Inheritance of phenotype in mammalian cells: genetic vs. epigenetic mechanisms

Abstract

Inherited phenotypic changes in cultured cells, as observed during differentiation and transformation, reflect alterations in gene expression and have both a genetic and epigenetic basis. The causes of specific changes are often difficult to define especially when observing phenomenological end points. Although such observations are an important step in defining the phenotypic changes that endure for multiple generations, it is necessary to analyze cells at the molecular level to characterize the pathways leading to changes in phenotype. Gene expression can be regulated at multiple levels, i.e., DNA structure, gene transcription, and/or posttranscriptional modifications. Four genetic mechanisms (DNA point mutations, deletion, rearrangement, and amplification) and two epigenetic mechanisms (DNA methylation and the preservation of DNA-protein complexes) can account for the majority of enduring changes observed in cultured cells. Genetic alterations in DNA sequence appear to be largely responsible for altered growth regulation associated with transformation, but there is also evidence to suggest that epigenetic mechanisms play a role in transformation. Differentiation of cultured cells is often associated with lack of growth, and has been ascribed in part to epigenetic mechanisms. However, differentiation and transformation are not mutually exclusive but may be regulated by parallel multistep pathways. Analysis of the causes underlying transformation has been complicated by the use of aneuploid cells, but it is clear that the tools for overcoming the ambiguities associated with phenomenological analysis are available.