreak. Bubonic plague would decimate Europe more than once.

One of the most devastating pandemics was the Black Death (1346 to 1361), which is believed to have been
another outbreak of bubonic plague caused by the bacterium Yersinia pestis. This bacterium is carried by fleas living
on black rats. The Black Death reduced the world’s population from an estimated 450 million to about 350 to 375
million. Bubonic plague struck London hard again in the mid-1600s. There are still approximately 1,000 to 3,000
cases of plague globally each year. Although contracting bubonic plague before antibiotics meant almost certain
death, the bacterium responds to several types of modern antibiotics, and mortality rates from plague are now very
low.

LINK TO LEARNING
Watch a video (http://openstax.org/l/black_death2) on the modern understanding of the Black Death (bubonic

1 Papagrigorakis M. J., Synodinos P. N., Yapijakis C, “Ancient typhoid epidemic reveals possible ancestral strain of Salmonella enterica
serovar Typhi, Infect Genet Evol 7 (2007): 126-7.
294 13 Diversity of Microbes, Fungi, and Protists

plague) in Europe during the fourteenth century.

Over the centuries, Europeans developed resistance to many infectious diseases. However, European conquerors
brought disease-causing bacteria and viruses with them when they reached the Western hemisphere, triggering
epidemics that completely devastated populations of Native Americans (who had no natural resistance to many
European diseases).

The Antibiotic Crisis
The word antibiotic comes from the Greek anti, meaning “against,” and bios, meaning “life.” An antibiotic is an
organism-produced chemical that is hostile to the growth of other organisms. Today’s news and media often
address concerns about an antibiotic crisis. Are antibiotics that were used to treat bacterial infections easily
treatable in the past becoming obsolete? Are there new “superbugs”—bacteria that have evolved to become more
resistant to our arsenal of antibiotics? Is this the beginning of the end of antibiotics? All of these questions challenge
the healthcare community.

One of the main reasons for resistant bacteria is the overuse and incorrect use of antibiotics, such as not completing
a full course of prescribed antibiotics. The incorrect use of an antibiotic results in the natural selection of resistant
forms of bacteria. The antibiotic kills most of the infecting bacteria, and therefore only the resistant forms remain.
These resistant forms reproduce, resulting in an increase in the proportion of resistant forms over non-resistant
ones.

Another problem is the excessive use of antibiotics in livestock. The routine use of antibiotics in animal feed
promotes bacterial resistance as well. In the United States, 70 percent of the antibiotics produced are fed to
animals. The antibiotics are not used to prevent disease, but to enhance production of their products.

LINK TO LEARNING
Watch an overview report (http://openstax.org/l/antibiotics2) on the problem of routine antibiotic administration to
livestock and antibiotic-resistant bacteria.

Staphylococcus aureus, often called “staph,” is a common bacterium that can live in and on the human body, which
usually is easily treatable with antibiotics. A very dangerous strain, however, has made the news over the past few
years (Figure 13.7). This strain, methicillin-resistant Staphylococcus aureus (MRSA), is resistant to many
commonly used antibiotics, including methicillin, amoxicillin, penicillin, and oxacillin. While MRSA infections have
been common among people in healthcare facilities, it is appearing more commonly in healthy people who live or
work in dense groups (like military personnel and prisoners). The Journal of the American Medical Association
reported that, among MRSA-afflicted persons in healthcare facilities, the average age is 68 years, while people with
2
“community-associated MRSA” (CA-MRSA) have an average age of 23 years.

FIGURE 13.7 This scanning electron micrograph shows methicillin-resistant Staphylococcus aureus bacteria, commonly known as MRSA.
(credit: modification of work by Janice Haney Carr, CDC; scale-bar data from Matt Russell)

2 Naimi, T. S., LeDell, K. H., Como-Sabetti, K., et al., “Comparison of community- and health care-associated methicillin-resistant
Staphylococcus aureus infection,” JAMA 290 (2003): 2976-2984, doi: 10.1001/jama.290.22.2976.

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 13.1 Prokaryotic Diversity 295

In summary, society is facing an antibiotic crisis. Some scientists believe that after years of being protected from
bacterial infections by antibiotics, we may be returning to a time in which a simple bacterial infection could again
devastate the human population. Researchers are working on developing new antibiotics, but few are in the drug
development pipeline, and it takes many years to generate an effective and approved drug.

