Misplaced Pages

Dominance (genetics)

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
(Redirected from Semidominant) One gene variant masking the effect of another in the other copy of the gene
This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.
Find sources: "Dominance" genetics – news · newspapers · books · scholar · JSTOR (February 2018) (Learn how and when to remove this message)
Autosomal dominant and autosomal recessive inheritance, the two most common Mendelian inheritance patterns. An autosome is any chromosome other than a sex chromosome.

In genetics, dominance is the phenomenon of one variant (allele) of a gene on a chromosome masking or overriding the effect of a different variant of the same gene on the other copy of the chromosome. The first variant is termed dominant and the second is called recessive. This state of having two different variants of the same gene on each chromosome is originally caused by a mutation in one of the genes, either new (de novo) or inherited. The terms autosomal dominant or autosomal recessive are used to describe gene variants on non-sex chromosomes (autosomes) and their associated traits, while those on sex chromosomes (allosomes) are termed X-linked dominant, X-linked recessive or Y-linked; these have an inheritance and presentation pattern that depends on the sex of both the parent and the child (see Sex linkage). Since there is only one copy of the Y chromosome, Y-linked traits cannot be dominant or recessive. Additionally, there are other forms of dominance, such as incomplete dominance, in which a gene variant has a partial effect compared to when it is present on both chromosomes, and co-dominance, in which different variants on each chromosome both show their associated traits.

Dominance is a key concept in Mendelian inheritance and classical genetics. Letters and Punnett squares are used to demonstrate the principles of dominance in teaching, and the upper-case letters are used to denote dominant alleles and lower-case letters are used for recessive alleles. An often quoted example of dominance is the inheritance of seed shape in peas. Peas may be round, associated with allele R, or wrinkled, associated with allele r. In this case, three combinations of alleles (genotypes) are possible: RR, Rr, and rr. The RR (homozygous) individuals have round peas, and the rr (homozygous) individuals have wrinkled peas. In Rr (heterozygous) individuals, the R allele masks the presence of the r allele, so these individuals also have round peas. Thus, allele R is dominant over allele r, and allele r is recessive to allele R.

Dominance is not inherent to an allele or its traits (phenotype). It is a strictly relative effect between two alleles of a given gene of any function; one allele can be dominant over a second allele of the same gene, recessive to a third, and co-dominant with a fourth. Additionally, one allele may be dominant for one trait but not others. Dominance differs from epistasis, the phenomenon of an allele of one gene masking the effect of alleles of a different gene.

Background

See also: Introduction to genetics
Inheritance of dwarfing in maize. Demonstrating the heights of plants from the two parent variations and their F1 heterozygous hybrid (centre)

Gregor Johann Mendel, "The Father of Genetics", promulgated the idea of dominance in the 1860s. However, it was not widely known until the early twentieth century. Mendel observed that, for a variety of traits of garden peas having to do with the appearance of seeds, seed pods, and plants, there were two discrete phenotypes, such as round versus wrinkled seeds, yellow versus green seeds, red versus white flowers or tall versus short plants. When bred separately, the plants always produced the same phenotypes, generation after generation. However, when lines with different phenotypes were crossed (interbred), one and only one of the parental phenotypes showed up in the offspring (green, round, red, or tall). However, when these hybrid plants were crossed, the offspring plants showed the two original phenotypes, in a characteristic 3:1 ratio, the more common phenotype being that of the parental hybrid plants. Mendel reasoned that each parent in the first cross was a homozygote for different alleles (one parent AA and the other parent aa), that each contributed one allele to the offspring, with the result that all of these hybrids were heterozygotes (Aa), and that one of the two alleles in the hybrid cross dominated expression of the other: A masked a. The final cross between two heterozygotes (Aa X Aa) would produce AA, Aa, and aa offspring in a 1:2:1 genotype ratio with the first two classes showing the (A) phenotype, and the last showing the (a) phenotype, thereby producing the 3:1 phenotype ratio.

Mendel did not use the terms gene, allele, phenotype, genotype, homozygote, and heterozygote, all of which were introduced later. He did introduce the notation of capital and lowercase letters for dominant and recessive alleles, respectively, still in use today.

