Cellular Reproduction
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Transcript Cellular Reproduction
Chapter 8
Cellular Reproduction: Cells from Cells
PowerPoint® Lectures for
Campbell Essential Biology, Fifth Edition, and
Campbell Essential Biology with Physiology,
Fourth Edition
– Eric J. Simon, Jean L. Dickey, and Jane B. Reece
Lectures by Edward J. Zalisko
© 2013 Pearson Education, Inc.
Biology and Society:
Virgin Birth of a Dragon
• In 2002, zookeepers at the Chester Zoo were
surprised to discover that their Komodo Dragon
laid eggs.
– The female dragon had not been in the company of
a male.
– The eggs developed without fertilization, in a
process called parthenogenesis.
– DNA analysis confirmed that her offspring had
genes only from her.
© 2013 Pearson Education, Inc.
Biology and Society:
Virgin Birth of a Dragon
• A second European Komodo dragon is now known
to have reproduced
– asexually, via parthenogenesis, and
– sexually.
© 2013 Pearson Education, Inc.
Figure 8.0
WHAT CELL REPRODUCTION
ACCOMPLISHES
• Reproduction
– may result in the birth of new organisms but
– more commonly involves the production of new
cells.
• When a cell undergoes reproduction, or cell
division, two “daughter” cells are produced that
are genetically identical
– to each other and
– to the “parent” cell.
© 2013 Pearson Education, Inc.
WHAT CELL REPRODUCTION
ACCOMPLISHES
• Before a parent cell splits into two, it duplicates its
chromosomes, the structures that contain most
of the cell’s DNA.
• During cell division, each daughter cell receives
one identical set of chromosomes from the lone,
original parent cell.
© 2013 Pearson Education, Inc.
WHAT CELL REPRODUCTION
ACCOMPLISHES
• Cell division plays important roles in the lives of
organisms.
• Cell division
– replaces damaged or lost cells,
– permits growth, and
– allows for reproduction.
© 2013 Pearson Education, Inc.
Figure 8.1aa
LM
Cell Replacement
Human kidney cell
Figure 8.1ab
Colorized SEM
Growth via Cell Division
Early human embryo
WHAT CELL REPRODUCTION
ACCOMPLISHES
• In asexual reproduction,
– single-celled organisms reproduce by simple cell
division and
– there is no fertilization of an egg by a sperm.
• Some multicellular organisms, such as sea stars,
can grow new individuals from fragmented pieces.
• Growing a new plant from a clipping is another
example of asexual reproduction.
© 2013 Pearson Education, Inc.
Figure 8.1ba
LM
Asexual Reproduction
Reproduction of an amoeba
Figure 8.1bb
Asexual Reproduction
Regeneration of a sea star
Figure 8.1bc
Asexual Reproduction
Reproduction of an African
violet from a clipping
WHAT CELL REPRODUCTION
ACCOMPLISHES
• In asexual reproduction, the lone parent and its
offspring have identical genes.
• Mitosis is the type of cell division responsible for
– asexual reproduction and
– growth and maintenance of multicellular
organisms.
© 2013 Pearson Education, Inc.
WHAT CELL REPRODUCTION
ACCOMPLISHES
• Sexual reproduction requires fertilization of an
egg by a sperm using a special type of cell division
called meiosis.
• Thus, sexually reproducing organisms use
– meiosis for reproduction and
– mitosis for growth and maintenance.
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THE CELL CYCLE AND MITOSIS
• In a eukaryotic cell,
– most genes are located on chromosomes in the
cell nucleus and
– a few genes are found in DNA in mitochondria and
chloroplasts.
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Eukaryotic Chromosomes
• Each eukaryotic chromosome contains one very
long DNA molecule, typically bearing thousands of
genes.
• The number of chromosomes in a eukaryotic cell
depends on the species.
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Figure 8.2
Species
Indian muntjac deer
Koala
Opossum
Giraffe
Mouse
Human
Duck-billed platypus
Buffalo
Dog
Red viscacha
rat
Number of chromosomes in body cells
6
16
22
30
40
46
54
60
78
102
Eukaryotic Chromosomes
• Chromosomes are
– made of chromatin, fibers composed of roughly
equal amounts of DNA and protein molecules and
– not visible in a cell until cell division occurs.
