Ion-mediated condensation controls the mechanics of mitotic chromosomes.

During mitosis in eukaryotic cells, mechanical forces generated by the mitotic spindle pull the sister chromatids into the nascent daughter cells. How do mitotic chromosomes achieve the necessary mechanical stiffness and stability to maintain their integrity under these forces? Here we use optical tweezers to show that ions involved in physiological chromosome condensation are crucial for chromosomal stability, stiffness and viscous dissipation. We combine these experiments with high-salt histone depletion and theory to show that chromosomal elasticity originates from the chromatin fibre behaving as a flexible polymer, whereas energy dissipation can be explained by modelling chromatin loops as an entangled polymer solution.

Replication fork barriers to study site-specific DNA replication perturbation.

DNA replication ensures the complete and accurate duplication of the genome. The traditional approach to analysing perturbation of DNA replication is to use chemical inhibitors, such as hydroxyurea or aphidicolin, that slow or stall replication fork progression throughout the genome. An alternative approach is to perturb replication at a single site in the genome that permits a more forensic investigation of the cellular response to the stalling or disruption of a replication fork.

PICH deficiency limits the progression of MYC-induced B-cell lymphoma.

Plk1-interacting checkpoint helicase (PICH) is a DNA translocase involved in resolving ultrafine anaphase DNA bridges and, therefore, is important to safeguard chromosome segregation and stability. PICH is overexpressed in various human cancers, particularly in lymphomas such as Burkitt lymphoma, which is caused by MYC translocations. To investigate the relevance of PICH in cancer development and progression, we have combined novel PICH-deficient mouse models with the Eμ-Myc transgenic mouse model, which recapitulates B-cell lymphoma development.