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{{Short description|Organism with a recessive genetic allele that does not display the recessive trait}}
{{more citations needed|date=October 2013}}
[[File:Autosomal recessive inheritance - Carriers.png|thumb|[[Punnett square]]: If the other parent does not have the recessive genetic disposition, it does not appear in the [[phenotype]] of the children, but on the average 50% of them become carriers.]]
[[File:Autosomal recessive inheritance - Carriers.png|thumb|[[Punnett square]]: If the other parent does not have the recessive genetic disposition, it does not appear in the [[phenotype]] of the children, but on the average 50% of them become carriers.]]
A '''hereditary carrier''' (or just '''carrier'''), is a person or other organism that has [[Genetics|inherited]] a recessive allele for a genetic trait or mutation but usually does not display that [[genetic trait|trait]] or show symptoms of the [[Genetic disease|disease]]. Carriers are, however, able to [[Heredity|pass]] the [[allele]] onto their offspring, who may then express the genetic.
A '''hereditary carrier''' ('''genetic carrier''' or just '''carrier'''), is a person or other organism that has [[Genetics|inherited]] a recessive allele for a genetic trait or mutation but usually does not display that [[genetic trait|trait]] or show symptoms of the [[Genetic disease|disease]]. Carriers are, however, able to [[Heredity|pass]] the [[allele]] onto their offspring, who may then express the genetic trait.


== Carriers in autosomal inheritances ==
== Carriers in autosomal inheritances ==
[[File:Autosomal recessive inheritance - segregation.png|thumb|Punnett square: If both parents are carriers, on the average 25 % of the offspring have the recessive trait in phenotype and 50 % are carriers.]]
[[File:Autosomal recessive inheritance - segregation.png|thumb|Punnett square: If both parents are carriers, on the average 25 % of the offspring have the recessive trait in phenotype and 50 % are carriers.]]
[[autosomal|Autosomal]] dominant-recessive [[inheritance (biology)#obligatory data|inheritance]] is made possible by the fact that the individuals of most species (including all higher animals and plants) have two [[alleles]] of most hereditary predispositions because the [[chromosomes]] in the [[Cell nucleus|cell nucleus]] are usually present in pairs ([[diploid]]). Carriers can be female or male as the autosoms are homologous indepentantly from the sex.
[[Autosomal]] dominant-recessive [[inheritance (biology)#obligatory data|inheritance]] is made possible by the fact that the individuals of most species (including all higher animals and plants) have two [[alleles]] of most hereditary predispositions because the [[chromosomes]] in the [[cell nucleus]] are usually present in pairs ([[diploid]]). Carriers can be female or male as the autosomes are homologous independently from the sex.


In carriers the expression of a certain characteristic is [[recessive]] (from Latin ''recedere'' "withdraw"). The individual has both a genetic predisposition for the [[dominance (genetics)|dominant]] trait and a genetic predisposition for the recessive trait, and the dominant expression prevails in the [[phenotype]]. In an individual which is [[heterozygous]] regarding a certain allele, it is not externally recognizable that it also has the recessive allele. But if the carrier has offspring, the recessive trait appeares in the phenotye, in case the descendant receives the recessive [[allele]] from both parents and therefore does not possess the dominant allele that would cover the recessive trait. According to [[Mendelian inheritance|Mendelian Law of Segregation of genes]] an average of 25 % of the offspring become [[homozygous]] and express the recessive trait. Carriers can either pass on normal autosomal recessive hereditary traits or an autosomal recessive [[hereditary disease]].
In carriers the expression of a certain characteristic is recessive. The individual has both a genetic predisposition for the [[dominance (genetics)|dominant]] trait and a genetic predisposition for the recessive trait, and the dominant expression prevails in the [[phenotype]]. In an individual which is [[heterozygous]] regarding a certain allele, it is not externally recognisable that it also has the recessive allele. But if the carrier has a child, the recessive trait appears in the phenotype, in case the descendant receives the recessive [[allele]] from both parents and therefore does not possess the dominant allele that would cover the recessive trait. According to [[Mendelian inheritance|Mendelian Law of Segregation of genes]] an average of 25% of the offspring become [[homozygous]] and express the recessive trait. Carriers can either pass on normal autosomal recessive hereditary traits or an autosomal recessive [[hereditary disease]].


