Chapter 06 Reproduction at the Cellular Level PDF

Summary

This document provides an overview of reproduction at the cellular level, including the structure and function of genomes and the cell cycle. The chapter also touches on cancer and prokaryotic cell division, offering insight into the mechanisms involved in both unicellular and multicellular organisms.

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CHAPTER 6
Reproduction at the Cellular Level

FIGURE 6.1 A sea urchin begins life as a single cell that (a) divides to form two cells, visible by scanning electron
microscopy. After four rounds of cell division, (b) there are 16 cells, as seen in this SEM image. After many rounds of
cell division, the individual develops into a complex, multicellular organism, as seen in this (c) mature sea urchin.
(credit a: modification of work by Evelyn Spiegel, Louisa Howard; credit b: modification of work by Evelyn Spiegel,
Louisa Howard; credit c: modification of work by Marco Busdraghi; scale-bar data from Matt Russell)

CHAPTER OUTLINE
6.1 The Genome
6.2 The Cell Cycle
6.3 Cancer and the Cell Cycle
6.4 Prokaryotic Cell Division

INTRODUCTION The individual sexually reproducing organism—including humans—begins life as
a fertilized egg, or zygote. Trillions of cell divisions subsequently occur in a controlled manner to
produce a complex, multicellular human. In other words, that original single cell was the ancestor
of every other cell in the body. Once a human individual is fully grown, cell reproduction is still
necessary to repair or regenerate tissues. For example, new blood and skin cells are constantly
being produced. All multicellular organisms use cell division for growth, and in most cases, the
maintenance and repair of cells and tissues. Single-celled organisms use cell division as their
method of reproduction.

6.1 The Genome
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the prokaryotic and eukaryotic genome
Distinguish between chromosomes, genes, and traits

The continuity of life from one cell to another has its foundation in the reproduction of cells by way
of the cell cycle. The cell cycle is an orderly sequence of events in the life of a cell from the division
of a single parent cell to produce two new daughter cells, to the subsequent division of those
daughter cells. The mechanisms involved in the cell cycle are highly conserved across eukaryotes.
Organisms as diverse as protists, plants, and animals employ similar steps.

Genomic DNA
Before discussing the steps a cell undertakes to replicate, a deeper understanding of the structure
and function of a cell’s genetic information is necessary. A cell’s complete complement of DNA is
called its genome. In prokaryotes, the genome is composed of a single, double-stranded DNA
134 6 Reproduction at the Cellular Level

molecule in the form of a loop or circle. The region in the cell containing this genetic material is
called a nucleoid. Some prokaryotes also have smaller loops of DNA called plasmids that are not
essential for normal growth.

In eukaryotes, the genome comprises several double-stranded, linear DNA molecules (Figure 6.2)
bound with proteins to form complexes called chromosomes. Each species of eukaryote has a
characteristic number of chromosomes in the nuclei of its cells. Human body cells (somatic cells)
have 46 chromosomes. A somatic cell contains two matched sets of chromosomes, a
configuration known as diploid. The letter n is used to represent a single set of chromosomes;
therefore a diploid organism is designated 2n. Human cells that contain one set of 23
chromosomes are called gametes, or sex cells; these eggs and sperm are designated n, or
haploid.

FIGURE 6.2 There are 23 pairs of homologous chromosomes in a female human somatic cell. These chromosomes
are viewed within the nucleus (top), removed from a cell in mitosis (right), and arranged according to length (left) in an
arrangement called a karyotype. In this image, the chromosomes were exposed to fluorescent stains to distinguish
them. (credit: “718 Bot”/Wikimedia Commons, National Human Genome Research)

The matched pairs of chromosomes in a diploid organism are called homologous chromosomes.
Homologous chromosomes are the same length and have specific nucleotide segments called
genes in exactly the same location, or locus. Genes, the functional units of chromosomes,
determine specific characteristics by coding for specific proteins. Traits are the different forms of a
characteristic. For example, the shape of earlobes is a characteristic with traits of free or attached.

