Complementation tests if two different alleles that result in observable phenotypes are part of the same gene or are alleles of different genes. If you have generated a range of mutants phenotypes for a trait it allows these mutations to be quickly grouped by genes (rather than, for example, conducting fine scaled recombinant mapping). Complementation assumes simple dominance where the mutant phenotype is recessive to wild-type.

If there are mutations in the same gene then when homozygous lines are crossed together there is not a wild-type allele present in the heterozygote. Thus, the heterozygote has a mutant phenotype. This is non-complementation and indicates that the two mutants occur at the same gene.

If there are mutations at two different genes then crossing true-breeding (homozygous) lines together generates double heterozygote offspring with a wild-type phenotype. This is complementation and indicates the two mutants occur at different genes.

Examples

Abstract example

Say we have three mutations, a[-], b[-], and c[-], that result in mutant wing phenotypes in Drosophila when homozygous. These mutant phenotypes are recessive to wild-type. First we cross a[-] and b[-] together.

a[-] and b[-] are two different alleles of the same gene and the wild-type phenotype is not restored (they failed to compliment). We can rename these as the a[1] and a[2] alleles.

Now we cross a[1] and c[-] together.

This double heterozygote has a wild-type phenotype because the phenotype corresponding to a[1] and the phenotype corresponding to c- are both recessive to wild-type. We can infer that these are alleles of two different genes because they complemented each other (restored a wild-type phenotype). We rename c- the c[1] allele now that we know it is an allele of a different gene.

Actual example

Classical genetic

You have a collection of eye color phenotypes that vary from wild-type red. You want to see if these are due to alleles of the same gene or of different genes. All of the mutant phenotypes are recessive to wild-type.

First you cross sepia and white together. The offspring are wild-type. You can infer that the offspring are double heterozygotes and that sepia and white are different genes.

Next you cross apricot and white together. The offspring are apricot, not wild-type. You infer that apricot is an allele of white.

Deletion mapping

Heterokaryons

Complementation tables

Pairwise crosses can be made and organized into a complementation table where a + indicates complementation and a - indicates noncomplementation.

In the example table above mutants 1, 3, and 6 form a complementation group (fail to complement each other). Mutants 2 and 4 also form a complementation group. The mutants in this table represent allele at three different genes.

• Gene 1 has mutant alleles 1, 3, and 6.
• Gene 2 has mutant alleles 2 and 4.
• Gene 3 has mutant allele 5.

Exceptions

Exceptions (except for dominant mutant phenotypes) are rare but they can give insights into gene products with functions that are closely associated.

Dominance

Cases where the mutant phenotype is dominant to wild-type, such as gain-of-function hypermorphs violate the assumptions used in complementation testing.

Example

(agouti vy and - amorph)

Intragenic complementation

If mutations that disrupt alternative promoters or alternative splicing variants are responsible for the altered phenotype then having two mutant alleles that are disrupted in different ways can restore a wild-type phenotype.

Example

Unlinked noncomplementation

If gene products from two different genes directly interact, such as subunits in a complex, or their functions are closely associated, such as steps in the same biochemical pathway, they can fail to complement in a double heterozygote.

Example

Links

http://www.wormbook.org/chapters/www_complementation/complementation.html

http://www.genetics.org/content/174/1/5

http://www.cureffi.org/2014/09/08/genetics-03/