- Since human cells carry two copies of each chromosome they have two versions of each gene. These different versions of a gene are called alleles.
- Alleles can be either dominant or recessive.
- Dominant alleles show their effect even if the individual only has one copy of the allele [also known as being heterozygous]. For example, the allele for brown eyes is dominant, therefore you only need one copy of the ‘brown eye’ allele to have brown eyes [although, with two copies you will still have brown eyes].
- If both alleles are dominant, it is called codominance. The resulting characteristic is due to both alleles being expressed equally. An example of this is the blood group AB which is the result of codominance of the A and B dominant alleles.
- Recessive alleles only show their effect if the individual has two copies of the allele [also known as being homozygous]. For example, the allele for blue eyes is recessive, therefore to have blue eyes you need to have two copies of the ‘blue eye’ allele.
Illustration to show the inheritance of dominant and recessive alleles for eye colour.
Image credit: Genome Research Limited
What are sex-linked genes?
- Some genes are found on the sex chromosome, X.
- These genes are inherited with the X chromosome [from the mother if it is a boy or from either mother or father if it is a girl].
- Females have two X chromosomes [XX], while males have one X chromosome and one Y chromosome [XY].
- This means females have two alleles for X-linked genes while males only have one.
- Some genetic diseases, are caused by sex linked genes, for example haemophilia.
- The allele for haemophilia is recessive so two copies are needed for a female to have the disease
- However, because males only have one X chromosome, they only need one copy of the haemophilia allele to have the disease.
- This means haemophilia is much more common in males than in females.
For example:
Functioning allele = H
Haemophilia allele = h
XH XH = healthy female
XH Xh = carrier female
Xh Xh = haemophilia female
XH Y = healthy male
Xh Y = haemophilia male
This page was last updated on 2021-07-21
In one sense, the term “genotype”—like the term “genome”—refers to the entire set of genes in the cells of an organism. In a narrower sense, however, it can refer to different alleles, or variant forms of a gene, for particular traits, or characteristics. An organism’s genotype is in contrast with its phenotype, which is the individual’s observable characteristics, resulting from interactions between the genotype and the environment.
There is a complex connection between the genotype and the phenotype. Since the phenotype is the result of an interaction between genes and the environment, different environments can lead to different traits in individuals with a particular genotype.
In addition, different genotypes can lead to the same phenotype. This happens because genes have different alleles. For some genes and traits, certain alleles are dominant while others are recessive. A dominant trait is one that shows up in an individual, even if the individual has only one allele">allele that produces the trait.
Some aspects of eye color work this way. Brown eyes, for instance, are dominant over blue eyes. This is because a pigment called melanin produces the brown color, while having no pigment leads to blue eyes. Having just one allele for the dark pigment is enough to make your eyes brown. There actually are several different pigments that affect eye color, each pigment resulting from a particular gene. This is the reason why people can have green eyes, hazel eyes, or any of a range of eye colors apart from blue or brown.
When discussing genotype, biologists use uppercase letters to stand for dominant alleles and lowercase letters to stand for recessive alleles. With eye color, for instance, “B” stands for a brown allele and “b” stands for a blue allele. An organism with two dominant alleles for a trait is said to have a homozygous dominant genotype. Using the eye color example, this genotype is written BB. An organism with one dominant allele and one recessive allele is said to have a heterozygous genotype. In our example, this genotype is written Bb. Finally, the genotype of an organism with two recessive alleles is called homozygous recessive. In the eye color example, this genotype is written bb.
Of these three genotypes, only bb, the homozygous recessive genotype, will produce a phenotype of blue eyes. The heterozygous genotype and the homozygous dominant genotype both will produce brown eyes, though only the heterozygous genotype can pass on the gene for blue eyes.
The homozygous dominant, homozygous recessive, and heterozygous genotypes only account for some genes and some traits. Most traits actually are more complex, because many genes have more than two alleles, and many alleles interact in complex ways.