© 2013 Pearson Education, Inc.
LM
Figure 8.3
Chromosomes
Eukaryotic Chromosomes
• The DNA in a cell is packed into an elaborate,
multilevel system of coiling and folding.
• Histones are proteins used to package DNA in
eukaryotes.
• Nucleosomes consist of DNA wound around
histone molecules.
© 2013 Pearson Education, Inc.
Figure 8.4
DNA double helix
Histones
TEM
“Beads
on a
string”
Nucleosome
Tight helical fiber
Duplicated
chromosomes
(sister
chromatids)
TEM
Thick supercoil
Centromere
Figure 8.4a
DNA double helix
Histones
TEM
“Beads
on a
string”
Nucleosome
Figure 8.4b
Tight helical fiber
Duplicated
chromosomes
(sister
chromatids)
TEM
Thick supercoil
Centromere
Eukaryotic Chromosomes
• Before a cell divides, it duplicates all of its
chromosomes, resulting in two copies called sister
chromatids containing identical genes.
• Two sister chromatids are joined together tightly at
a narrow “waist” called the centromere.
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Eukaryotic Chromosomes
• When the cell divides, the sister chromatids of a
duplicated chromosome separate from each other.
• Once separated, each chromatid is
– considered a full-fledged chromosome and
– identical to the original chromosome.
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Figure 8.5
Chromosome
duplication
Sister
chromatids
Chromosome
distribution to
daughter cells
The Cell Cycle
• A cell cycle is the ordered sequence of events that
extend
– from the time a cell is first formed from a dividing
parent cell
– to its own division into two cells.
• The cell cycle consists of two distinct phases:
1. interphase and
2. the mitotic phase.
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Figure 8.6a
S phase
(DNA synthesis; chromosome duplication)
Interphase: metabolism and
growth (90% of time)
G1
Mitotic
(M) phase:
cell division
(10% of time)
G2
The Cell Cycle
• Most of a cell cycle is spent in interphase.
• During interphase, a cell
– performs its normal functions,
– doubles everything in its cytoplasm, and
– grows in size.
© 2013 Pearson Education, Inc.
https://www.youtube.com/watch?v=L0kenzoeOM Mitosis (10.47)
https://www.youtube.com/watch?v=gwcwSZI
fKlM Mitosis (7.41)
The Cell Cycle
• The mitotic (M) phase includes two overlapping
processes:
1. mitosis, in which the nucleus and its contents
divide evenly into two daughter nuclei and
2. cytokinesis, in which the cytoplasm is divided in
two.
© 2013 Pearson Education, Inc.
Mitosis and Cytokinesis
• During mitosis the mitotic spindle, a footballshaped structure of microtubules, guides the
separation of two sets of daughter chromosomes.
• Spindle microtubules grow from structures within
the cytoplasm called centrosomes.
© 2013 Pearson Education, Inc.
Mitosis and Cytokinesis
• Mitosis consists of four distinct phases:
1. Prophase
© 2013 Pearson Education, Inc.
Figure 8.7a
INTERPHASE
Centrosomes
(with centriole
pairs)
Chromatin
PROPHASE
Early mitotic
spindle
Centrosome
Fragments of
nuclear envelope
Centromere
Nuclear
envelope
Plasma
membrane
Chromosome
(two sister chromatids)
Spindle microtubules
Mitosis and Cytokinesis
1. Prophase
2. Metaphase
© 2013 Pearson Education, Inc.
Figure 8.7b
METAPHASE
ANAPHASE
TELOPHASE AND CYTOKINESIS
Nuclear
envelope
forming
Spindle
Daughter
chromosomes
Cleavage
furrow
Mitosis and Cytokinesis
1. Prophase
2. Metaphase
3. Anaphase
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Figure 8.7b
METAPHASE
ANAPHASE
TELOPHASE AND CYTOKINESIS
Nuclear
envelope
forming
Spindle
Daughter
chromosomes
Cleavage
furrow
Mitosis and Cytokinesis
1. Prophase
2. Metaphase
3. Anaphase
4. Telophase
© 2013 Pearson Education, Inc.
