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Asymmetric Histone Inheritance: Establishment, Recognition, and Execution

Jennifer A. Urban, Rajesh Ranjan, Xin Chen

2022Annual Review of Genetics18 citationsDOIOpen Access PDF

Abstract

male germline stem cells demonstrates one means to produce two distinct daughter cells with identical genetic material. This inspired further studies in different systems, which revealed that this phenomenon may be a widespread mechanism to introduce cellular diversity. While the extent of asymmetric histone inheritance could vary among systems, this phenomenon is proposed to occur in three steps: first, establishment of histone asymmetry between sister chromatids during DNA replication; second, recognition of sister chromatids carrying asymmetric histone information during mitosis; and third, execution of this asymmetry in the resulting daughter cells. By compiling the current knowledge from diverse eukaryotic systems, this review comprehensively details and compares known chromatin factors, mitotic machinery components, and cell cycle regulators that may contribute to each of these three steps. Also discussed are potential mechanisms that introduce and regulate variable histone inheritance modes and how these different modes may contribute to cell fate decisions in multicellular organisms.

Topics & Concepts

Sister chromatidsBiologyGeneticsHistoneMulticellular organismChromatinEstablishment of sister chromatid cohesionPolytene chromosomeInheritance (genetic algorithm)Histone codeCell biologyHistone H1MitosisDrosophila melanogasterDNACellNucleosomeChromosomeGeneGenomics and Chromatin DynamicsChromosomal and Genetic VariationsPlant Molecular Biology Research
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