Litcius/Paper detail

Tackling redundancy: genetic mechanisms underlying paralog compensation in plants

Sessen Daniel Iohannes, David Jackson

2023New Phytologist56 citationsDOIOpen Access PDF

Abstract

Gene duplication is a powerful source of biological innovation giving rise to paralogous genes that undergo diverse fates. Redundancy between paralogous genes is an intriguing outcome of duplicate gene evolution, and its maintenance over evolutionary time has long been considered a paradox. Redundancy can also be dubbed 'a geneticist's nightmare': It hinders the predictability of genome editing outcomes and limits our ability to link genotypes to phenotypes. Genetic studies in yeast and plants have suggested that the ability of ancient redundant duplicates to compensate for dosage perturbations resulting from a loss of function depends on the reprogramming of gene expression, a phenomenon known as active compensation. Starting from considerations on the stoichiometric constraints that drive the evolutionary stability of redundancy, this review aims to provide insights into the mechanisms of active compensation between duplicates that could be targeted for breaking paralog dependencies - the next frontier in plant functional studies.

Topics & Concepts

BiologyRedundancy (engineering)Gene duplicationFunctional divergenceGeneReprogrammingPhenotypeGeneticsSubfunctionalizationEvolutionary biologyPredictabilityGenomeComputational biologyGene familyComputer scienceQuantum mechanicsPhysicsOperating systemCRISPR and Genetic EngineeringRNA and protein synthesis mechanismsPlant tissue culture and regeneration