Figure 8.7ba
METAPHASE
ANAPHASE
TELOPHASE AND CYTOKINESIS
Nuclear
envelope
forming
Spindle
Daughter
chromosomes
Cleavage
furrow
Figure 8.7bd
TELOPHASE AND
CYTOKINESIS
Mitosis and Cytokinesis
• Cytokinesis usually
– begins during telophase,
– divides the cytoplasm, and
– is different in plant and animal cells.
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Mitosis and Cytokinesis
• In animal cells, cytokinesis
– is known as cleavage and
– begins with the appearance of a cleavage furrow,
an indentation at the equator of the cell.
© 2013 Pearson Education, Inc.
SEM
Figure 8.8a
Cleavage
furrow
Cleavage furrow
Contracting ring of
microfilaments
Daughter cells
Figure 8.8aa
Cleavage furrow
Contracting ring of
microfilaments
Daughter cells
SEM
Figure 8.8ab
Cleavage
furrow
Mitosis and Cytokinesis
• In plant cells, cytokinesis begins when vesicles
containing cell wall material collect at the middle of
the cell and then fuse, forming a membranous disk
called the cell plate.
© 2013 Pearson Education, Inc.
Figure 8.8b
Daughter nucleus
LM
Wall of parent cell
Cell plate
forming
Cell wall
Vesicles containing
cell wall material
Cell plate
New cell wall
Daughter cells
Figure 8.8ba
Daughter nucleus
LM
Wall of parent cell
Cell plate
forming
Figure 8.8bb
Cell wall
Vesicles containing
cell wall material
Cell plate
New cell wall
Daughter cells
Cancer Cells: Growing Out of Control
• Normal plant and animal cells have a cell cycle
control system that consists of specialized
proteins, which send “stop” and “go-ahead” signals
at certain key points during the cell cycle.
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What Is Cancer?
• Cancer is a disease of the cell cycle.
• Cancer cells do not respond normally to the cell
cycle control system.
• Cancer cells can form tumors, abnormally growing
masses of body cells.
• If the abnormal cells remain at the original site, the
lump is called a benign tumor.
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What Is Cancer?
• The spread of cancer cells beyond their original
site of origin is metastasis.
• Malignant tumors can
– spread to other parts of the body and
– interrupt normal body functions.
• A person with a malignant tumor is said to have
cancer.
© 2013 Pearson Education, Inc.
Figure 8.9
Lymph
vessels
Tumor
Blood
vessel
Glandular
tissue
A tumor grows
from a single
cancer cell.
Cancer cells invade
neighboring tissue.
Metastasis: Cancer
cells spread through
lymph and blood
vessels to other parts
of the body.
Cancer Treatment
• Cancer treatment can involve
– radiation therapy, which damages DNA and
disrupts cell division, and
– chemotherapy, the use of drugs to disrupt cell
division.
© 2013 Pearson Education, Inc.
Cancer Prevention and Survival
• Certain behaviors can decrease the risk of cancer:
– not smoking,
– exercising adequately,
– avoiding exposure to the sun,
– eating a high-fiber, low-fat diet,
– performing self-exams, and
– regularly visiting a doctor to identify tumors early.
© 2013 Pearson Education, Inc.
MEIOSIS, THE BASIS OF SEXUAL
REPRODUCTION
• Sexual reproduction
– depends on meiosis and fertilization and
– produces offspring that contain a unique
combination of genes from the parents.
© 2013 Pearson Education, Inc.
Figure 8.10
https://www.youtube.com/watch?v=16enC385R
0w
Meiosis (11.42)
https://www.youtube.com/watch?v=qCLmR9
-YY7o Meiosis (11.42)
Homologous Chromosomes
• Different individuals of a single species have the
same
– number and
– types of chromosomes.
• A human somatic cell
– is a typical body cell and
– has 46 chromosomes.
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Homologous Chromosomes
• A karyotype is an image that reveals an orderly
arrangement of chromosomes.
• Homologous chromosomes
– are matching pairs of chromosomes that
– can possess different versions of the same genes.
© 2013 Pearson Education, Inc.
Pair of homologous
chromosomes
Centromere
One
duplicated
chromosome
Sister
chromatids
LM
Figure 8.11
LM
Figure 8.11a
Homologous Chromosomes
• Humans have
– two different sex chromosomes, X and Y, and
– 22 pairs of matching chromosomes, called
autosomes.
© 2013 Pearson Education, Inc.
Gametes and the Life Cycle of a Sexual Organism
• The life cycle of a multicellular organism is the
sequence of stages leading from the adults of one
generation to the adults of the next.
© 2013 Pearson Education, Inc.
Figure 8.12
Haploid gametes (n 23)
n
Egg cell
n
Sperm cell
MEIOSIS
FERTILIZATION
Multicellular
diploid adults
(2n 46)
2n
Diploid
zygote
(2n 46)
MITOSIS
and development
Key
Haploid (n)
Diploid (2n)
Gametes and the Life Cycle of a Sexual Organism
• Humans are diploid organisms with
– body cells containing two sets of chromosomes
and
– haploid gametes that have only one member of
each homologous pair of chromosomes.
• In humans, a haploid sperm fuses with a haploid
egg during fertilization to form a diploid zygote.
© 2013 Pearson Education, Inc.
Gametes and the Life Cycle of a Sexual Organism
• Sexual life cycles involve an alternation of diploid
and haploid stages.
• Meiosis produces haploid gametes, which keeps
the chromosome number from doubling every
generation.
© 2013 Pearson Education, Inc.
Figure 8.13-1
1
Chromosomes
duplicate.
Pair of
homologous
chromosomes
in diploid
parent cell
Duplicated pair
of homologous
chromosomes
INTERPHASE BEFORE MEIOSIS
Sister
chromatids
Figure 8.13-2
1
Chromosomes
duplicate.
Pair of
homologous
chromosomes
in diploid
parent cell
2
Duplicated pair
of homologous
chromosomes
INTERPHASE BEFORE MEIOSIS
Homologous
chromosomes
separate.
Sister
chromatids
MEIOSIS I
Figure 8.13-3
1
Chromosomes
duplicate.
Pair of
homologous
chromosomes
in diploid
parent cell
2
Duplicated pair
of homologous
chromosomes
INTERPHASE BEFORE MEIOSIS
Homologous
chromosomes
separate.
3
Sister chromatids
separate.
Sister
chromatids
MEIOSIS I
MEIOSIS II
The Process of Meiosis
• In meiosis,
– haploid daughter cells are produced in diploid
organisms,
– interphase is followed by two consecutive
divisions, meiosis I and meiosis II, and
– crossing over occurs.
© 2013 Pearson Education, Inc.
Figure 8.14a
MEIOSIS I: HOMOLOGOUS CHROMOSOMES SEPARATE
INTERPHASE
Centrosomes
(with centriole pairs)
PROPHASE I
Sites of
crossing over
Spindle
Nuclear Chromatin
envelope
Chromosomes
duplicate.
Sister
chromatids
Pair of
homologous
chromosomes
Homologous
chromosomes
pair up and
exchange
segments.
METAPHASE I
Microtubules
attached to
chromosome
ANAPHASE I
Sister chromatids
remain attached
Centromere
Pairs of
homologous
chromosomes
line up.
Pairs of
homologous
chromosomes
split up.
Figure 8.14aa
INTERPHASE
Centrosomes
(with centriole pairs)
Nuclear Chromatin
envelope
Figure 8.14ab
PROPHASE I
Sites of
crossing over
Spindle
Sister
chromatids
Pair of
homologous
chromosomes
METAPHASE I
Microtubules
attached to
chromosome
Centromere
ANAPHASE I
Sister chromatids
remain attached
TELOPHASE I AND
CYTOKINESIS
Cleavage
furrow
Figure 8.14ac
PROPHASE I
Sites of
crossing over
Spindle
Sister
chromatids
Pair of
homologous
chromosomes
METAPHASE I
Microtubules
attached to
chromosome
Centromere
Figure 8.14ad
ANAPHASE I
Sister chromatids
remain attached
TELOPHASE I AND
CYTOKINESIS
Cleavage
furrow
Figure 8.14b
MEIOSIS II: SISTER CHROMATIDS SEPARATE
TELOPHASE I AND
CYTOKINESIS
PROPHASE II
METAPHASE II
ANAPHASE II
TELOPHASE II
AND
CYTOKINESIS
Sister
chromatids
separate
Haploid
daughter
cells forming
Cleavage
furrow
Two haploid
cells form;
chromosomes
are still doubled.