Each copy of the homologous pair of chromosomes originates from a different parent; therefore,
the copies of each of the genes themselves may not be identical. The variation of individuals
within a species is caused by the specific combination of the genes inherited from both parents.
For example, there are three possible gene sequences on the human chromosome that codes for
blood type: sequence A, sequence B, and sequence O. Because all diploid human cells have two
copies of the chromosome that determines blood type, the blood type (the trait) is determined by
which two versions of the marker gene are inherited. It is possible to have two copies of the same
gene sequence, one on each homologous chromosome (for example, AA, BB, or OO), or two
different sequences, such as AB.

Minor variations in traits such as those for blood type, eye color, and height contribute to the
natural variation found within a species. The sex chromosomes, X and Y, are the single exception
to the rule of homologous chromosomes; other than a small amount of homology that is necessary
to reliably produce gametes, the genes found on the X and Y chromosomes are not the same.

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 6.2 The Cell Cycle 135

6.2 The Cell Cycle
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the three stages of interphase
Discuss the behavior of chromosomes during mitosis and how the cytoplasmic content divides during
cytokinesis
Define the quiescent G0 phase
Explain how the three internal control checkpoints occur at the end of G1, at the G2–M transition, and
during metaphase

The cell cycle is an ordered series of events involving cell growth and cell division that produces two new daughter
cells. Cells on the path to cell division proceed through a series of precisely timed and carefully regulated stages of
growth, DNA replication, and division that produce two genetically identical cells. The cell cycle has two major
phases: interphase and the mitotic phase (Figure 6.3). During interphase, the cell grows and DNA is replicated.
During the mitotic phase, the replicated DNA and cytoplasmic contents are separated and the cell divides. Watch
this video about the cell cycle: http://openstax.org/l/biocellcyc (http://openstaxcollege.org/l/biocellcyc)

FIGURE 6.3 A cell moves through a series of phases in an orderly manner. During interphase, G1 involves cell growth and protein synthesis,
the S phase involves DNA replication and the replication of the centrosome, and G2 involves further growth and protein synthesis. The
mitotic phase follows interphase. Mitosis is nuclear division during which duplicated chromosomes are segregated and distributed into
daughter nuclei. Usually the cell will divide after mitosis in a process called cytokinesis in which the cytoplasm is divided and two daughter
cells are formed.

Interphase
During interphase, the cell undergoes normal processes while also preparing for cell division. For a cell to move from
interphase to the mitotic phase, many internal and external conditions must be met. The three stages of interphase
are called G1, S, and G2.

G1 Phase
The first stage of interphase is called the G1 phase, or first gap, because little change is visible. However, during the
G1 stage, the cell is quite active at the biochemical level. The cell is accumulating the building blocks of
chromosomal DNA and the associated proteins, as well as accumulating enough energy reserves to complete the
task of replicating each chromosome in the nucleus.
136 6 Reproduction at the Cellular Level

S Phase
Throughout interphase, nuclear DNA remains in a semi-condensed chromatin configuration. In the S phase
(synthesis phase), DNA replication results in the formation of two identical copies of each chromosome—sister
chromatids—that are firmly attached at the centromere region. At this stage, each chromosome is made of two sister
chromatids and is a duplicated chromosome. The centrosome is duplicated during the S phase. The two
centrosomes will give rise to the mitotic spindle, the apparatus that orchestrates the movement of chromosomes
during mitosis. The centrosome consists of a pair of rod-like centrioles at right angles to each other. Centrioles help
organize cell division. Centrioles are not present in the centrosomes of many eukaryotic species, such as plants and
most fungi.

G2 Phase
In the G2 phase, or second gap, the cell replenishes its energy stores and synthesizes the proteins necessary for
chromosome manipulation. Some cell organelles are duplicated, and the cytoskeleton is dismantled to provide
resources for the mitotic spindle. There may be additional cell growth during G2. The final preparations for the
mitotic phase must be completed before the cell is able to enter the first stage of mitosis.

