Medicine:Uniparental disomy

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Uniparental disomy
File:Animation of uniparental isodisomy.ogv
Animation of uniparental isodisomy
SpecialtyMedical genetics

Uniparental disomy (UPD) occurs when a person receives two copies of a chromosome, or of part of a chromosome, from one parent and no copy from the other.[1] UPD can be the result of heterodisomy, in which a pair of non-identical chromosomes are inherited from one parent (an earlier stage meiosis I error) or isodisomy, in which a single chromosome from one parent is duplicated (a later stage meiosis II error).[2] Uniparental disomy may have clinical relevance for several reasons. For example, either isodisomy or heterodisomy can disrupt parent-specific genomic imprinting, resulting in imprinting disorders. Additionally, isodisomy leads to large blocks of homozygosity, which may lead to the uncovering of recessive genes, a similar phenomenon seen in inbred children of consanguineous partners.[3]

UPD has been found to occur in about 1 in 2,000 births.[4]

Pathophysiology

UPD can occur as a random event during the formation of egg cells or sperm cells or may happen in early fetal development. It can also occur during trisomic rescue.

  • When the child receives two (different) homologous chromosomes (inherited from both grandparents) from one parent, this is called heterodisomic UPD. Heterodisomy (heterozygous) indicates a meiosis I error if the gene loci in question didn't cross over.[5]
  • When the child receives two (identical) replica copies of a single homologue of a chromosome, this is called an isodisomic UPD. Isodisomy (homozygous) indicates either a meiosis II (if the gene loci in question didn't cross over[5]) or postzygotic chromosomal duplication.
  • A meiosis I error can result in isodisomic UPD if the gene loci in question crossed over, for example, a distal isodisomy would be due to duplicated gene loci from the maternal grandmother that crossed over and due to an error during meiosis I, ended up in the same gamete.[5]
  • A meiosis II error can result in heterodisomy UPD if the gene loci crossed over in a similar fashion.[5]

Phenotype

Most occurrences of UPD result in no phenotypical anomalies. However, if the UPD-causing event happened during meiosis II, the genotype may include identical copies of the uniparental chromosome (isodisomy), leading to the manifestation of rare recessive disorders. UPD should be suspected in an individual manifesting a recessive disorder where only one parent is a carrier.

Uniparental inheritance of imprinted genes can also result in phenotypical anomalies. Although few imprinted genes have been identified, uniparental inheritance of an imprinted gene can result in the loss of gene function, which can lead to delayed development, intellectual disability, or other medical problems.[citation needed]

UPD has rarely been studied prospectively, with most reports focusing on either known conditions or incidental findings. It has been proposed that the incidence may not be as low as believed, rather it may be under-reported.[9]

All chromosomes

Main page: Medicine:Isodisomy

Genome wide UPD, also called uniparental diploidy, is when all chromosomes are inherited from one parent. Only in mosaic form can this phenomenon be compatible with life. As of 2017, there have only been 18 reported cases of genome wide UPD.[10]

History

The first clinical case of UPD was reported in 1988 and involved a girl with cystic fibrosis and short stature who carried two copies of maternal chromosome 7.[11] Since 1991, out of the 47 possible disomies, 29 have been identified among individuals ascertained for medical reasons. This includes chromosomes 2, 5–11, 13–16, 21 and 22.

See also

References

  1. Robinson WP (May 2000). "Mechanisms leading to uniparental disomy and their clinical consequences". BioEssays 22 (5): 452–9. doi:10.1002/(SICI)1521-1878(200005)22:5<452::AID-BIES7>3.0.CO;2-K. PMID 10797485. 
  2. Human Molecular Genetics 3. Garland Science. pp. 58. ISBN 0-8153-4183-0. https://archive.org/details/humanmolecularge0000stra_b0q6/page/58. 
  3. King DA (2013). "A novel method for detecting uniparental disomy from trio genotypes identifies a significant excess in children with developmental disorders". Genome Research 24 (4): 673–687. doi:10.1101/gr.160465.113. PMID 24356988. 
  4. Nakka, Priyanka; Smith, Samuel Pattillo; O'Donnell-Luria, Anne H.; McManus, Kimberly F.; Agee, Michelle; Auton, Adam; Bell, Robert K.; Bryc, Katarzyna et al. (2019-11-07). "Characterization of Prevalence and Health Consequences of Uniparental Disomy in Four Million Individuals from the General Population" (in en). The American Journal of Human Genetics 105 (5): 921–932. doi:10.1016/j.ajhg.2019.09.016. ISSN 0002-9297. PMID 31607426. 
  5. 5.0 5.1 5.2 5.3 "Meiosis: Uniparental Disomy". https://www.peds.ufl.edu/divisions/genetics/teaching/Uniparental_disomy.html. 
  6. Angelman Syndrome, Online Mendelian Inheritance in Man
  7. "OMIM Entry - # 608149 - KAGAMI-OGATA SYNDROME" (in en-us). https://omim.org/entry/608149. 
  8. Duncan, Malcolm (1 September 2020). "Chromosome 14 uniparental disomy syndrome information Diseases Database" (in en). http://www.diseasesdatabase.com/ddb32320.htm. 
  9. Bhatt, Arpan; Liehr, Thomas; Bakshi, Sonal R. (2013). "Phenotypic spectrum in uniparental disomy: Low incidence or lack of study". Indian Journal of Human Genetics 19 (3): 131–34. doi:10.4103/0971-6866.120819. PMID 24339543. PMC 3841555. http://www.ijhg.com/text.asp?2013/19/3/311/120819. 
  10. Bens, Susanne; Luedeke, Manuel; Richter, Tanja; Graf, Melanie; Kolarova, Julia; Barbi, Gotthold; Lato, Krisztian; Barth, Thomas F. et al. (2017). "Mosaic genome-wide maternal isodiploidy: an extreme form of imprinting disorder presenting as prenatal diagnostic challenge". Clinical Epigenetics 9: 111. doi:10.1186/s13148-017-0410-y. ISSN 1868-7083. PMID 29046733. 
  11. "Uniparental disomy as a mechanism for human genetic disease". American Journal of Human Genetics 42 (2): 217–226. 1988. PMID 2893543. 

External links

Classification

This article incorporates public domain text from The U.S. National Library of Medicine