In 1928, British population geneticist Ronald Fisher proposed that dominance acted based on natural selection through the contribution of modifier genes. In 1929, American geneticist Sewall Wright responded by stating that dominance is simply a physiological consequence of metabolic pathways and the relative necessity of the gene involved.

Types of dominance

Complete dominance (Mendelian)

In complete dominance, the effect of one allele in a heterozygous genotype completely masks the effect of the other. The allele that masks are considered dominant to the other allele, and the masked allele is considered recessive.

When we only look at one trait determined by one pair of genes, we call it monohybrid inheritance. If the crossing is done between parents (P-generation, F0-generation) who are homozygote dominant and homozygote recessive, the offspring (F1-generation) will always have the heterozygote genotype and always present the phenotype associated with the dominant gene.

Monohybrid cross between homozygote dominant (GG) and homozygote recessive (gg), always resulting in heterozygote genotype (Gg) and the phenotype associated with the dominant allele, in this case capital G.
Monohybrid cross between heterozygotes (Gg), resulting in genptypical ratio 1:2:1 (GG:Gg:gg) and phenotypical ratio 3:1 (G:g).

However, if the F1-generation is further crossed with the F1-generation (heterozygote crossed with heterozygote) the offspring (F2-generation) will present the phenotype associated with the dominant gene ¾ times. Although heterozygote monohybrid crossing can result in two phenotype variants, it can result in three genotype variants -  homozygote dominant, heterozygote and homozygote recessive, respectively.

In dihybrid inheritance we look at the inheritance of two pairs of genes simultaneous. Assuming here that the two pairs of genes are located at non-homologous chromosomes, such that they are not coupled genes (see genetic linkage) but instead inherited independently. Consider now the cross between parents (P-generation) of genotypes homozygote dominant and recessive, respectively. The offspring (F1-generation) will always heterozygous and present the phenotype associated with the dominant allele variant.

Dihybrid cross between homozygote dominant (GGRR) and homozygote recessive (ggrr) always resulting in heterozygotes (GgRr) with phenotype associated with the dominant alleles G and R.
Dihybrid cross between heterozygotes (GgRr), resulting in the phenotypical ratio 9:3:3:1 (G and R: G and r: g and R: g and r)

However, when crossing the F1-generation there are four possible phenotypic possibilities and the phenotypical ratio for the F2-generation will always be 9:3:3:1.

Incomplete dominance (non-Mendelian)

This Punnett square illustrates incomplete dominance. In this example, the red petal trait associated with the R allele recombines with the white petal trait of the r allele. The plant incompletely expresses the dominant trait (R) causing plants with the Rr genotype to express flowers with less red pigment resulting in pink flowers. The colors are not blended together, the dominant trait is just expressed less strongly.
See also: partial dominance hypothesis

Incomplete dominance (also called partial dominance, semi-dominance, intermediate inheritance, or occasionally incorrectly co-dominance in reptile genetics) occurs when the phenotype of the heterozygous genotype is distinct from and often intermediate to the phenotypes of the homozygous genotypes. The phenotypic result often appears as a blended form of characteristics in the heterozygous state. For example, the snapdragon flower color is homozygous for either red or white. When the red homozygous flower is paired with the white homozygous flower, the result yields a pink snapdragon flower. The pink snapdragon is the result of incomplete dominance. A similar type of incomplete dominance is found in the four o'clock plant wherein pink color is produced when true-bred parents of white and red flowers are crossed. In quantitative genetics, where phenotypes are measured and treated numerically, if a heterozygote's phenotype is exactly between (numerically) that of the two homozygotes, the phenotype is said to exhibit no dominance at all, i.e. dominance exists only when the heterozygote's phenotype measure lies closer to one homozygote than the other.

When plants of the F1 generation are self-pollinated, the phenotypic and genotypic ratio of the F2 generation will be 1:2:1 (Red:Pink:White).

Co-dominance (non-Mendelian)

Co-dominance in a Camellia cultivar
A and B blood types in humans show co-dominance, but the O type is recessive to A and B.
This Punnett square shows co-dominance. In this example a white bull (WW) mates with a red cow (RR), and their offspring exhibit co-dominance expressing both white and red hairs.

Co-dominance occurs when the contributions of both alleles are visible in the phenotype and neither allele masks another.