== Carriers in gonosomal inheritances ==
== Carriers in gonosomal inheritances ==
[[File:Gonosomal recessive inheritance.png|thumb|The mother is a carrier of the recessive hereditary disposition for [[Color blindness]]. The Y chromosome of the father cannot oppose this. The healthy allele on the X chromosome of the father can compensate for this in a daughter. She can see normally, but she becomes a conductor. The same pattern of inheritance applies to [[Haemophilia]].]]
[[File:Gonosomal recessive inheritance.png|thumb|The mother is a carrier of the recessive hereditary disposition for [[Color blindness]]. The Y chromosome of the father cannot oppose this. The healthy allele on the X chromosome of the father can compensate for this in a daughter. She can see normally, but she becomes a conductor. The same pattern of inheritance applies to [[Haemophilia]].]]
[[Gonosome|Gonosomeal]] recessive genes are also passed on by carriers. The term is used in [[human genetics]] in cases of hereditary traits in which the observed trait lies on the female [[gonosome|sex chromosome]] the [[X chromosome]]. The carriers are always [[Woman|women]]. [[Man|Men]] cannot be carriers because they only have one X chromosome. The Y chromosome is not a really homologous chromosome. For this reason, the genetic make-up of the observed trait is not twofold. If a man has a certain recessive genetic disposition on his X chromosome, this is called ''hemizygot'' and it gets phenotypically expressed. Also a recessive genetic disposition on his Y chromosome - also ''hemizygot'' - can come to expression, because there is no homologous chromosome with an allele, which could overlay it. If there is no genetic information on the Y chromosome for a certain trait, the effect of the Y is neutral and the allele on his X chromosome, which ''would'' be recessive in a heterozygous woman, can now ''alone'' come to expression.
[[Gonosome|Gonosomal]] recessive genes are also passed on by carriers. The term is used in [[human genetics]] in cases of hereditary traits in which the observed trait lies on the female [[gonosome|sex chromosome]], the [[X chromosome]]. These are [[Sex linkage|sex-linked]] genes. The carriers are always [[Woman|women]]. Women have two homologous sex chromosomes (XX). [[Man|Men]] cannot be carriers because they only have one X chromosome. If a man has a certain recessive genetic disposition on his X chromosome, this is called ''hemizygous'' and it gets phenotypically expressed.


Although the Y chromosome is not a really homologous chromosome and carries relatively little genetic information compared to X chromosomes, a genetic component on the Y chromosome can come to expression because there is no homologous chromosome with an allele which could overlay it.
Women have two homologous sex chromosomes (XX). Therefore women can be carriers of [[Sex linkage|X-linked]] genes. Examples of traits inherited via the X chromosome are [[Color blindness|color blindness]] and the most common hereditary form of [[Haemophilia]]. Men are affected much more often than women.<ref>[[Neil A. Campbell]], [[Jane B. Reece]]: ''Biologie.'' Spektrum-Verlag 2003, {{ISBN|3-8274-1352-4}}, page 308–311.</ref><ref>Ulrich Weber: ''Biologie Gesamtband Oberstufe,'' Cornelsen-Verlag 2001, {{ISBN|3-464-04279-0}}, page 178–182.</ref>
[[File:Erbgang Bluterkrankheit.png|thumb|left|Inheritance by female carriers]]
[[Queen Victoria]], and her daughters Princesses Alice and Beatrix, were carriers of the [[hemophilia]] gene (an abnormal allele of a gene, necessary to produce one of the blood clotting factors). Both had children who continued to pass on the gene to succeeding generations of the royal houses of [[Spain]] and [[Russia]], into which they married.<ref>Potts, W.T.W. "Royal Haemophilia." Journal of Biological Education (Society of Biology) 30.3 (1996): 207. Academic Search Premier. 16 Sept. 2013</ref> Since males only have one X chromosome, males who carried the altered gene had hemophilia B. Females have two X chromosomes, so one copy of an [[X-linked recessive]] gene would cause them to be an asymptomatic carrier. These females simply passed it to half of their children.<ref>{{cite web|last1=Pagon|first1=R. A.|last2=Adam|first2=M. P.|last3=Ardinger|first3=H. H.|title=Illustrated Glossary|url=https://www.ncbi.nlm.nih.gov/books/NBK5191/|publisher=GeneReviews. University of Washington, Seattle|accessdate=15 December 2014}}</ref>


Examples of traits inherited via the X chromosome are [[color blindness]] and the most common hereditary form of [[haemophilia]] which therefore affect men much more often than women.<ref>[[Neil A. Campbell]], [[Jane B. Reece]]: ''Biologie.'' Spektrum-Verlag 2003, {{ISBN|3-8274-1352-4}}, page 308–311.</ref><ref>Ulrich Weber: ''Biologie Gesamtband Oberstufe,'' Cornelsen-Verlag 2001, {{ISBN|3-464-04279-0}}, page 178–182.</ref>
Gonosomal dominant inheritances are also known. There are ''no'' carriers, since carriers of a dominant hereditary disposition phenotypically express the trait in each case.
[[File:Erbgang Bluterkrankheit.svg|thumb|left|Inheritance by female carriers]]
[[Queen Victoria]], and her daughters Princesses Alice and Beatrix, were carriers of the [[hemophilia]] gene (an abnormal allele of a gene, necessary to produce one of the blood clotting factors). Both had children who continued to pass on the gene to succeeding generations of the royal houses of [[Spain]] and [[Russia]], into which they married.<ref>Potts, W.T.W. "Royal Haemophilia." Journal of Biological Education (Society of Biology) 30.3 (1996): 207. Academic Search Premier. 16 Sept. 2013</ref> Since males only have one X chromosome, males who carried the altered gene had hemophilia B. Those female children who inherited the altered gene were asymptomatic carriers who also would have passed it to half of their children.