The Mitotic Phase
To make two daughter cells, the contents of the nucleus and the cytoplasm must be divided. The mitotic phase is a
multistep process during which the duplicated chromosomes are aligned, separated, and moved to opposite poles
of the cell, and then the cell is divided into two new identical daughter cells. The first portion of the mitotic phase,
mitosis, is composed of five stages, which accomplish nuclear division. The second portion of the mitotic phase,
called cytokinesis, is the physical separation of the cytoplasmic components into two daughter cells.

Mitosis
Mitosis is divided into a series of phases—prophase, prometaphase, metaphase, anaphase, and telophase—that
result in the division of the cell nucleus (Figure 6.4).

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 6.2 The Cell Cycle 137

VISUAL CONNECTION

FIGURE 6.4 Animal cell mitosis is divided into five stages—prophase, prometaphase, metaphase, anaphase, and telophase—visualized here
by light microscopy with fluorescence. Mitosis is usually accompanied by cytokinesis, shown here by a transmission electron microscope.
(credit "diagrams": modification of work by Mariana Ruiz Villareal; credit "mitosis micrographs": modification of work by Roy van Heesbeen;
credit "cytokinesis micrograph": modification of work by the Wadsworth Center, NY State Department of Health; donated to the Wikimedia
foundation; scale-bar data from Matt Russell)

Which of the following is the correct order of events in mitosis?

a. Sister chromatids line up at the metaphase plate. The kinetochore becomes attached to the mitotic spindle. The
nucleus re-forms and the cell divides. The sister chromatids separate.
b. The kinetochore becomes attached to the mitotic spindle. The sister chromatids separate. Sister chromatids
line up at the metaphase plate. The nucleus re-forms and the cell divides.
c. The kinetochore becomes attached to metaphase plate. Sister chromatids line up at the metaphase plate. The
kinetochore breaks down and the sister chromatids separate. The nucleus re-forms and the cell divides.
d. The kinetochore becomes attached to the mitotic spindle. Sister chromatids line up at the metaphase plate. The
kinetochore breaks apart and the sister chromatids separate. The nucleus re-forms and the cell divides.

During prophase, the “first phase,” several events must occur to provide access to the chromosomes in the nucleus.
The nuclear envelope starts to break into small vesicles, and the Golgi apparatus and endoplasmic reticulum
fragment and disperse to the periphery of the cell. The nucleolus disappears. The centrosomes begin to move to
opposite poles of the cell. The microtubules that form the basis of the mitotic spindle extend between the
centrosomes, pushing them farther apart as the microtubule fibers lengthen. The sister chromatids begin to coil
more tightly and become visible under a light microscope.

During prometaphase, many processes that were begun in prophase continue to advance and culminate in the
formation of a connection between the chromosomes and cytoskeleton. The remnants of the nuclear envelope
disappear. The mitotic spindle continues to develop as more microtubules assemble and stretch across the length of
138 6 Reproduction at the Cellular Level

the former nuclear area. Chromosomes become more condensed and visually discrete. Each sister chromatid
attaches to spindle microtubules at the centromere via a protein complex called the kinetochore.

During metaphase, all of the chromosomes are aligned in a plane called the metaphase plate, or the equatorial
plane, midway between the two poles of the cell. The sister chromatids are still tightly attached to each other. At
this time, the chromosomes are maximally condensed.

During anaphase, the sister chromatids at the equatorial plane are split apart at the centromere. Each chromatid,
now called a chromosome, is pulled rapidly toward the centrosome to which its microtubule was attached. The cell
becomes visibly elongated as the non-kinetochore microtubules slide against each other at the metaphase plate
where they overlap.

During telophase, all of the events that set up the duplicated chromosomes for mitosis during the first three phases
are reversed. The chromosomes reach the opposite poles and begin to decondense (unravel). The mitotic spindles
are broken down into monomers that will be used to assemble cytoskeleton components for each daughter cell.
Nuclear envelopes form around chromosomes.

LINK TO LEARNING
This page of movies (http://openstax.org/l/divisn_newtcell) illustrates different aspects of mitosis. Watch the movie
entitled “DIC microscopy of cell division in a newt lung cell” and identify the phases of mitosis.

