16.4:
Complementation Tests
Sometimes, different mutations can produce the same phenotype, such as loss of coloration in bird feathers. Whether these mutations are in the same gene or in two different genes, can be determined using a complementation test.
Consider the breeding between two mutant chickens. If the same gene is mutated in both parents, the offspring will inherit the mutation and appear white.
On the other hand, if the offspring appears brown like the wild-type bird, then this would indicate that the parents had mutations in two different genes.
Although each parental gene had a mutation, they worked together to produce a wild-type phenotype. This phenomenon is called complementation.
16.4:
Complementation Tests
A complementation test is a simple cross to identify whether the two mutations are located on the same gene or different genes. It was first performed by Edward Lewis in the 1940s while working on fruit flies. He developed the test to identify the location and arrangement of different mutations on chromosomes.
Organisms heterozygous for different mutations are crossed pairwise in all combinations. If present on different genes, the mutations can complement each other by providing the missing genetic element producing a wild-type phenotype. However, if both mutations belong to the same gene, they cannot complement each other and fail to exhibit the wild-type phenotype. The mutations that fail to complement each other are said to be in the same complementation group. The mutations that complement each other belong to different complementation groups.
Suggested Reading
- Bernstein, Harris, Henry C. Byerly, Frederic A. Hopf, and Richard E. Michod. "Genetic damage, mutation, and the evolution of sex." Science 229, no. 4719 (1985): 1277-1281.