HUMAN BIOLOGY

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370 Chapter 18

expLoreon your oWn


suMMary


section 18.1 In reproduction, a parent
cell produces a new generation of cells,
or parents produce a new individual.
Reproduction is part of a life cycle, a
recurring sequence in which individuals
grow, develop, and reproduce. Each cell of a
new generation must receive a copy of the parental DNA and
enough cytoplasm to start up its own operation.
Mitosis maintains the diploid number of chromosomes in
the two daughter nuclei.
A chromosome is a DNA molecule and its associated
proteins. The sum of the chromosomes in a given cell type
is the chromosome number. Human somatic cells have a
diploid chromosome number of 46, or two copies of 23 types
of chromosomes. Except for the sex chromosomes, pairs of
homologous chromosomes are the same length and carry
similar genes.
section 18.2 The cell cycle begins when
a new cell is produced and ends when that
cell divides. The longest part of the cycle is
interphase, which includes a growth stage
(G1), when the cell roughly doubles the
number of organelles and other components
in its cytoplasm. In the S stage the cell’s
chromosomes are duplicated. There is also a final, short growth
stage (G2). The duration of the cell cycle varies in different types
of cells.
Human cells divide the cell nucleus by either mitosis or
meiosis. Mitosis is the division mechanism in somatic cells—
body cells that are not specialized to make gametes. It functions
in growth and tissue repair. Meiosis divides the nucleus in
germ cells, cells in the gonads that give rise to gametes.

An unduplicated chromosome consists of one DNA mole-
cule and proteins. A duplicated chromosome consists of two
DNA molecules that are temporarily attached to each other
as sister chromatids. When the nucleus divides, microtubules
attach to a centromere on the paired chromatids. The
microtubules are part of a spindle that moves chromosomes
during nuclear division.
sections 18.3, 18.4 Mitosis has four
stages:


  1. Prophase. Duplicated, threadlike chro-
    mosomes condense into rodlike structures;
    new microtubules start to assemble in orga-
    nized arrays near the nucleus; they will form a
    spindle. The nuclear envelope disappears.

  2. Metaphase. Spindle microtubules orient the sister
    chromatids of each chromosome toward opposite spindle
    poles. The chromosomes line up at the spindle equator.

  3. Anaphase. Sister chromatids of each chromosome
    separate. Both are now independent chromosomes, and they
    move to opposite poles.

  4. Telophase. Chromosomes become threadlike again and
    a new nuclear envelope forms around the two clusters of
    chromosomes. Mitosis is completed. Cytokinesis divides the
    cytoplasm; the result is two diploid cells.
    Division of the cytoplasm, called cytokinesis, occurs toward
    the end of mitosis or shortly afterward.
    sections 18.6, 18.7 Meiosis reduces
    the total number of chromosomes in daughter
    cells. Two consecutive divisions of a germ
    cell cut the parental diploid chromosome
    number in half. Meiosis I distributes the pairs
    of homologous chromosomes. Meiosis II
    separates sister chromatids. The result, after
    cytokinesis, is four haploid cells.


Section 16.2 explains that oogenesis begins when a female is still a
developing embryo. Meiosis I begins in the immature eggs (primary oocytes) of a
female embryo but is arrested in prophase I. Meiosis I won’t resume until the female
undergoes puberty. From then until menopause, just before an egg is ovulated, it will
undergo the remaining stages of meiosis I. As the egg is traveling down an oviduct,
meiosis II begins. This stage also is arrested, in metaphase II. Only if the egg is fertil-
ized will all the stages of meiosis finally be completed (Figure 18.15).
Knowing this sequence, you can calculate fairly accurately how long it took for the
egg that helped make you to pass through all the stages of meiosis. You only need to
know the month and year your mother was born and the month and year you were
conceived (or born). As a starting point, remember that a female’s primary oocytes
form during the third month of embryonic development, about 6 months before birth.
If you have siblings, do the same calculation for them.

Figure 18.15 This photograph shows an egg
with a sperm that will penetrate and fertilize
it—marking the end of meiosis in the egg and
the beginning of bodily growth by mitosis.

Don W. Fawcett/Science Source

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