G2-M DNA damage checkpoint

The G2-M DNA damage checkpoint is an important cell cycle checkpoint in eukaryotic organisms ranging from yeast to mammals, ensuring that cells don't initiate mitosis until damaged DNA or incompletely replicated DNA is sufficiently repaired after replication. Cells that have a defective G2-M checkpoint enter mitosis before repairing their DNA, leading to apoptosis or death after cell division. The G2-M DNA damage checkpoint is an important cell cycle checkpoint in eukaryotic organisms ranging from yeast to mammals, ensuring that cells don't initiate mitosis until damaged DNA or incompletely replicated DNA is sufficiently repaired after replication. Cells that have a defective G2-M checkpoint enter mitosis before repairing their DNA, leading to apoptosis or death after cell division. The cell cycle is driven by proteins called cyclin dependent kinases that associate with cyclin regulatory proteins at different checkpoints of the cell cycle. Different phases of the cell cycle experience activation and/or deactivation of specific cyclin-CDK complexes. CyclinB-CDK1 activity is specific to the G2/M checkpoint. Accumulation of cyclin B increases the activity of the cyclin dependent kinase Cdk1 human homolog Cdc2 as cells prepare to enter mitosis. Cdc2 activity is further regulated by phosphorylation/dephosphorylation of its corresponding activators and inhibitors. Through a positive feedback loop, CyclinB-Cdc2 activates the phosphatase Cdc25 which in turn deactivates the CyclinB-Cdc2 inhibitors, Wee1 and Myt1. Cdc25 activates the complex through the removal of phosphates from the active site while Wee1 inactivates the complex through the phosphorylation of tyrosine residues, specifically tyrosine-15. This loop is further amplified indirectly through the coordinated interaction of the Aurora A kinase and the Bora cofactor. During the G2 phase, Bora accumulates and forms an activation complex with Aurora A. This complex then regulates the activation of Polo-like kinase 1 (Plk1). Plk1 phosphorylates Wee1, targeting it for degradation through the SCF ubiquitin ligase complex (SCF complex), and activates Cdc25 through phosphorylation with combined action activating Cdc2. The combined activity and complex of Cdc2, Cdc25, and Plk1 with the accumulation of cyclin B activates the CyclinB-Cdc2 complex, promoting entry into mitosis. Many proteins involved in this positive feedback loop drive the activation of the CyclinB-Cdc2 complex because entry into mitosis requires an all-or-none response. The Novak-Tyson model is a mathematical model used to explain such regulatory loop that predicted the irreversible transition into mitosis driven by hysteresis.Through experiments in Xenopus laevis cell-free egg extracts, such model was confirmed as the basis for entry into mitosis. Once cyclin concentration reaches a certain minimum activation threshold, Cdc2 is rapidly activated. It remains in this state until activity falls below a separate inactivation threshold at which it is abruptly inactivated through tyrosine phosphorylation by Wee1 and Myt1. In the case of unreplicated DNA, the cyclin concentration threshold for Cdc2 activation is further increased. Through this mechanism, there exists two separate steady-state conditions separated by an unstable steady state. The bistable and hysteretic nature of CyclinB-Cdc2 ensures a highly regulated nature of the G2/M checkpoint. Proteins that localize to sites of DNA damage in the G2 phase initiate a signaling cascade that regulates important components of the pathway, as described above, therefore controlling mitotic entry via CyclinB-Cdc2 activity. Negative regulation of CyclinB-Cdc2 activity results in a delay in mitotic entry, which is important for cells to repair any DNA damage that may have accumulated after S phase and necessary before cell division can continue. Proteins that function in the G2-M checkpoint were originally identified in yeast screens that looked for mutants which show enhanced sensitivity to radiation, termed 'rad' mutants. Inefficient repair of DNA damaged by ionizing radiation or chemical agents in these mutants revealed proteins essential in this pathway. Early signaling proteins in the checkpoint pathway are members of a family of phosphatidylinositol 3-kinases, rad3 in yeast and ATR in vertebrates, that are believed to localize to sites of DNA damage. Rad3 phosphorylates rad26 which is required to initiate, but not maintain the checkpoint. Rad3 also phosphorylates a number of other proteins whose absence abolishes checkpoint DNA repair, including rad1, rad9, hus1 and rad17. It has been hypothesized that rad9, hus1 and rad17 are similar to proteins involved in forming the clamp that increases the processivity of DNA polymerase during DNA replication. In agreement with this idea, rad17 is similar to proteins involved in loading the clamp onto DNA. This supports a model where phosphorylation by rad3 causes recruitment of these proteins to sites of DNA damage where they mediate the activity of DNA polymerases involved in DNA repair. The main rad3 effector is the kinase Chk1, which is required for the G2-M arrest in response to DNA-damaging agents.Chk1 is an effector protein kinase that maintains mitotic cyclin in an inactive state and is phosphorylated by rad3 between S phase and mitosis, implicating its specific role in G2 arrest.Its upregulation through overexpression can induce arrest independent of DNA damage.In addition, overexpression of Chk1 rescues the radiation sensitivity of rad mutants, presumably by allowing DNA repair to take place before entry into mitosis. The presence of DNA damage triggers the ATM (Ataxia telangiectasia mutated) or ATR (Ataxia Telangiectasia and Rad3 related) pathways which activate the Chk2 and Chk1 kinases, respectively. These kinases act upstream of Cdc25 and Wee1, the direct regulators of the CyclinB-Cdc2 complex. Chk1 and Chk2 phosphorylate Cdc25, inhibiting its phosphorylating activity and marking it for ubiquitinated degradation.These pathways also stimulate the tumor suppressor p53. p53 regulates the function of the Cdk2 inhibitor p21 and the 14-3-3 proteins that phosphorylate (and thereby inactivate) and sequester Cdc25 in the cytoplasm, respectively.Recent studies have also suggested that Cdk1 and 14-3-3 positively regulate Wee1 in a similar manner. The hyperphosphorylation of Wee1 by Cdk1 allows for the binding of 14-3-3, sequestering Wee1 to the nucleus and enhancing its ability to phosphorylate Cdc2. The phosphorylation of both Wee1 and Cdc25 prevents Cdc2 activation.