Gonosomal dominant inheritances are also known. There are ''no'' carriers since owners of a dominant hereditary disposition phenotypically express the trait in each case.
==Sickle cell anemia==
Sickle cell anemia is the most common genetic disorder among African Americans in the United States. While approximately 8% are carriers, 1 in 375 African Americans are born with the disease. Carriers are typically asymptomatic, but they may show symptoms at high altitudes or under oxygen-poor environments as in instances of extreme exercise.<ref name= "Edwards" /> Carriers are also known to be resistant to malaria, suggesting there is a heterozygote advantage in certain regions of Africa. This is a probable explanation for why the disease is most prevalent among African Americans <ref>{{cite journal|last1=B.|first1=G.|title=Malaria and Sickle-Cell Anemia|journal=Science|date=October 5, 1956|volume=124|pages=619–624|doi=10.1126/science.124.3223.619 }}</ref>


==References==
==References==
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[[Category:Genetics]]
[[Category:Genetics]]

[[fi:Kantaja (biologia)]]

Latest revision as of 01:08, 21 August 2024

Punnett square: If the other parent does not have the recessive genetic disposition, it does not appear in the phenotype of the children, but on the average 50% of them become carriers.

A hereditary carrier (genetic carrier or just carrier), is a person or other organism that has inherited a recessive allele for a genetic trait or mutation but usually does not display that trait or show symptoms of the disease. Carriers are, however, able to pass the allele onto their offspring, who may then express the genetic trait.

Carriers in autosomal inheritances

[edit]
Punnett square: If both parents are carriers, on the average 25 % of the offspring have the recessive trait in phenotype and 50 % are carriers.

Autosomal dominant-recessive inheritance is made possible by the fact that the individuals of most species (including all higher animals and plants) have two alleles of most hereditary predispositions because the chromosomes in the cell nucleus are usually present in pairs (diploid). Carriers can be female or male as the autosomes are homologous independently from the sex.

In carriers the expression of a certain characteristic is recessive. The individual has both a genetic predisposition for the dominant trait and a genetic predisposition for the recessive trait, and the dominant expression prevails in the phenotype. In an individual which is heterozygous regarding a certain allele, it is not externally recognisable that it also has the recessive allele. But if the carrier has a child, the recessive trait appears in the phenotype, in case the descendant receives the recessive allele from both parents and therefore does not possess the dominant allele that would cover the recessive trait. According to Mendelian Law of Segregation of genes an average of 25% of the offspring become homozygous and express the recessive trait. Carriers can either pass on normal autosomal recessive hereditary traits or an autosomal recessive hereditary disease.

Carriers in gonosomal inheritances

[edit]
The mother is a carrier of the recessive hereditary disposition for Color blindness. The Y chromosome of the father cannot oppose this. The healthy allele on the X chromosome of the father can compensate for this in a daughter. She can see normally, but she becomes a conductor. The same pattern of inheritance applies to Haemophilia.

Gonosomal recessive genes are also passed on by carriers. The term is used in human genetics in cases of hereditary traits in which the observed trait lies on the female sex chromosome, the X chromosome. These are sex-linked genes. The carriers are always women. Women have two homologous sex chromosomes (XX). Men cannot be carriers because they only have one X chromosome. If a man has a certain recessive genetic disposition on his X chromosome, this is called hemizygous and it gets phenotypically expressed.

Although the Y chromosome is not a really homologous chromosome and carries relatively little genetic information compared to X chromosomes, a genetic component on the Y chromosome can come to expression because there is no homologous chromosome with an allele which could overlay it.

Examples of traits inherited via the X chromosome are color blindness and the most common hereditary form of haemophilia which therefore affect men much more often than women.[1][2]

Inheritance by female carriers

Queen Victoria, and her daughters Princesses Alice and Beatrix, were carriers of the hemophilia gene (an abnormal allele of a gene, necessary to produce one of the blood clotting factors). Both had children who continued to pass on the gene to succeeding generations of the royal houses of Spain and Russia, into which they married.[3] Since males only have one X chromosome, males who carried the altered gene had hemophilia B. Those female children who inherited the altered gene were asymptomatic carriers who also would have passed it to half of their children.

Gonosomal dominant inheritances are also known. There are no carriers since owners of a dominant hereditary disposition phenotypically express the trait in each case.

References

[edit]
  1. ^ Neil A. Campbell, Jane B. Reece: Biologie. Spektrum-Verlag 2003, ISBN 3-8274-1352-4, page 308–311.
  2. ^ Ulrich Weber: Biologie Gesamtband Oberstufe, Cornelsen-Verlag 2001, ISBN 3-464-04279-0, page 178–182.
  3. ^ Potts, W.T.W. "Royal Haemophilia." Journal of Biological Education (Society of Biology) 30.3 (1996): 207. Academic Search Premier. 16 Sept. 2013