Polysomy
Polysomy is a condition found in many species, including fungi, plants, insects, and mammals, in which an organism has at least one more chromosome than normal, i.e., there may be three or more copies of the chromosome rather than the expected two copies. Most eukaryotic species are diploid, meaning they have two sets of chromosomes, whereas prokaryotes are haploid, containing a single chromosome in each cell. Aneuploids possess chromosome numbers that are not exact multiples of the haploid number and polysomy is a type of aneuploidy. A karyotype is the set of chromosomes in an organism and the suffix -somy is used to name aneuploid karyotypes. This is not to be confused with the suffix -ploidy, referring to the number of complete sets of chromosomes.
Polysomy is usually caused by non-disjunction during meiosis, but may also be due to a translocation mutation. Polysomy is found in many diseases, including Down syndrome in humans where affected individuals possess three copies of chromosome 21.
Polysomic inheritance occurs during meiosis when chiasmata form between more than two homologous partners, producing chromosomes. Autopolyploids may show polysomic inheritance of all the linkage groups, and their fertility may be reduced due to unbalanced chromosome numbers in the gametes. In tetrasomic inheritance, four copies of a linkage group rather than two assort two-by-two.
Types
Polysomy types are categorized based on the number of extra chromosomes in each set, noted as a diploid with an extra chromosome of various numbers. For example, a polysomy with three chromosomes is called a trisomy, a polysomy with four chromosomes is called tetrasomy, etc.:In mammals
In canines
Polysomy plays a role in canine leukemia, hemangiopericytomas, and thyroid tumors. Abnormalities of chromosome 13 have been observed in canine osteoid chondrosarcoma and lymphosarcoma. Trisomy 13 in dogs with lymphosarcoma show a longer duration of first remission and survival, responding well to treatments with chemotherapeutic agents. Polysomy of chromosome 13 is significant in the development of prostate cancer and is often caused by centric fusions. Since canine chromosome 13 is similar to human chromosome 8q, research could provide insight to treatment for prostate cancer in humans.Polysomy of chromosomes 1, 2, 4, 5, and 25 are also frequently involved in canine tumors. Chromosome 1 may contain a gene responsible for tumor development and lead to changes in the karyotype, including fusion of the centromere, or centric fusions. Aneuploidy due to nondisjunction is a common feature in tumor cells.
In humans
Sex chromosomes
Some of the most frequent genetic disorders are abnormalities of sex chromosomes, but polysomies rarely occur. 49,XXXXY chromosome polysomy occurs every 1 in 85,000 newborn males. The incidence of other X polysomies is more rare than 49,XXXXY. Polysomy Y occurs in 1 out of 975 males and may cause psychiatric, social, and somatic abnormalities. Polysomy X may cause mental and developmental retardation and physical malformation. Klinefelter syndrome is an example of human polysomy X with the karyotype 47, XXY. X chromosome polysomies can be inherited from either a single maternal or paternal X chromosome. Polysomy of sex chromosomes is caused by successive nondisjunctions in meiosis I and II.Chromosome 7
In squamous cell carcinoma, a protein from the epidermal growth factor receptor gene is often overexpressed in conjunction with polysomy of chromosome 7, so chromosome 7 can be used to predict the presence of EGFR in squamous cell carcinoma. In colorectal cancer, EGFR expression is decreased with polysomy 7, which makes polysomy 7 easier to detect and could be used to prevent patients from having unnecessary cancer treatment.Chromosome 8
Tetrasomy and hexasomy 8 are rare compared to trisomy 8, which is the most common karyotypic finding in acute myeloid leukemia and myelodysplastic syndromes. AML, MDS, or myeloproliferative disorder with a high incidence of secondary diseases and a six-month survival rate are associated with a polysomy 8 syndrome.Chromosome 17
Overexpression of the HER2/neu gene on chromosome 17 and some type of polysomy has been reported in 8-68% of breast carcinomas. If theHER-2/neu gene does not amplify in the case of polysomy, proteins may be overexpressed and could lead to tumerogenesis. Polysomy 17 may complicate the interpretation of HER2 testing results in cancer patients. Chromosome 17 polysomy may not be present when the centromere is amplified, so it was later discovered that polysomy 17 is rare. This was discovered using array comparative genomic hybridization, a DNA-based alternative for clinical evaluation of HER2 gene copy number.Trisomy 21