Cytokinesis
Cytokinesis is the second part of the mitotic phase during which cell division is completed by the physical
separation of the cytoplasmic components into two daughter cells. Although the stages of mitosis are similar for
most eukaryotes, the process of cytokinesis is quite different for eukaryotes that have cell walls, such as plant cells.

In cells such as animal cells that lack cell walls, cytokinesis begins following the onset of anaphase. A contractile
ring composed of actin filaments forms just inside the plasma membrane at the former metaphase plate. The actin
filaments pull the equator of the cell inward, forming a fissure. This fissure, or “crack,” is called the cleavage furrow.
The furrow deepens as the actin ring contracts, and eventually the membrane and cell are cleaved in two (Figure
6.5).

In plant cells, a cleavage furrow is not possible because of the rigid cell walls surrounding the plasma membrane. A
new cell wall must form between the daughter cells. During interphase, the Golgi apparatus accumulates enzymes,
structural proteins, and glucose molecules prior to breaking up into vesicles and dispersing throughout the dividing
cell. During telophase, these Golgi vesicles move on microtubules to collect at the metaphase plate. There, the
vesicles fuse from the center toward the cell walls; this structure is called a cell plate. As more vesicles fuse, the
cell plate enlarges until it merges with the cell wall at the periphery of the cell. Enzymes use the glucose that has
accumulated between the membrane layers to build a new cell wall of cellulose. The Golgi membranes become the
plasma membrane on either side of the new cell wall (Figure 6.5).

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 6.2 The Cell Cycle 139

FIGURE 6.5 In part (a), a cleavage furrow forms at the former metaphase plate in the animal cell. The plasma membrane is drawn in by a
ring of actin fibers contracting just inside the membrane. The cleavage furrow deepens until the cells are pinched in two. In part (b), Golgi
vesicles coalesce at the former metaphase plate in a plant cell. The vesicles fuse and form the cell plate. The cell plate grows from the
center toward the cell walls. New cell walls are made from the vesicle contents.

G0 Phase
Not all cells adhere to the classic cell-cycle pattern in which a newly formed daughter cell immediately enters
interphase, closely followed by the mitotic phase. Cells in the G0 phase are not actively preparing to divide. The cell
is in a quiescent (inactive) stage, having exited the cell cycle. Some cells enter G0 temporarily until an external signal
triggers the onset of G1. Other cells that never or rarely divide, such as mature cardiac muscle and nerve cells,
remain in G0 permanently (Figure 6.6).

FIGURE 6.6 Cells that are not actively preparing to divide enter an alternate phase called G0. In some cases, this is a temporary condition
until triggered to enter G1. In other cases, the cell will remain in G0 permanently.

Control of the Cell Cycle
The length of the cell cycle is highly variable even within the cells of an individual organism. In humans, the
frequency of cell turnover ranges from a few hours in early embryonic development to an average of two to five days
140 6 Reproduction at the Cellular Level

for epithelial cells, or to an entire human lifetime spent in G0 by specialized cells such as cortical neurons or cardiac
muscle cells. There is also variation in the time that a cell spends in each phase of the cell cycle. When fast-dividing
mammalian cells are grown in culture (outside the body under optimal growing conditions), the length of the cycle is
approximately 24 hours. In rapidly dividing human cells with a 24-hour cell cycle, the G1 phase lasts approximately
11 hours. The timing of events in the cell cycle is controlled by mechanisms that are both internal and external to
the cell.

Regulation at Internal Checkpoints
It is essential that daughter cells be exact duplicates of the parent cell. Mistakes in the duplication or distribution of
the chromosomes lead to mutations that may be passed forward to every new cell produced from the abnormal cell.
To prevent a compromised cell from continuing to divide, there are internal control mechanisms that operate at
three main cell cycle checkpoints at which the cell cycle can be stopped until conditions are favorable. These
checkpoints occur near the end of G1, at the G2–M transition, and during metaphase (Figure 6.7).

FIGURE 6.7 The cell cycle is controlled at three checkpoints. Integrity of the DNA is assessed at the G1 checkpoint. Proper chromosome
duplication is assessed at the G2 checkpoint. Attachment of each kinetochore to a spindle fiber is assessed at the M checkpoint.

