After migration primordial germ cells will become oogonia in the forming gonad (ovary). The oogonia proliferate extensively by mitotic divisions, up to 5-7 million cells in humans. But then many of these oogonia die and about 50,000 remain. These cells differentiate into primary oocytes. In week 11-12
fertilization age the first meiotic division begins (before birth for most mammals) and remains arrested in prophase I from a few days to many years depending on the species. It is in this period or in some cases at the beginning of sexual maturity that the primary oocytes secrete proteins to form a coat called
zona pellucida and they also produce
cortical granules containing enzymes and proteins needed for fertilization. Meiosis stands by because of the
follicular granulosa cells that send inhibitory signals through
gap junctions and the zona pellucida. Sexual maturation is the beginning of periodic ovulation.
Ovulation is the regular release of one oocyte from the ovary into the reproductive tract and is preceded by follicular growth. A few follicle cells are stimulated to grow but only one oocyte is ovulated. A primordial follicle consists of an epithelial layer of follicular granulosa cells enclosing an oocyte. The
pituitary gland secrete
follicle-stimulating hormones (FSHs) that stimulate follicular growth and oocyte maturation. The
thecal cells around each follicle secrete
estrogen. This hormone stimulates the production of FSH receptors on the follicular granulosa cells and has at the same time a negative feedback on FSH secretion. This results in a competition between the follicles and only the follicle with the most FSH receptors survives and is ovulated. Meiotic division I goes on in the ovulated oocyte stimulated by
luteinizing hormones (LHs) produced by the
pituitary gland. FSH and LH block the gap junctions between follicle cells and the oocyte therefore inhibiting communication between them. Most follicular granulosa cells stay around the oocyte and so form the cumulus layer. Large non-mammalian oocytes accumulate
egg yolk,
glycogen,
lipids,
ribosomes, and the
mRNA needed for protein synthesis during early embryonic growth. These intensive RNA biosynthese are mirrored in the structure of the
chromosomes, which decondense and form lateral loops giving them a lampbrush appearance (see
Lampbrush chromosome). Oocyte maturation is the following phase of oocyte development. It occurs at sexual maturity when hormones stimulate the oocyte to complete meiotic division I. The meiotic division I produces 2 cells differing in size: a small polar body and a large secondary oocyte. The secondary oocyte undergoes meiotic division II and that results in the formation of a second small polar body and a large mature egg, both being
haploid cells. The polar bodies degenerate. Oocyte maturation stands by at metaphase II in most vertebrates. During ovulation, the arrested secondary oocyte leaves the ovary and matures rapidly into an egg ready for fertilization. Fertilization will cause the egg to complete meiosis II. In human females there is proliferation of the oogonia in the fetus, meiosis starts then before birth and stands by at meiotic division I up to 50 years, ovulation begins at
puberty.
Egg growth A 10 - 20 μm large somatic cell generally needs 24 hours to double its
mass for mitosis. By this way it would take a very long time for that cell to reach the size of a mammalian egg with a diameter of 100 μm (some insects have eggs of about 1,000 μm or greater). Eggs have therefore special mechanisms to grow to their large size. One of these mechanisms is to have extra copies of
genes: meiotic division I is paused so that the oocyte grows while it contains two diploid chromosome sets. Some species produce many extra copies of genes, such as amphibians, which may have up to 1 or 2 million copies. A complementary mechanism is partly dependent on syntheses of other cells. In amphibians, birds, and insects, yolk is made by the liver (or its equivalent) and secreted into the
blood. Neighboring
accessory cells in the ovary can also provide nutritive help of two types. In some invertebrates some oogonia become
nurse cells. These cells are connected by cytoplasmic bridges with oocytes. The nurse cells of insects provide oocytes macromolecules such as proteins and mRNA. Follicular granulosa cells are the second type of accessory cells in the ovary in both invertebrates and vertebrates. They form a layer around the oocyte and nourish them with small molecules, no macromolecules, but eventually their smaller precursor molecules, by
gap junctions.
Mutation and DNA repair The
mutation frequency of female
germline cells in mice is about 5-fold lower than that of
somatic cells, according to one study. The mouse
oocyte in the
dictyate (prolonged diplotene) stage of
meiosis actively repairs
DNA damage, whereas
DNA repair was not detected in the pre-dictyate (
leptotene,
zygotene and
pachytene) stages of meiosis. The long period of meiotic arrest at the four
chromatid dictyate stage of meiosis may facilitate
recombinational repair of DNA damages. ==Spermatogenesis==