Foodborne Diseases
Prokaryotes are everywhere: They readily colonize the surface of any type of material, and food is not an exception.
Outbreaks of bacterial infection related to food consumption are common. A foodborne disease (colloquially called
“food poisoning”) is an illness resulting from the consumption of food contaminated with pathogenic bacteria,
viruses, or other parasites. Although the United States has one of the safest food supplies in the world, the Center
for Disease Control and Prevention (CDC) has reported that “76 million people get sick, more than 300,000 are
3
hospitalized, and 5,000 Americans die each year from foodborne illness.”

The characteristics of foodborne illnesses have changed over time. In the past, it was relatively common to hear
about sporadic cases of botulism, the potentially fatal disease produced by a toxin from the anaerobic bacterium
Clostridium botulinum. A can, jar, or package created a suitable anaerobic environment where Clostridium could
grow. Proper sterilization and canning procedures have reduced the incidence of this disease.

Most cases of foodborne illnesses are now linked to produce contaminated by animal waste. For example, there
have been serious, produce-related outbreaks associated with raw spinach in the United States and with vegetable
sprouts in Germany (Figure 13.8). The raw spinach outbreak in 2006 was produced by the bacterium E. coli strain
O157:H7. Most E. coli strains are not particularly dangerous to humans, (indeed, they live in our large intestine), but
O157:H7 is potentially fatal.

FIGURE 13.8 (a) Locally grown vegetable sprouts were the cause of a European E. coli outbreak that killed 31 people and sickened about
3,000 in 2010. (b) Escherichia coli are shown here in a scanning electron micrograph. The strain of E. coli that caused a deadly outbreak in
Germany is a new one not involved in any previous E. coli outbreaks. It has acquired several antibiotic resistance genes and specific genetic
sequences involved in aggregation ability and virulence. It has recently been sequenced. (credit b: Rocky Mountain Laboratories, NIAID,
NIH; scale-bar data from Matt Russell)

All types of food can potentially be contaminated with harmful bacteria of different species. Recent outbreaks of
Salmonella reported by the CDC occurred in foods as diverse as peanut butter, alfalfa sprouts, and eggs.

CAREER CONNECTION

Epidemiologist
Epidemiology is the study of the occurrence, distribution, and determinants of health and disease in a population. It
is, therefore, related to public health. An epidemiologist studies the frequency and distribution of diseases within
human populations and environments.

Epidemiologists collect data about a particular disease and track its spread to identify the original mode of

3 http://www.cdc.gov/ecoli/2006/september, Centers for Disease Control and Prevention, “Multi-state outbreak of E. coli O157:H7
infections from spinach,” September-October (2006).
296 13 Diversity of Microbes, Fungi, and Protists

transmission. They sometimes work in close collaboration with historians to try to understand the way a disease
evolved geographically and over time, tracking the natural history of pathogens. They gather information from
clinical records, patient interviews, and any other available means. That information is used to develop strategies
and design public health policies to reduce the incidence of a disease or to prevent its spread. Epidemiologists also
conduct rapid investigations in case of an outbreak to recommend immediate measures to control it.

Epidemiologists typically have a graduate-level education. An epidemiologist often has a bachelor’s degree in some
field and a master’s degree in public health (MPH). Many epidemiologists are also physicians (and have an MD) or
they have a PhD in an associated field, such as biology or epidemiology.

Beneficial Prokaryotes
Not all prokaryotes are pathogenic. On the contrary, pathogens represent only a very small percentage of the
diversity of the microbial world. In fact, our life and all life on this planet would not be possible without prokaryotes.

Prokaryotes, and Food and Beverages
According to the United Nations Convention on Biological Diversity, biotechnology is “any technological application
that uses biological systems, living organisms, or derivatives thereof, to make or modify products or processes for
4
specific use.” The concept of “specific use” involves some sort of commercial application. Genetic engineering,
artificial selection, antibiotic production, and cell culture are current topics of study in biotechnology. However,
humans have used prokaryotes to create products before the term biotechnology was even coined. And some of the
goods and services are as simple as cheese, yogurt, sour cream, vinegar, cured sausage, sauerkraut, and fermented
seafood that contains both bacteria and archaea (Figure 13.9).

FIGURE 13.9 Some of the products derived from the use of prokaryotes in early biotechnology include (a) cheese, (b) salami, (c) yogurt,
and (d) fish sauce. (credit b: modification of work by Alisdair McDiarmid; credit c: modification of work by Kris Miller; credit d: modification
of work by Jane Whitney)

Cheese production began around 4,000 years ago when humans started to breed animals and process their milk.
Evidence suggests that cultured milk products, like yogurt, have existed for at least 4,000 years.

4 http://www.cbd.int/convention/articles/?a=cbd-02http://www.cbd.int/convention/articles/?a=cbd-02, United Nations Convention on
Biological Diversity, “Article 2: Use of Terms.”

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 13.1 Prokaryotic Diversity 297

Using Prokaryotes to Clean up Our Planet: Bioremediation
Microbial bioremediation is the use of prokaryotes (or microbial metabolism) to remove pollutants. Bioremediation
has been used to remove agricultural chemicals (pesticides and fertilizers) that leach from soil into groundwater.
Certain toxic metals, such as selenium and arsenic compounds, can also be removed from water by bioremediation.
The reduction of to and to Se0 (metallic selenium) is a method used to remove selenium ions from
water. Mercury is an example of a toxic metal that can be removed from an environment by bioremediation. Mercury
is an active ingredient of some pesticides; it is used in industry and is also a byproduct of certain industries, such as
battery production. Mercury is usually present in very low concentrations in natural environments but it is highly
toxic because it accumulates in living tissues. Several species of bacteria can carry out the biotransformation of
toxic mercury into nontoxic forms. These bacteria, such as Pseudomonas aeruginosa, can convert Hg2+ to Hg0,
which is nontoxic to humans.

Probably one of the most useful and interesting examples of the use of prokaryotes for bioremediation purposes is
the cleanup of oil spills. The importance of prokaryotes to petroleum bioremediation has been demonstrated in
several oil spills in recent years, such as the Exxon Valdez spill in Alaska (1989) (Figure 13.10), the Prestige oil spill
in Spain (2002), the spill into the Mediterranean from a Lebanon power plant (2006,) and more recently, the BP oil
spill in the Gulf of Mexico (2010). To clean up these spills, bioremediation is promoted by adding inorganic nutrients
that help bacteria already present in the environment to grow. Hydrocarbon-degrading bacteria feed on the
hydrocarbons in the oil droplet, breaking them into inorganic compounds. Some species, such as Alcanivorax
borkumensis, produce surfactants that solubilize the oil, while other bacteria degrade the oil into carbon dioxide. In
the case of oil spills in the ocean, ongoing, natural bioremediation tends to occur, inasmuch as there are oil-
consuming bacteria in the ocean prior to the spill. Under ideal conditions, it has been reported that up to 80 percent
of the nonvolatile components in oil can be degraded within 1 year of the spill. Other oil fractions containing
aromatic and highly branched hydrocarbon chains are more difficult to remove and remain in the environment for
longer periods of time. Researchers have genetically engineered other bacteria to consume petroleum products;
indeed, the first patent application for a bioremediation application in the U.S. was for a genetically modified oil-
eating bacterium.

FIGURE 13.10 (a) Cleaning up oil after the Valdez spill in Alaska, the workers hosed oil from beaches and then used a floating boom to
corral the oil, which was finally skimmed from the water surface. Some species of bacteria are able to solubilize and degrade the oil. (b) One
of the most catastrophic consequences of oil spills is the damage to fauna. (credit a: modification of work by NOAA; credit b: modification of
work by GOLUBENKOV, NGO: Saving Taman)

Prokaryotes in and on the Body
Humans are no exception when it comes to forming symbiotic relationships with prokaryotes. We are accustomed to
thinking of ourselves as single organisms, but in reality, we are walking ecosystems. There are 10 to 100 times as
many bacterial and archaeal cells inhabiting our bodies as we have cells in our bodies. Some of these are in mutually
beneficial relationships with us, in which both the human host and the bacterium benefit, while some of the
relationships are classified as commensalism, a type of relationship in which the bacterium benefits and the human
host is neither benefited nor harmed.

Human gut flora lives in the large intestine and consists of hundreds of species of bacteria and archaea, with
different individuals containing different species mixes. The term “flora,” which is usually associated with plants, is
traditionally used in this context because bacteria were once classified as plants. The primary functions of these
prokaryotes for humans appear to be metabolism of food molecules that we cannot break down, assistance with the
298 13 Diversity of Microbes, Fungi, and Protists

absorption of ions by the colon, synthesis of vitamin K, training of the infant immune system, maintenance of the
adult immune system, maintenance of the epithelium of the large intestine, and formation of a protective barrier
against pathogens.

The surface of the skin is also coated with prokaryotes. The different surfaces of the skin, such as the underarms,
the head, and the hands, provide different habitats for different communities of prokaryotes. Unlike with gut flora,
the possible beneficial roles of skin flora have not been well studied. However, the few studies conducted so far
have identified bacteria that produce antimicrobial compounds as probably responsible for preventing infections by
pathogenic bacteria.

As they would in any ecosystem, the organisms in the microbiome are subject to selection and evolution. Simply to
survive through changes in the human body requires a degree of adaptability and resistance. Because humans and
other animals (such as livestock) ingest more and more antibiotics, the bacteria within our bodies are becoming
resistant to those medicines. Abigail A. Salyers, who provided much of the foundational research on the human
microbiome, focused much of her early work on a type of bacteria (Bacteroides) that could not only become
resistant to antibiotics, but pass on that resistance to surrounding bacteria. Salyers was among the first researchers
to sound the alarm about the dangers of antibiotic resistance and its potential impact on health. Researchers are
actively studying the relationships between various diseases and alterations to the composition of human microbial
flora. Some of this work is being carried out by the Human Microbiome Project, funded in the United States by the
National Institutes of Health.

13.2 Eukaryotic Origins
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the endosymbiotic theory
Explain the origin of mitochondria and chloroplasts

The fossil record and genetic evidence suggest that prokaryotic cells were the first organisms on Earth. These cells
originated approximately 3.5 billion years ago, which was about 1 billion years after Earth’s formation, and were the
only life forms on the planet until eukaryotic cells emerged approximately 2.1 billion years ago. During the
prokaryotic reign, photosynthetic prokaryotes evolved that were capable of applying the energy from sunlight to
synthesize organic materials (like carbohydrates) from carbon dioxide and an electron source (such as hydrogen,
hydrogen sulfide, or water).

Photosynthesis using water as an electron donor consumes carbon dioxide and releases molecular oxygen (O2) as a
byproduct. The functioning of photosynthetic bacteria over millions of years progressively saturated Earth’s water
with oxygen and then oxygenated the atmosphere, which previously contained much greater concentrations of
carbon dioxide and much lower concentrations of oxygen. Older anaerobic prokaryotes of the era could not function
in their new, aerobic environment. Some species perished, while others survived in the remaining anaerobic
environments left on Earth. Still other early prokaryotes evolved mechanisms, such as aerobic respiration, to exploit
the oxygenated atmosphere by using oxygen to store energy contained within organic molecules. Aerobic respiration
is a more efficient way of obtaining energy from organic molecules, which contributed to the success of these
species (as evidenced by the number and diversity of aerobic organisms living on Earth today). The evolution of
aerobic prokaryotes was an important step toward the evolution of the first eukaryote, but several other
distinguishing features had to evolve as well.

Endosymbiosis
The origin of eukaryotic cells was largely a mystery until a revolutionary hypothesis was comprehensively examined
in the 1960s by Lynn Margulis. The endosymbiotic theory states that eukaryotes are a product of one prokaryotic
cell engulfing another, one living within another, and evolving together over time until the separate cells were no
longer recognizable as such. This once-revolutionary hypothesis had immediate persuasiveness and is now widely
accepted, with work progressing on uncovering the steps involved in this evolutionary process as well as the key
players. It has become clear that many nuclear eukaryotic genes and the molecular machinery responsible for
replicating and expressing those genes appear closely related to the Archaea. On the other hand, the metabolic
organelles and the genes responsible for many energy-harvesting processes had their origins in bacteria. Much

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 13.2 Eukaryotic Origins 299

remains to be clarified about how this relationship occurred; this continues to be an exciting field of discovery in
biology. Several endosymbiotic events likely contributed to the origin of the eukaryotic cell.

Mitochondria
Eukaryotic cells may contain anywhere from one to several thousand mitochondria, depending on the cell’s level of
energy consumption. Each mitochondrion measures 1 to 10 micrometers in length and exists in the cell as a moving,
fusing, and dividing oblong spheroid (Figure 13.11). However, mitochondria cannot survive outside the cell. As the
atmosphere was oxygenated by photosynthesis, and as successful aerobic prokaryotes evolved, evidence suggests
that an ancestral cell engulfed and kept alive a free-living, aerobic prokaryote. This gave the host cell the ability to
use oxygen to release energy stored in nutrients. Several lines of evidence support that mitochondria are derived
from this endosymbiotic event. Most mitochondria are shaped like a specific group of bacteria and are surrounded
by two membranes. The mitochondrial inner membrane involves substantial infoldings or cristae that resemble the
textured outer surface of certain bacteria.

FIGURE 13.11 In this transmission electron micrograph of mitochondria in a mammalian lung cell, the cristae, infoldings of the
mitochondrial inner membrane, can be seen in cross-section. (credit: modification of work by Louisa Howard; scale-bar data from Matt
Russell)

Mitochondria divide on their own by a process that resembles binary fission in prokaryotes. Mitochondria have their
own circular DNA chromosome that carries genes similar to those expressed by bacteria. Mitochondria also have
special ribosomes and transfer RNAs that resemble these components in prokaryotes. These features all support
that mitochondria were once free-living prokaryotes.

Chloroplasts
Chloroplasts are one type of plastid, a group of related organelles in plant cells that are involved in the storage of
starches, fats, proteins, and pigments. Chloroplasts contain the green pigment chlorophyll and play a role in
photosynthesis. Genetic and morphological studies suggest that plastids evolved from the endosymbiosis of an
ancestral cell that engulfed a photosynthetic cyanobacterium. Plastids are similar in size and shape to cyanobacteria
and are enveloped by two or more membranes, corresponding to the inner and outer membranes of cyanobacteria.
Like mitochondria, plastids also contain circular genomes and divide by a process reminiscent of prokaryotic cell
division. The chloroplasts of red and green algae exhibit DNA sequences that are closely related to photosynthetic
cyanobacteria, suggesting that red and green algae are direct descendants of this endosymbiotic event.

Mitochondria likely evolved before plastids because all eukaryotes have either functional mitochondria or
mitochondria-like organelles. In contrast, plastids are only found in a subset of eukaryotes, such as terrestrial plants
and algae. One hypothesis of the evolutionary steps leading to the first eukaryote is summarized in Figure 13.12.
300 13 Diversity of Microbes, Fungi, and Protists

FIGURE 13.12 The first eukaryote may have originated from an ancestral prokaryote that had undergone membrane proliferation,
compartmentalization of cellular function (into a nucleus, lysosomes, and an endoplasmic reticulum), and the establishment of
endosymbiotic relationships with an aerobic prokaryote and, in some cases, a photosynthetic prokaryote to form mitochondria and
chloroplasts, respectively.

The exact steps leading to the first eukaryotic cell can only be hypothesized, and some controversy exists regarding
which events actually took place and in what order. Spirochete bacteria have been hypothesized to have given rise
to microtubules, and a flagellated prokaryote may have contributed the raw materials for eukaryotic flagella and
cilia. Other scientists suggest that membrane proliferation and compartmentalization, not endosymbiotic events,
led to the development of mitochondria and plastids. However, the vast majority of studies support the
endosymbiotic hypothesis of eukaryotic evolution.

The early eukaryotes were unicellular like most protists are today, but as eukaryotes became more complex, the
evolution of multicellularity allowed cells to remain small while still exhibiting specialized functions. The ancestors
of today’s multicellular eukaryotes are thought to have evolved about 1.5 billion years ago.

13.3 Protists
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the main characteristics of protists
Describe important pathogenic species of protists
Describe the roles of protists as food sources and as decomposers

FIGURE 13.13 Protists range from the microscopic, single-celled (a) Acanthocystis turfacea and the (b) ciliate Tetrahymena thermophila to
the enormous, multicellular (c) kelps (Chromalveolata) that extend for hundreds of feet in underwater “forests.” (credit a: modification of
work by Yuiuji Tsukii; credit b: modification of work by Richard Robinson, Public Library of Science; credit c: modification of work by Kip
Evans, NOAA; scale-bar data from Matt Russell)

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