User:Jrobins2/Forward Genetics

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Forward Genetics is an approach that encompasses several means of identifying the gene or set of genes that are responsible for a particular phenotype within an organism. Initially, this entailed the generation of random mutations in an organism, often through radiation, and then through a series of breeding of subsequent generations, isolating individuals with an aberrant phenotype, though there are today many different means of following the general path of altering the genotype to witness the phenotype, several which within the genomic era can be useful in study of [functional genomics]. Forward genetics can be thought of as a counter to reverse genetics, which seeks to alter genes in order to illuminate their multiple phenotypes.

Classical Forward Genetics

By the classical genetics approach, a researcher would then locate (map) the gene on its chromosome by crossbreeding with individuals that carry other unusual traits and collecting statistics on how frequently the two traits are inherited together. Classical geneticists would have used phenotypic traits to map the new mutant alleles. Eventually the hope is that such screens would reach a large enough scale that most or all newly generated mutations would represent a second hit of a loci, essentially saturating the genome with mutations. This type of saturation mutagenesis within classical experiments was used to define sets of genes that were a bare minimum for the appearance of specific phenotypes.^[1] However, such initial screens were either incomplete as they were missing redundant loci and epigenetic effects, and such screens were difficult to undertake for certain phenotypes that lack directing measurable phenotypes.

References

1. A Primer of Genome Science, Third Edition. Greg Gibson and Spencer V. Muse. 2009. Sinauer Press

External links