For example, in the ABO blood group system, chemical modifications to a glycoprotein (the H antigen) on the surfaces of blood cells are controlled by three alleles, two of which are co-dominant to each other (I, I) and dominant over the recessive i at the ABO locus. The I and I alleles produce different modifications. The enzyme coded for by I adds an N-acetylgalactosamine to a membrane-bound H antigen. The I enzyme adds a galactose. The i allele produces no modification. Thus the I and I alleles are each dominant to i (II and Ii individuals both have type A blood, and II and Ii individuals both have type B blood), but II individuals have both modifications on their blood cells and thus have type AB blood, so the I and I alleles are said to be co-dominant.

Another example occurs at the locus for the beta-globin component of hemoglobin, where the three molecular phenotypes of Hb/Hb, Hb/Hb, and Hb/Hb are all distinguishable by protein electrophoresis. (The medical condition produced by the heterozygous genotype is called sickle-cell trait and is a milder condition distinguishable from sickle-cell anemia, thus the alleles show incomplete dominance concerning anemia, see above). For most gene loci at the molecular level, both alleles are expressed co-dominantly, because both are transcribed into RNA.

Co-dominance, where allelic products co-exist in the phenotype, is different from incomplete dominance, where the quantitative interaction of allele products produces an intermediate phenotype. For example, in co-dominance, a red homozygous flower and a white homozygous flower will produce offspring that have red and white spots. When plants of the F1 generation are self-pollinated, the phenotypic and genotypic ratio of the F2 generation will be 1:2:1 (Red:Spotted:White). These ratios are the same as those for incomplete dominance. Again, this classical terminology is inappropriate – in reality, such cases should not be said to exhibit dominance at all.

Relationship to other genetic concepts

Dominance can be influenced by various genetic interactions and it is essential to evaluate them when determining phenotypic outcomes. Multiple alleles, epistasis and pleiotropic genes are some factors that might influence the phenotypic outcome.

Multiple alleles

Main article: Allele § Multiple alleles

Although any individual of a diploid organism has at most two different alleles at a given locus, most genes exist in a large number of allelic versions in the population as a whole. This is called polymorphism, and is caused by mutations. Polymorphism can have an effect on the dominance relationship and phenotype, which is observed in the ABO blood group system. The gene responsible for human blood type have three alleles; A, B, and O, and their interactions result in different blood types based on the level of dominance the alleles expresses towards each other.

Pleiotropic genes

Main article: Pleiotropy

Pleiotropic genes are genes where one single gene affects two or more characters (phenotype). This means that a gene can have a dominant effect on one trait, but a more recessive effect on another trait.

Epistasis

Main article: Epistasis

Epistasis is interactions between multiple alleles at different loci. Easily said, several genes for one phenotype. The dominance relationship between alleles involved in epistatic interactions can influence the observed phenotypic ratios in offspring.