is a form of Down syndrome that occurs when there is an extra copy of chromosome 21. The result is a genetic condition in which a person has 47 chromosomes instead of the usual 46. During egg or sperm development the 21st chromosome does not separate during either the egg or sperm development. The end result is a cell that has 24 chromosomes. This extra chromosome may cause problems with the manner in which the body and brain develop.Tetrasomy 9p
Tetrasomy 9p is a rare condition in which people have a small extra chromosome that contains two copies of part of chromosome 9, in addition to having two normal chromosome 9's as well. This condition may be diagnosed by analyzing a person's blood sample since 9p is found in high concentrations in the blood. Ultrasound is another tool that may be utilized to identify tetrasomy 9p in infants prior to birth. Prenatal ultrasound may reveal several common characteristics including: growth restriction, ventriculomegaly, cleft lip or palate, and renal anomalies.Tetrasomy 18p
Tetrasomy 18p occurs when the short arm of the 18th chromosome appears four times, rather than twice, in the cells of the body. It is considered to be a rare disease and usually is not inherited. The mechanism of 18p formation appears to be the result of two independent events: centromeric misdivision and nondisjunction. Characteristic features of tetrasomy 18p include, but are not limited to: growth retardation, scoliosis, abnormal brain MRI, developmental delays, and strabismus.In insects
Germ line polysomy in the grasshopper
cells develop into eggs and sperm and the associated inherited material can be passed down to future generations. As shown in the associated karyotype image, chromosomes 1–22 are grouped A-G. A population of male grasshoppers from the Sierra Nevada are polysomic mosaics possessing an extra E group chromosome in their testicles. Parents that exhibited polysomy did not pass the E chromosome abnormality to any of the offspring, so this is not something that is passed down to future generations. Male grasshoppers from Australia carry between one and ten extra copies of chromosome A9, with one being the most common in natural populations. Most polysomic males produce normal sperm. However, polysomy can be transmissible through both the male and female parents through nondisjunction.Heterochromatic polysomy in the cricket
contains a small number of genes and densely staining nodules in or along chromosomes.The mole cricket chromosome number varies between 19 and 23 chromosomes depending on the part of the world in which they are located, including Jerusalem, Palestine, and Europe. Heterochromic polysomy is seen in mole crickets with 23 chromosomes and may be a factor contributing to their evolution, specifically within the species Gryllotalpa gryllotalpa, along with various living environments and mating systems.
X-chromosome polysomy in the fruit fly
In the fruit fly, Drosophila, one X chromosome in the male is almost the same as two X chromosomes in the female in terms of the gene product produced. Despite this, metafemales, or females having three X chromosomes, are unlikely to survive. It is possible that the extra X chromosome decreases gene expression and could explain why the metafemales rarely survive this X-chromosome polysomy.In plants
A karyotype rearrangement of individual chromosomes takes place when polysomy in plants in observed. The mechanism of this type of rearrangement is "non-disjunction, mis-segregation in diploids or polyploids; mis-segregation from multivalents in interchange heterozygotes." Incidences of polysomy have been identified in many species of plants, including:- Ornithogalum umbellatum L.
- Conifers
- Cultivar R570
- Brassica
- Euphrasia
- Paspalum dilatatum
In fungi
Polysomy of Chromosome 13 has been observed in the Flor strains of the yeast species Saccharomyces cerevisiae.
Chromosome 13 contains loci, specifically the ADH2 and ADH3 loci, which encode for the isozymes of alcohol dehydrogenase.
These isozymes play a primary role in the biological aging of wines via ethanol oxidative utilization.
Polysomy of Chromosome 13 is promoted when there is disruption of the yeast RNA1 gene with LEU2 sequences.
Diagnostic tools
Fluorescent in situ hybridization
is a cytogenetic technique that has proven to be useful in the diagnosis of patients with polysomy. Conventional cytogenetics and fluorescence in situ hybridization have been used to detect various polysomies, including the most common autosomies as well as polysomy X and Y.Testing for chromosomal aneuploidy with Fluorescence in situ hybridization may increase the sensitivity of cytology and improve the accuracy of cancer diagnosis. The Cervical Cancer, TERC, Fluorescence in situ hybridization test, detects amplification of the human telomerase RNA component gene and/or polysomy of chromosome 3.