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Nondisjunction is a genetic defect where chromosomes don’t separate properly during cell division, resulting in aneuploids. It can occur during meiosis I or II, causing trisomy or monosomy. Nondisjunction can lead to birth defects and genetic abnormalities, including Down syndrome and Turner syndrome. Genetic testing can detect these disorders, but there are no known cures. Research continues to find cures for diseases and genetic defects caused by nondisjunction.
In the field of genetics, “nondisjunction” is a technical term for a specific defect in the way a cell’s chromosomes separate. This defect creates a genetic mutation or defect in the cells produced by the process. The resulting cells are called aneuploids. There are two crucial stages of cell division where this defect can occur. The first stage is meiosis I, when homologous chromosomes do not separate, and the second is meiosis II, commonly known as mitosis, when sister chromatids do not separate properly.
When nondisjunction occurs during meiosis I, all of the resulting gametes, called daughter cells, are affected. Two of the daughter cells will have an extra chromosome and the other two daughter cells will be missing a chromosome.
Only half of the resulting daughter cells will be affected when this defect occurs during meiosis II. Of the four resulting gametes, two will be normal, one will have an extra chromosome, and one will be missing a chromosome.
If carried forward in genetics, nondisjunction can cause the parent’s sperm or oocytes to possess 24 chromosomes instead of the normal 23. In these cases, the conceived child will have 47 chromosomes, which is the common variation known as trisomy, seen in children with Down syndrome.
When cells lack a single chromosome, it is called monosomy. This form of genetic mutation can lead to birth defects such as Turner syndrome, a syndrome characterized by developmental delays. It can also lead to infertility caused by lack of genetic material.
Genetically, nondisjunction is often a death sentence for the fetus. As a result of the abnormal cell structure, the mother’s immune system often becomes activated, destroying the rogue cells and causing a miscarriage. In other cases, it leads to genetic defects, referred to as chromosomal abnormalities, resulting in conditions such as Down syndrome, Edwards syndrome, Patau syndrome, Klinefelter syndrome and Turner syndrome.
Although genetic testing, including prenatal testing, is used to detect genetic disorders, there are no known cures for many of the conditions caused by this defect. Medical science continues to study this mutation process in hopes of understanding why cells don’t replicate properly. Mapping the changes found in the cells produced by this condition can help researchers find cures for diseases and genetic defects.
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