Abstract

{beta}- and {gamma}-cytoplasmic-actin are nearly indistinguishable in their amino acid sequence, but are encoded by different genes that play non-redundant biological roles. The key determinants that drive their functional distinction are unknown. Here we tested the hypothesis that {beta}- and {gamma}-actin functions are defined by their nucleotide, rather than their amino acid sequence, using targeted editing of the mouse genome. Although previous studies have shown that disruption of {beta}-actin gene critically impacts cell migration and mouse embryogenesis, we demonstrate here that generation of a mouse lacking {beta}-actin protein by editing {beta}-actin gene to encode {gamma}-actin protein, and vice versa, does not affect cell migration and/or organism survival. Our data suggest that the essential in vivo function of {beta}-actin is provided by the gene sequence independent of the encoded protein isoform. We propose that this regulation constitutes a global \"silent code\" mechanism that controls the functional diversity of protein isoforms.