During another round of cell division, the sister
chromatids finally separate; four haploid
daughter cells result, containing single
chromosomes.
Figure 8.14ba
PROPHASE II
METAPHASE II
ANAPHASE II
Sister
chromatids
separate
TELOPHASE II
AND
CYTOKINESIS
Haploid
daughter
cells forming
Figure 8.14bb
PROPHASE II
METAPHASE II
LM
Figure 8.14bc
LM
Meiosis II in
a lily cell
Figure 8.14bd
ANAPHASE II
Sister
chromatids
separate
TELOPHASE II
AND
CYTOKINESIS
Haploid
daughter
cells forming
Review: Comparing Mitosis and Meiosis
• In mitosis and meiosis, the chromosomes duplicate
only once, during the preceding interphase.
• The number of cell divisions varies:
– Mitosis uses one division and produces two
diploid cells.
– Meiosis uses two divisions and produces four
haploid cells.
• All the events unique to meiosis occur during
meiosis I.
© 2013 Pearson Education, Inc.
Figure 8.15
MITOSIS
MEIOSIS
Prophase I
Prophase
Duplicated
chromosome
MEIOSIS I
Parent cell
Metaphase I
Metaphase
Chromosomes
align.
Sister
chromatids
separate.
Homologous
pairs align.
Anaphase I
Telophase I
Anaphase
Telophase
2n
Site of
crossing
over
2n
MEIOSIS I
Homologous
chromosomes
separate.
Haploid
n2
MEIOSIS II
Sister
chromatids
separate.
n
n
n
n
Figure 8.15a
MITOSIS
MEIOSIS
Prophase I
Prophase
Duplicated
chromosome
Parent cell
Metaphase I
Metaphase
Chromosomes
align.
Homologous
pairs align.
MEIOSIS I
Site of
crossing
over
Figure 8.15b
MITOSIS
MEIOSIS
Anaphase
Telophase
2n
Sister
chromatids
separate.
2n
Anaphase I
Telophase I
MEIOSIS I
Homologous
chromosomes
separate.
Haploid
n2
MEIOSIS II
Sister
chromatids
separate.
n
n
n
n
https://www.youtube.com/watch?v=bRcjB11hD
CU Comparison of Meiosis and Mitosis
(15.24)
The Origins of Genetic Variation
• Offspring of sexual reproduction are genetically
different from their parents and one another.
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Independent Assortment of Chromosomes
• When aligned during metaphase I of meiosis, the
side-by-side orientation of each homologous pair
of chromosomes is a matter of chance.
• Every chromosome pair orients independently of
all of the others at metaphase I.
• For any species, the total number of chromosome
combinations that can appear in the gametes due
to independent assortment is
– 2n, where n is the haploid number.
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Independent Assortment of Chromosomes
• For a human,
– n = 23.
– With n = 23, there are 8,388,608 different
chromosome combinations possible in a gamete.
© 2013 Pearson Education, Inc.
Figure 8.16-1
POSSIBILITY 2
POSSIBILITY 1
Two equally probable
arrangements of
chromosomes
at metaphase of
meiosis I
Figure 8.16-2
POSSIBILITY 2
POSSIBILITY 1
Two equally probable
arrangements of
chromosomes
at metaphase of
meiosis I
Metaphase
of
meiosis II
Figure 8.16-3
POSSIBILITY 2
POSSIBILITY 1
Two equally probable
arrangements of
chromosomes
at metaphase of
meiosis I
Metaphase
of
meiosis II
Gametes
Combination a Combination b
Combination c Combination d
Because possibilities 1 and 2 are equally likely, the four possible types of
gametes will be made in approximately equal numbers.
Random Fertilization
• A human egg cell is fertilized randomly by one
sperm, leading to genetic variety in the zygote.
