X-linked dominant inheritance

X-linked dominant inheritance, sometimes referred to as X-linked dominance, is a mode of genetic inheritance by which a dominant gene is carried on the X chromosome. As an inheritance pattern, it is less common than the X-linked recessive type. In medicine, X-linked dominant inheritance indicates that a gene responsible for a genetic disorder is located on the X chromosome, and only one copy of the allele is sufficient to cause the disorder when inherited from a parent who has the disorder. In this case, someone who expresses an X-linked dominant allele will exhibit the disorder and be considered affected.

X-linked dominant traits do not necessarily affect males more than females (unlike X-linked recessive traits). The exact pattern of inheritance varies, depending on whether the father or the mother has the trait of interest. All fathers that are affected by an X-linked dominant disorder, will have affected daughters, but not affected sons. However, if the mother is also affected then sons will have a chance of being affected, depending on whether a dominant or recessive X chromosome is passed on. When the son is affected the mother will always be affected.

Some scholars have suggested discontinuing the terms dominant and recessive when referring to X-linked inheritance due to the multiple mechanisms that can result in the expression of X-linked traits in females, which include cell autonomous expression, skewed X-inactivation, clonal expansion, and somatic mosaicism.^[1]

Genetics

As the X chromosome is one of the sex chromosomes (the other being the Y chromosome), X-linked inheritance is determined by the sex of the parent carrying a specific gene and can often seem complex. This is due to the fact that, typically, females have two copies of the X-chromosome, while males have only one copy. The difference between dominant and recessive inheritance patterns also plays a role in determining the chances of a child inheriting an X-linked disorder from their parentage.

Males can only get an X chromosome from their mother whilst females get an X chromosome from both parents. As a result, females tend to show higher prevalence of X-linked dominant disorders because they have more of a chance to inherit a faulty X chromosome.

Inheritance


X-linked dominant inheritance works differently depending upon whether the mother (left image) or father (right image) is the carrier of a gene that causes a disease or disorder.

In X-linked dominant inheritance, when the mother alone is the carrier of a mutated, or defective gene associated with a disease or disorder; she herself will have the disorder. Her children will inherit the disorder as follows:

Of her daughters and sons: 50% will have the disorder, 50% will be completely unaffected. Children of either sex have an even chance of receiving either of their mother's two X chromosomes, one of which contains the defective gene in question.

When the father alone is the carrier of a defective gene associated with a disease or disorder, he too will have the disorder. His children will inherit the disorder as follows:

Of his daughters: 100% will have the disorder, since all of his daughters will receive one copy of his single X chromosome.
Of his sons: none will have the disorder; sons do not receive an X chromosome from their father.

If both parents were carriers of a defective gene associated with a disease or disorder, they would both have the disorder. Their children would inherit the disorder as follows:

Of their daughters: 100% will have the disorder, since all of the daughters will receive a copy of their father's X chromosome.
Of the sons: 50% will have the disorder, 50% will be completely unaffected. Sons have an equal chance of receiving either of their mother's X chromosomes.

In such a case, where both parents carry and thus are affected by an X-linked dominant disorder, the chance of a daughter receiving two copies of the X chromosome with the defective gene is 50%, since daughters receive one copy of the X chromosome from both parents. Were this to occur with an X-linked dominant disorder, that daughter would likely experience a more severe form.

Some X-linked dominant conditions such as Aicardi Syndrome are fatal to boys, therefore only girls with these conditions survive, or boys with Klinefelter's syndrome (and hence have more than one X chromosome).

List of dominant X-linked diseases

Vitamin D resistant rickets: X-linked hypophosphatemia
Rett syndrome (95% of cases are due to sporadic mutations)
Most cases of Alport syndrome^[2]
Incontinentia pigmenti^[3]
Giuffrè–Tsukahara syndrome^[4]
Goltz syndrome
X-linked dominant protoporphyria^[5]^{[better source needed]}
Fragile X syndrome

References

^ Dobyns, William B.; Filauro, Allison; Tomson, Brett N.; Chan, April S.; Ho, Allen W.; Ting, Nicholas T.; Oosterwijk, Jan C.; Ober, Carole (2004). "Inheritance of most X-linked traits is not dominant or recessive, just X-linked". American Journal of Medical Genetics. 129A (2): 136. doi:10.1002/ajmg.a.30123. PMID 15316978.
^ Jais, J. P.; Knebelmann, B; Giatras, I; De Marchi, M; Rizzoni, G; Renieri, A; Weber, M; Gross, O; Netzer, K. O.; Flinter, F; Pirson, Y; Dahan, K; Wieslander, J; Persson, U; Tryggvason, K; Martin, P; Hertz, J. M.; Schröder, C; Sanak, M; Carvalho, M. F.; Saus, J; Antignac, C; Smeets, H; Gubler, M. C. (2003). "X-Linked Alport Syndrome: Natural History and Genotype-Phenotype Correlations in Girls and Women Belonging to 195 Families: A "European Community Alport Syndrome Concerted Action" Study". Journal of the American Society of Nephrology. 14 (10): 2603–10. doi:10.1097/01.ASN.0000090034.71205.74. PMID 14514738.
^ http://dermnetnz.org/systemic/incontinentia-pigmenti.html^{[full citation needed]}
^ Dalal, Ashwin B.; Sarkar, Anujit; Priya, T. Padma; Nandineni, Madhusudan R. (2010). "Giuffrè-Tsukahara syndrome: Evidence for X-linked dominant inheritance and review". American Journal of Medical Genetics Part A. 152A (8): 2057. doi:10.1002/ajmg.a.33505. PMID 20635354.
^ Porphyria#Subtypes

[1] Dobyns, William B.; Filauro, Allison; Tomson, Brett N.; Chan, April S.; Ho, Allen W.; Ting, Nicholas T.; Oosterwijk, Jan C.; Ober, Carole (2004). "Inheritance of most X-linked traits is not dominant or recessive, just X-linked". American Journal of Medical Genetics. 129A (2): 136. doi:10.1002/ajmg.a.30123. PMID 15316978.

[2] Jais, J. P.; Knebelmann, B; Giatras, I; De Marchi, M; Rizzoni, G; Renieri, A; Weber, M; Gross, O; Netzer, K. O.; Flinter, F; Pirson, Y; Dahan, K; Wieslander, J; Persson, U; Tryggvason, K; Martin, P; Hertz, J. M.; Schröder, C; Sanak, M; Carvalho, M. F.; Saus, J; Antignac, C; Smeets, H; Gubler, M. C. (2003). "X-Linked Alport Syndrome: Natural History and Genotype-Phenotype Correlations in Girls and Women Belonging to 195 Families: A "European Community Alport Syndrome Concerted Action" Study". Journal of the American Society of Nephrology. 14 (10): 2603–10. doi:10.1097/01.ASN.0000090034.71205.74. PMID 14514738.

[3] ttp://dermnetnz.org/systemic/incontinentia-pigmenti.html^{[full citation needed]}

[Giuffrè-4] Dalal, Ashwin B.; Sarkar, Anujit; Priya, T. Padma; Nandineni, Madhusudan R. (2010). "Giuffrè-Tsukahara syndrome: Evidence for X-linked dominant inheritance and review". American Journal of Medical Genetics Part A. 152A (8): 2057. doi:10.1002/ajmg.a.33505. PMID 20635354.

[5] Porphyria#Subtypes

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[3]

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[5]

Genetics

Inheritance

List of dominant X-linked diseases

See also

References