Topological Features of Histone H2A Monoubiquitination.

ABSTRACT

The cellular response to DNA damage protects the essential information stored in the genome. This mechanism is crucial in terms of the cancer prevention and aging progression. The DNA damage response (DDR) consists of a complex network controlling the cell cycle and multiple mechanisms of the DNA repair. The DDR disruption is a cornerstone feature of the tumor cells, which allows them to enhance beneficial mutations that prevent successful disease treatment. The important checkpoints of the DDR are currently poorly understood due to the complexity and diversity of the DNA repair machinery. Histone ubiquitination is intensively involved in the repair of the double-stranded DNA breaks. This post-translational modification is known to be a key factor in the recruitment of the repair factors to the DNA damage sites. Here, the crucial role of the ubiquitin lysine residue K27 in the process of histone H2A monoubiquitination mediated by the ubiquitin ligase RNF168 has been showed. The presented data suggest forced and intensive diffusion of ubiquitin from the cytoplasm to the nucleus, which is characterized by the dynamic equilibrium less than 10 min. The comparison of the turnover rate of the wild-type ubiquitin and its variant with a single functional lysine residue K27 suggests an important role of the ubiquitin deposition as a covalent conjugate with histone H2A in terms of the stability of the entire ubiquitinome.