• If each gamete represents one of 8,388,608
different chromosome combinations, at fertilization,
humans would have 8,388,608 × 8,388,608, or
more than 70 trillion different possible chromosome
combinations.
• So we see that the random nature of fertilization
adds a huge amount of potential variability to the
offspring of sexual reproduction.
© 2013 Pearson Education, Inc.
Colorized LM
Figure 8.17
Crossing Over
• In crossing over,
– nonsister chromatids of homologous chromosomes
exchange corresponding segments and
– genetic recombination, the production of gene
combinations different from those carried by
parental chromosomes, occurs.
© 2013 Pearson Education, Inc.
Figure 8.18
Prophase I of meiosis
Homologous
chromatids exchange
corresponding
segments.
Duplicated pair
of homologous
chromosomes
Chiasma, site of
crossing over
Metaphase I
Sister chromatids
remain joined at their
centromeres.
Spindle
microtubule
Metaphase II
Gametes
Recombinant
chromosomes combine
genetic information
from different parents.
Recombinant chromosomes
Figure 8.18a
Prophase I of meiosis
Homologous
chromatids exchange
corresponding
segments.
Duplicated pair
of homologous
chromosomes
Chiasma, site of
crossing over
Metaphase I
Sister chromatids
remain joined at their
centromeres.
Spindle
microtubule
Figure 8.18b
Metaphase II
Gametes
Recombinant
chromosomes combine
genetic information
from different parents.
Recombinant chromosomes
When Meiosis Goes Awry
• What happens when errors occur in meiosis?
• Such mistakes can result in genetic abnormalities
that range from mild to fatal.
© 2013 Pearson Education, Inc.
How Accidents during Meiosis Can Alter Chromosome
Number
• In nondisjunction,
– the members of a chromosome pair fail to separate
at anaphase,
– producing gametes with an incorrect number of
chromosomes.
• Nondisjunction can occur during meiosis I or II.
© 2013 Pearson Education, Inc.
Figure 8.20-1
NONDISJUNCTION IN MEIOSIS I
NONDISJUNCTION IN MEIOSIS II
Meiosis I
Homologous
chromosomes fail
to separate.
Figure 8.20-2
NONDISJUNCTION IN MEIOSIS I
NONDISJUNCTION IN MEIOSIS II
Meiosis I
Homologous
chromosomes fail
to separate.
Meiosis II
Sister
chromatids
fail to
separate.
Figure 8.20-3
NONDISJUNCTION IN MEIOSIS I
NONDISJUNCTION IN MEIOSIS II
Meiosis I
Homologous
chromosomes fail
to separate.
Meiosis II
Sister
chromatids
fail to
separate.
Gametes
n1
n1
n–1
Abnormal
n–1
n1
n–1
Abnormal
n
n
Normal
Figure 8.22b
Down Syndrome: An Extra Chromosome 21
• The incidence of Down syndrome in the offspring
of normal parents increases markedly with the age
of the mother.
© 2013 Pearson Education, Inc.
Figure 8.23
Infants with Down syndrome
(per 1,000 births)
90
80
70
60
50
40
30
20
10
0
20
25
30
35
40
Age of mother
45
50
Abnormal Numbers of Sex Chromosomes
• Nondisjunction in meiosis
– can lead to abnormal numbers of sex
chromosomes but
– seems to upset the genetic balance less than
unusual numbers of autosomes, perhaps because
the Y chromosome is very small and carries
relatively few genes.
© 2013 Pearson Education, Inc.
Table 8.1
Evolution Connection:
The Advantages of Sex
• Asexual reproduction conveys an evolutionary
advantage when plants are
– sparsely distributed and unlikely to be able to
exchange pollen or
– superbly suited to a stable environment.
• Asexual reproduction also eliminates the need to
expend energy
– forming gametes and
– copulating with a partner.
© 2013 Pearson Education, Inc.
Figure 8.24
Runner
Evolution Connection:
The Advantages of Sex
• Sexual reproduction may convey an evolutionary
advantage by
– speeding adaptation to a changing environment or
– allowing a population to more easily rid itself of
harmful genes.
© 2013 Pearson Education, Inc.