The G1 Checkpoint
The G1 checkpoint determines whether all conditions are favorable for cell division to proceed. The G1 checkpoint,
also called the restriction point, is the point at which the cell irreversibly commits to the cell-division process. In
addition to adequate reserves and cell size, there is a check for damage to the genomic DNA at the G1 checkpoint. A
cell that does not meet all the requirements will not be released into the S phase.

The G2 Checkpoint
The G2 checkpoint bars the entry to the mitotic phase if certain conditions are not met. As in the G1 checkpoint, cell
size and protein reserves are assessed. However, the most important role of the G2 checkpoint is to ensure that all
of the chromosomes have been replicated and that the replicated DNA is not damaged.

The M Checkpoint
The M checkpoint occurs near the end of the metaphase stage of mitosis. The M checkpoint is also known as the
spindle checkpoint because it determines if all the sister chromatids are correctly attached to the spindle
microtubules. Because the separation of the sister chromatids during anaphase is an irreversible step, the cycle will
not proceed until the kinetochores of each pair of sister chromatids are firmly anchored to spindle fibers arising from
opposite poles of the cell.

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 6.3 Cancer and the Cell Cycle 141

LINK TO LEARNING
Watch what occurs at the G1, G2, and M checkpoints by visiting this animation (https://www.youtube.com/
watch?v=f-ldPgEfAHI) of the cell cycle.

6.3 Cancer and the Cell Cycle
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Explain how cancer is caused by uncontrolled cell division
Understand how proto-oncogenes are normal cell genes that, when mutated, become oncogenes
Describe how tumor suppressors function to stop the cell cycle until certain events are completed
Explain how mutant tumor suppressors cause cancer

Cancer is a collective name for many different diseases caused by a common mechanism: uncontrolled cell division.
Despite the redundancy and overlapping levels of cell-cycle control, errors occur. One of the critical processes
monitored by the cell-cycle checkpoint surveillance mechanism is the proper replication of DNA during the S phase.
Even when all of the cell-cycle controls are fully functional, a small percentage of replication errors (mutations) will
be passed on to the daughter cells. If one of these changes to the DNA nucleotide sequence occurs within a gene, a
gene mutation results. All cancers begin when a gene mutation gives rise to a faulty protein that participates in the
process of cell reproduction. The change in the cell that results from the malformed protein may be minor. Even
minor mistakes, however, may allow subsequent mistakes to occur more readily. Over and over, small, uncorrected
errors are passed from parent cell to daughter cells and accumulate as each generation of cells produces more non-
functional proteins from uncorrected DNA damage. Eventually, the pace of the cell cycle speeds up as the
effectiveness of the control and repair mechanisms decreases. Uncontrolled growth of the mutated cells outpaces
the growth of normal cells in the area, and a tumor can result.

Proto-oncogenes
The genes that code for the positive cell-cycle regulators are called proto-oncogenes. Proto-oncogenes are normal
genes that, when mutated, become oncogenes—genes that cause a cell to become cancerous. Consider what might
happen to the cell cycle in a cell with a recently acquired oncogene. In most instances, the alteration of the DNA
sequence will result in a less functional (or non-functional) protein. The result is detrimental to the cell and will
likely prevent the cell from completing the cell cycle; however, the organism is not harmed because the mutation
will not be carried forward. If a cell cannot reproduce, the mutation is not propagated and the damage is minimal.
Occasionally, however, a gene mutation causes a change that increases the activity of a positive regulator. For
example, a mutation that allows Cdk, a protein involved in cell-cycle regulation, to be activated before it should be
could push the cell cycle past a checkpoint before all of the required conditions are met. If the resulting daughter
cells are too damaged to undertake further cell divisions, the mutation would not be propagated and no harm comes
to the organism. However, if the atypical daughter cells are able to divide further, the subsequent generation of cells
will likely accumulate even more mutations, some possibly in additional genes that regulate the cell cycle.

The Cdk example is only one of many genes that are considered proto-oncogenes. In addition to the cell-cycle
regulatory proteins, any protein that influences the cycle can be altered in such a way as to override cell-cycle
checkpoints. Once a proto-oncogene has been altered such that there is an increase in the rate of the cell cycle, it is
then called an oncogene.

