Litcius/Paper detail

Protein diversification through post-translational modifications, alternative splicing, and gene duplication

Yonathan Goldtzvik, Neeladri Sen, Su Datt Lam, Christine Orengo

2023Current Opinion in Structural Biology46 citationsDOIOpen Access PDF

Abstract

Proteins provide the basis for cellular function. Having multiple versions of the same protein within a single organism provides a way of regulating its activity or developing novel functions. Post-translational modifications of proteins, by means of adding/removing chemical groups to amino acids, allow for a well-regulated and controlled way of generating functionally distinct protein species. Alternative splicing is another method with which organisms possibly generate new isoforms. Additionally, gene duplication events throughout evolution generate multiple paralogs of the same genes, resulting in multiple versions of the same protein within an organism. In this review, we discuss recent advancements in the study of these three methods of protein diversification and provide illustrative examples of how they affect protein structure and function.

Topics & Concepts

Gene duplicationAlternative splicingBiologyGeneOrganismComputational biologyRNA splicingGeneticsFunction (biology)Gene isoformModel organismProtein functionRNARNA and protein synthesis mechanismsProtein Structure and DynamicsFungal and yeast genetics research
Protein diversification through post-translational modifications, alternative splicing, and gene duplication | Litcius