Mitosis takes a diploid cell and creates a nearly exact copy. Mitosis has two main functions: (1) it leads to the creation of all of the somatic (body) cells in humans and other living organisms; (2) in organisms that undergo asexual reproduction, diploid parent cells undergo mitosis to create identical daughter copies of themselves. Mitosis creates a daughter cell with chromosomes that are identical to the chromosomes in its parent cell.
But humans and most other complex plants and animals each have a unique set of chromosomes. This diversity of chromosomes is the result of sexual reproduction, which involves the contribution of the genetic material from not one, but two parents. During sexual reproduction the father’s haploid sperm cell and the mother’s haploid ovum (egg) cell fuse to form a single-celled diploid zygote that then divides billions of times to form a whole individual.
In order for sexual reproduction to take place, however, the parents first need to have haploid sperm or ova, also called sex cells, germ cells, or gametes. Meiosis is the name for the special type of cell division that produces gametes.
Process of Meiosis
Unlike the single-cell division of mitosis, meiosis involves two cellular divisions: meiosis I and meiosis II. Each stage of meiosis runs through the same five stages as discussed in mitosis. During the first round of division, two intermediate daughter cells are produced. By the end of the second round of meiotic division (meiosis II), the original diploid (2n) cell has become four haploid (n) daughter cells.
Meiosis I
Meiosis I is quite similar to mitosis. However, there are a number of crucial differences between meiosis I and mitosis, all of which will be outlined in the discussion of each individual stage below.
Interphase I
Just as in mitosis, the cell undergoes DNA replication during this intermediate phase. After replication, the cell has a total of 46 chromosomes, each made up of two sister chromatids joined by a centromere.
Prophase I
The major distinction between mitosis and meiosis occurs during this phase. In mitotic prophase, the double-stranded chromosomes line up individually along the spindle. But in meiotic prophase I, chromosomes line up along the spindle in homologous pairs. Then, in a process called synapsis, the homologous pairs actually join together and intertwine, forming a tetrad (two chromosomes of two chromatids each, or four total chromatids). Often this intertwining leads the chromatids of homologous chromosomes to actually exchange corresponding pieces of DNA, a process called crossing-over or genetic reassortment. Throughout prophase I, sister chromatids behave as a unit and are identical except for the region where crossover occurred.
Metaphase I
After prophase I, the meiotic cell enters metaphase I. During this phase, the nuclear membrane breaks down, allowing microtubules access to the chromosomes. Still joined at their crossover regions in tetrads, the homologous pairs of chromosomes, with one maternal and one paternal chromosome in each pair, align at the center of the cell via microtubules, as in mitotic metaphase. The pairs align in random order.
