366 Chapter 18
how Meiosis produces new Combinations of genes
are rearranged. Remember that germ cells contain sets of
homologous chromosomes, one set that came originally
from a person’s mother and a corresponding set from the
father. These homologues therefore can be called “maternal”
and “paternal” chromosomes and they carry genes for the
same traits. During meiosis I, the two pairs of sister chroma-
tids (one maternal, the other paternal) line up very closely.
This close alignment favors crossing over. In a cross-
over, nonsister chromatids break at the same places along
their length and exchange corresponding segments. The
X-shaped areas shown in Figure 18.12 are crossovers. Each
segment in the exchange includes one or more genes.
The exchange of chromosome
pieces is called genetic recombina-
tion. It leads to variation in the
details of inherited traits because
a gene may have several chemical
forms. For example, as described
in Chapter 19, the gene for earlobe shape has two forms, one
for attached earlobes and the other for detached earlobes.
Often, particular forms of genes on one chromosome differ
from corresponding ones on its homologue partner. When a
crossover occurs between chromosomes in a germ cell, both
then have a slightly different version of their genes than
they had before. If a “Mom” chromosome had the gene for
attached earlobes and the “Dad” had the gene for detached
earlobes, the situation may now be reversed.
gametes also receive a random assortment
of maternal and paternal chromosomes
As you know from looking at Figure 18.11 in Section 18.7,
during metaphase I of meiosis the maternal and paternal
chromosomes get lined up and tethered to the spindle in
preparation for the formation of two new daughter cells. The
chromosomes line up at random, making it highly unlikely
that one daughter cell will receive only maternal chromo-
somes and the other will receive only paternal ones. In fact,
odds are that there will always be a mix of maternal and
paternal chromosomes in each cell that forms during meio-
sis. Figure 18.13A shows the possibilities when there are only
three pairs of homologues. In this case, eight combinations
(2^3 ) of maternal and paternal chromosomes are possible for
the forthcoming gametes.
Of course, a human germ cell has a full 23 pairs of
homologous chromosomes, not just three. So a grand total
© Cengage Learning
n Events that happen during meiosis explain why no person is
genetically identical to either parent.
pieces of chromosomes may be exchanged
No one ever looks, or has a body that operates, exactly like
his or her parents. Most of the trait variations we take for
granted result from changes to chromosomes that occurred
during meiosis, when germ cells were forming sperm in a
father’s testes or eggs in a mother’s ovaries.
Some genetic variations come about during prophase I
of meiosis. This is a time when parts of the duplicated
chromosomes—the sister chromatids—in gonad germ cells
18.8
crossing over Swapping
of corresponding segments
between homologous chro-
mosomes during meiosis.
Figure 18.12 Animated! During meiosis I, a process called crossing
over may create new combinations of genes on the duplicated
chromosomes in germ cells. For clarity, this diagram of a cell shows
only one pair of homologous chro mosomes and one crossover. Here,
the paternal chromosome is blue and its maternal homologue is pink.
© Cengage Learning
B
A
B
A
b
a
b
a
Bb
AA
B
a
b
a
A Here, we focus
on only two of the
many genes on a
chromosome. In
this example, one
chromosome has
genes A and B; the
other has genes a
and b.
C Crossing
over mixes up
paternal and
maternal forms
of genes on
homologous
chromosomes.
B Close contact
between homologous
chromosomes pro-
motes crossing over
between nonsister
chromatids. Paternal
and maternal chro-
matids exchange cor-
responding pieces.
One duplicated
chromosome
One duplicated
chromosome
B
A
B
A
b
a
b
a
Bb
AA
B
a
b
a
A Here, we focus
on only two of the
many genes on a
chromosome. In
this example, one
chromosome has
genes A and B; the
other has genes a
and b.
C Crossing
over mixes up
paternal and
maternal forms
of genes on
homologous
chromosomes.
B Close contact
between homologous
chromosomes pro-
motes crossing over
between nonsister
chromatids. Paternal
and maternal chro-
matids exchange cor-
responding pieces.
One duplicated
chromosome
One duplicated
chromosome
B
A
B
A
b
a
b
a
Bb
AA
B
a
b
a
A Here, we focus
on only two of the
many genes on a
chromosome. In
this example, one
chromosome has
genes A and B; the
other has genes a
and b.
C Crossing
over mixes up
paternal and
maternal forms
of genes on
homologous
chromosomes.
B Close contact
between homologous
chromosomes pro-
motes crossing over
between nonsister
chromatids. Paternal
and maternal chro-
matids exchange cor-
responding pieces.
One duplicated
chromosome
One duplicated
chromosome
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