Abstract
The origin of novel protein-coding genes de novo was once considered so improbable as to be impossible. In less than a decade, and especially in the last five years, this view has been overturned by extensive evidence from diverse eukaryotic lineages. There is now evidence that this mechanism has contributed a significant number of genes to genomes of organisms as diverse as Saccharomyces, Drosophila, Plasmodium, Arabidopisis and human. From simple beginnings, these genes have in some instances acquired complex structure, regulated expression and important functional roles. New genes are often thought of as dispensable late additions; however, some recent de novo genes in human can play a role in disease. Rather than an extremely rare occurrence, it is now evident that there is a relatively constant trickle of proto-genes released into the testing ground of natural selection. It is currently unknown whether de novo genes arise primarily through an ‘RNA-first’ or ‘ORF-first’ pathway. Either way, evolutionary tinkering with this pool of genetic potential may have been a significant player in the origins of lineage-specific traits and adaptations.
Highlights
A persistent and fundamental question in evolutionary genetics concerns the origin of genetic novelty [1,2,3]
New loci are free of such constraints and constitute genetic novelty that may form the basis for lineage-specific adaptations and diversification [6,7,8]
The most radical form of genetic novelty comes from genes that originate de novo from non-genic DNA in that they are not similar to any pre-existing genes
Summary
A persistent and fundamental question in evolutionary genetics concerns the origin of genetic novelty [1,2,3]. It is possible for novel functions to arise within an existing gene [4], it is likely that there will be some degree of antagonism or adaptive conflict between the new and the old functions The most radical form of genetic novelty comes from genes that originate de novo from non-genic DNA in that they are not similar to any pre-existing genes. Both protein-coding and RNA genes are important, but for the purposes of this perspective we will only consider the former. Protein-coding genes must have arisen de novo from non-coding sequence in very early life evolution. In recent years, there has been a growing appreciation for the role of de novo gene origination
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