Tumor Suppressor Genes
Like proto-oncogenes, many of the negative cell-cycle regulatory proteins were discovered in cells that had become
cancerous. Tumor suppressor genes are genes that code for the negative regulator proteins, the type of regulator
that—when activated—can prevent the cell from undergoing uncontrolled division. The collective function of the
best-understood tumor suppressor gene proteins, retinoblastoma protein (RB1), p53, and p21, is to put up a
roadblock to cell-cycle progress until certain events are completed. A cell that carries a mutated form of a negative
regulator might not be able to halt the cell cycle if there is a problem.
142 6 Reproduction at the Cellular Level

Mutated p53 genes have been identified in more than half of all human tumor cells. This discovery is not surprising
in light of the multiple roles that the p53 protein plays at the G1 checkpoint. The p53 protein activates other genes
whose products halt the cell cycle (allowing time for DNA repair), activates genes whose products participate in DNA
repair, or activates genes that initiate cell death when DNA damage cannot be repaired. A damaged p53 gene can
result in the cell behaving as if there are no mutations (Figure 6.8). This allows cells to divide, propagating the
mutation in daughter cells and allowing the accumulation of new mutations. In addition, the damaged version of
p53 found in cancer cells cannot trigger cell death.

FIGURE 6.8 (a) The role of p53 is to monitor DNA. If damage is detected, p53 triggers repair mechanisms. If repairs are unsuccessful, p53
signals apoptosis. (b) A cell with an abnormal p53 protein cannot repair damaged DNA and cannot signal apoptosis. Cells with abnormal
p53 can become cancerous. (credit: modification of work by Thierry Soussi)

LINK TO LEARNING
Go to this website (http://openstax.org/l/cancer2) to watch an animation of how cancer results from errors in the
cell cycle.

Since cancer is defined by uncontrolled cell growth, cancer treatments aim to interrupt the cell cycle. One of the first
treatments involved folic acid, a substance discovered by Lucy Wills while she was researching pregnancy anemia
(blood disorder). Several scientists showed that inhibiting folic acid uptake by tumor cells resulted in reduced
growth. Jane C. Wright identified the drug now known as methotrexate as an effective treatment for breast and skin
cancers. The same drug was applied to other cancers, such as placental, uterine, and lung cancers. Methotrexate is
known as the first chemotherapy drug, and Wright's additional work to establish dosage protocols and
sequences—both to maximize the effect and manage side effects—laid the foundation for contemporary
chemotherapy treatments.

6.4 Prokaryotic Cell Division
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the process of binary fission in prokaryotes
Explain how FtsZ and tubulin proteins are examples of homology

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 6.4 Prokaryotic Cell Division 143

Prokaryotes such as bacteria propagate by binary fission. For unicellular organisms, cell division is the only method
to produce new individuals. In both prokaryotic and eukaryotic cells, the outcome of cell reproduction is a pair of
daughter cells that are genetically identical to the parent cell. In unicellular organisms, daughter cells are
individuals.

To achieve the outcome of identical daughter cells, some steps are essential. The genomic DNA must be replicated
and then allocated into the daughter cells; the cytoplasmic contents must also be divided to give both new cells the
machinery to sustain life. In bacterial cells, the genome consists of a single, circular DNA chromosome; therefore,
the process of cell division is simplified. Mitosis is unnecessary because there is no nucleus or multiple
chromosomes. This type of cell division is called binary fission.

Binary Fission
The cell division process of prokaryotes, called binary fission, is a less complicated and much quicker process than
cell division in eukaryotes. Because of the speed of bacterial cell division, populations of bacteria can grow very
rapidly. The single, circular DNA chromosome of bacteria is not enclosed in a nucleus, but instead occupies a
specific location, the nucleoid, within the cell. As in eukaryotes, the DNA of the nucleoid is associated with proteins
that aid in packaging the molecule into a compact size. The packing proteins of bacteria are, however, related to
some of the proteins involved in the chromosome compaction of eukaryotes.