See also

References

  1. "dominance". Oxford Dictionaries Online. Oxford University Press. Archived from the original on July 18, 2012. Retrieved 14 May 2014.
  2. "express". Oxford Dictionaries Online. Oxford University Press. Archived from the original on July 18, 2012. Retrieved 14 May 2014.
  3. Eggers, Stefanie; Sinclair, Andrew (2012). "Mammalian sex determination—insights from humans and mice". Chromosome Res. 20 (1). Dordrecht: Springer-Verlag: 215–238. doi:10.1007/s10577-012-9274-3. hdl:11343/270255. ISSN 0967-3849. PMC 3279640. PMID 22290220.
  4. Bateson, William; Mendel, Gregor (2009). Mendel's Principles of Heredity: A Defence, with a Translation of Mendel's Original Papers on Hybridisation. Cambridge University Press. doi:10.1017/CBO9780511694462. ISBN 978-1108006132.
  5. ^ Billiard, Sylvain; Castric, Vincent; Llaurens, Violaine (2021). "The integrative biology of genetic dominance". Biol Rev Camb Philos Soc. 96 (6). Oxford, UK: Oxford, UK: Blackwell Publishing Ltd: 2925–2942. doi:10.1111/brv.12786. PMC 9292577. PMID 34382317.
  6. Griffiths AJF; Gelbart WM; Miller JH; et al. (1999). "Gene Interaction Leads to Modified Dihybrid Ratios". Modern Genetic Analysis. New York: W. H. Freeman & Company. ISBN 978-0-7167-3118-4.
  7. Mayo, O. and Bürger, R. 1997. The evolution of dominance: A theory whose time has passed? Archived 2016-03-04 at the Wayback Machine "Biological Reviews", Volume 72, Issue 1, pp. 97–110
  8. Bourguet, D. 1999. The evolution of dominance Archived 2016-08-29 at the Wayback Machine Heredity, Volume 83, Number 1, pp. 1–4
  9. Bagheri, H.C. 2006. Unresolved boundaries of evolutionary theory and the question of how inheritance systems evolve: 75 years of debate on the evolution of dominance Archived 2019-07-02 at the Wayback Machine "Journal of Experimental Zoology Part B: Molecular and Developmental Evolution", Volume 306B, Issue 4, pp. 329–359
  10. Rodríguez-Beltrán, Jerónimo; Sørum, Vidar; Toll-Riera, Macarena; de la Vega, Carmen; Peña-Miller, Rafael; San Millán, Álvaro (2020). "Genetic dominance governs the evolution and spread of mobile genetic elements in bacteria". Proc Natl Acad Sci U S A. 117 (27). United States: United States: National Academy of Sciences: 15755–15762. Bibcode:2020PNAS..11715755R. doi:10.1073/pnas.2001240117. ISSN 0027-8424. PMC 7355013. PMID 32571917.
  11. Trudy, F. C. Mackay; Robert, R. H. Anholt (2022). "Gregor Mendel's legacy in quantitative genetics". PLOS Biology. 20 (7). Public Library of Science (PLoS): e3001692. doi:10.1371/journal.pbio.3001692. ISSN 1544-9173. PMC 9295954. PMID 35852997.
  12. Alberts, Bruce; Heald, Rebecca; Hopkin, Karen; Johnson, Alexander; Morgan, David; Roberts, Keith; Walter, Peter (2023). Essential cell biology (Sixth edition.; International student ed.). W.W. Norton & Company. ISBN 9781324033394.
  13. Bulinski, Steven (2016-01-05). "A Crash Course in Reptile Genetics". Reptiles. Living World Media. Archived from the original on 2020-02-04. Retrieved 2023-02-03. The term co-dominant is often used interchangeably with incomplete dominant, but the two terms have different meanings.
  14. ^ Brown, T. A. (2018). Genomes 4 (4th ed.). Milton: Milton: Garland Science. doi:10.1201/9781315226828. ISBN 9780815345084. S2CID 239528980.
  15. ^ Ingelman-Sundberg, M. (2005). "Genetic polymorphisms of cytochrome P450 2D6 (CYP2D6): clinical consequences, evolutionary aspects and functional diversity". Pharmacogenomics J. 5 (1). United States: United States: Nature Publishing Group: 6–13. doi:10.1038/sj.tpj.6500285. ISSN 1470-269X. PMID 15492763. S2CID 10695794.
  16. Yamamoto, F; Clausen, H; White, T; Marken, J; Hakomori, S (1990). "Molecular genetic basis of the histo-blood group ABO system". Nature. 345 (6272): 229–233. Bibcode:1990Natur.345..229Y. doi:10.1038/345229a0. PMID 2333095. S2CID 4237562.
  17. Du, Qingzhang; Tian, Jiaxing; Yang, Xiaohui; Pan, Wei; Xu, Baohua; Li, Bailian; Ingvarsson, Pär K.; Zhang, Deqiang (2015). "Identification of additive, dominant, and epistatic variation conferred by key genes in cellulose biosynthesis pathway in Populus tomentosa". DNA Res. 22 (1). England: England: Oxford University Press: 53–67. doi:10.1093/dnares/dsu040. ISSN 1340-2838. PMC 4379978. PMID 25428896.
  18. Phillips, Patrick C (2008). "Epistasis - the essential role of gene interactions in the structure and evolution of genetic systems". Nat Rev Genet. 9 (11). London: London: Nature Publishing Group: 855–867. doi:10.1038/nrg2452. ISSN 1471-0056. PMC 2689140. PMID 18852697.

External links

Categories: