<P> Homologous chromosomes are important in the processes of meiosis and mitosis . They allow for the recombination and random segregation of genetic material from the mother and father into new cells . </P> <P> Meiosis is a round of two cell divisions that results in four haploid daughter cells that each contain half the number of chromosomes as the parent cell . It reduces the chromosome number in a germ cell by half by first separating the homologous chromosomes in meiosis I and then the sister chromatids in meiosis II . The process of meiosis I is generally longer than meiosis II because it takes more time for the chromatin to replicate and for the homologous chromosomes to be properly oriented and segregated by the processes of pairing and synapsis in meiosis I. During meiosis, genetic recombination (by random segregation) and crossing over produces daughter cells that each contain different combinations of maternally and paternally coded genes . This recombination of genes allows for the introduction of new allele pairings and genetic variation . Genetic variation among organisms helps make a population more stable by providing a wider range of genetic traits for natural selection to act on . </P> <P> In prophase I of meiosis I, each chromosome is aligned with its homologous partner and pairs completely . In prophase I, the DNA has already undergone replication so each chromosome consists of two identical chromatids connected by a common centromere . During the zygotene stage of prophase I, the homologous chromosomes pair up with each other . This pairing occurs by a synapsis process where the synaptonemal complex - a protein scaffold - is assembled and joins the homologous chromosomes along their lengths . Cohesin crosslinking occurs between the homologous chromosomes and helps them resist being pulled apart until anaphase . Genetic crossing - over, a type of recombintion, occurs during the pachytene stage of prophase I. In addition, another type of recombination referred to as synthesis - dependent strand annealing (SDSA) frequently occurs . SDSA recombination involves information exchange between paired homologous chromatids, but not physical exchange . SDSA recombination does not cause crossing - over . </P> <P> In the process of crossing - over, genes are exchanged by the breaking and union of homologous portions of the chromosomes' lengths . Structures called chiasmata are the site of the exchange . Chiasmata physically link the homologous chromosomes once crossing over occurs and throughout the process of chromosomal segregation during meiosis . Both the non-crossover and crossover types of recombination function as processes for repairing DNA damage, particularly double - strand breaks . At the diplotene stage of prophase I the synaptonemal complex disassembles before which will allow the homologous chromosomes to separate, while the sister chromatids stay associated by their centromeres . </P>

Where does the parent cell in meiosis come from