The starting point of replication, the origin, is close to the binding site of the chromosome to the plasma membrane
(Figure 6.9). Replication of the DNA is bidirectional—moving away from the origin on both strands of the DNA loop
simultaneously. As the new double strands are formed, each origin point moves away from the cell-wall attachment
toward opposite ends of the cell. As the cell elongates, the growing membrane aids in the transport of the
chromosomes. After the chromosomes have cleared the midpoint of the elongated cell, cytoplasmic separation
begins. A septum is formed between the nucleoids from the periphery toward the center of the cell. When the new
cell walls are in place, the daughter cells separate.
144 6 Reproduction at the Cellular Level

FIGURE 6.9 The binary fission of a bacterium is outlined in five steps. (credit: modification of work by “Mcstrother”/Wikimedia Commons)

EVOLUTION CONNECTION

Mitotic Spindle Apparatus
The precise timing and formation of the mitotic spindle is critical to the success of eukaryotic cell division.
Prokaryotic cells, on the other hand, do not undergo mitosis and therefore have no need for a mitotic spindle.
However, the FtsZ protein that plays such a vital role in prokaryotic cytokinesis is structurally and functionally very
similar to tubulin, the building block of the microtubules that make up the mitotic spindle fibers that are necessary
for eukaryotes. The formation of a ring composed of repeating units of a protein called FtsZ directs the partition
between the nucleoids in prokaryotes. Formation of the FtsZ ring triggers the accumulation of other proteins that
work together to recruit new membrane and cell-wall materials to the site. FtsZ proteins can form filaments, rings,
and other three-dimensional structures resembling the way tubulin forms microtubules, centrioles, and various
cytoskeleton components. In addition, both FtsZ and tubulin employ the same energy source, GTP (guanosine

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 6.4 Prokaryotic Cell Division 145

triphosphate), to rapidly assemble and disassemble complex structures.

FtsZ and tubulin are an example of homology, structures derived from the same evolutionary origins. In this
example, FtsZ is presumed to be similar to the ancestor protein to both the modern FtsZ and tubulin. While both
proteins are found in extant organisms, tubulin function has evolved and diversified tremendously since the
evolution from its FtsZ-like prokaryotic origin. A survey of cell-division machinery in present-day unicellular
eukaryotes reveals crucial intermediary steps to the complex mitotic machinery of multicellular eukaryotes (Table
6.1).

Mitotic Spindle Evolution

Separation of
Structure of genetic
Division of nuclear material daughter
material
cells

There is no nucleus. FtsZ proteins
The single, circular Occurs through binary fission. As the chromosome is assemble into
Prokaryotes chromosome exists in replicated, the two copies move to opposite ends of a ring that
a region of cytoplasm the cell by an unknown mechanism. pinches the
called the nucleoid. cell in two.

Microfilaments
Chromosomes attach to the nuclear envelope, which form a
Some Linear chromosomes remains intact. The mitotic spindle passes through cleavage
protists exist in the nucleus. the envelope and elongates the cell. No centrioles furrow that
exist. pinches the
cell in two.

Microfilaments
A mitotic spindle forms from the centrioles and
form a
passes through the nuclear membrane, which
Other Linear chromosomes cleavage
remains intact. Chromosomes attach to the mitotic
protists exist in the nucleus. furrow that
spindle. The mitotic spindle separates the
pinches the
chromosomes and elongates the cell.
cell in two.

Microfilaments
A mitotic spindle forms from the centrioles. The form a
Animal Linear chromosomes nuclear envelope dissolves. Chromosomes attach to cleavage
cells exist in the nucleus. the mitotic spindle, which separates them and furrow that
elongates the cell. pinches the
cell in two.

TABLE 6.1 The mitotic spindle fibers of eukaryotes are composed of microtubules. Microtubules are polymers of the protein tubulin. The
FtsZ protein active in prokaryote cell division is very similar to tubulin in the structures it can form and its energy source. Single-celled
eukaryotes (such as yeast) display possible intermediary steps between FtsZ activity during binary fission in prokaryotes and the mitotic
spindle in multicellular eukaryotes, during which the nucleus breaks down and is reformed.