Spotlight on Geminin

In the previous issue of Breast Cancer Research, Gardner and co-workers describe a novel interaction between Geminin, a protein that prevents reinitiation of DNA replication, and Topoisomerase IIα (TopoIIα), an enzyme essential for removing catenated intertwines between sister chromatids. Geminin facilitates the action of TopoIIα, thereby promoting termination of DNA replication at the same time it inhibits initiation. In this manner, Geminin ensures that cells duplicate their genome once, but only once, each time they divide. Remarkably, either depletion of Geminin or over-expression of Geminin inhibits the action of TopoIIα, thereby making Geminin an excellent target for cancer chemotherapy.

suppression of Geminin has been suggested as a novel strategy for killing cancer cells with little or no eff ect on normal cells [9]. In contrast to normal cells, many cancer cells rely exclusively on Geminin to prevent reinitiation of DNA replication before mitosis is completed. Depletion of Geminin in these cells induces DNA re-replication, which results in accumulation of stalled replication forks and DNA damage. Th is, in turn, triggers apoptosis.
Working with human mammary epithelial (HME) cells, Gardner and colleagues [1] discovered that Geminin facilitates the ability of Topoisomerase IIα (TopoIIα) to bind chromatin and resolve catenated intertwines, and that this trimolecular interaction appears to be regulated by two protein kinases, one (CKIε) that activates TopoIIα, and one (Cdc7-Dbf4) that inhibits TopoIIα. Without TopoIIα activity, sister chromatids accumulate catenated intertwines during S-phase that prevent their separation during mitosis. Th is, in turn, triggers the spindle assembly checkpoint to arrest cells at metaphase and then induce apoptosis. Indeed, several chemo thera peutic drugs promote this reaction by inhibiting TopoIIα. HME cells treated with siRNA against Geminin also rapidly accumulate with 4N DNA content (G2 or M phase) and fail to complete cytokinesis due to chromo some bridges that remain between the two nuclei. Th is means that TopoIIα activity is suppressed during G1 phase when Geminin is absent and Cdc7-Dbf4 is present, but TopoIIα activity is facilitated from S through meta phase when Geminin is present. Th us, Geminin not only suppresses initiation of DNA replication, but also promotes termination of DNA replication forks.
Th ere is, however, a signifi cant diff erence between inhibiting TopoIIα binding to chromatin by suppressing Geminin and chemical inhibition of TopoIIα activity. Chemical inhibitors arrest cells in G2/M phase, but these cells soon by-pass the spindle assembly checkpoint and attempt to replicate their genome, a phenomenon termed 'mitotic slippage' [10]. Mitotic slippage occurs most frequently in cancer cells that lack p53 and Rb, components of checkpoints that prevent premature entrance into S phase. In contrast, siRNA depletion of Geminin in synchronized HME cells also suppressed expression of cyclins E and A1, Cdk1 and Cdk2, which would prevent initiation of DNA replication [11].

Abstract
In the previous issue of Breast Cancer Research, Gardner and co-workers describe a novel interaction between Geminin, a protein that prevents reinitiation of DNA replication, and Topoisomerase IIα (TopoIIα), an enzyme essential for removing catenated intertwines between sister chromatids. Geminin facilitates the action of TopoIIα, thereby promoting termination of DNA replication at the same time it inhibits initiation. In this manner, Geminin ensures that cells duplicate their genome once, but only once, each time they divide. Remarkably, either depletion of Geminin or overexpression of Geminin inhibits the action of TopoIIα, thereby making Geminin an excellent target for cancer chemotherapy. However, this was not observed when Geminin was depleted in ten other cell lines derived from normal human tissues and three from cancer tissues [9]. Th ese cells continued to proliferate normally and re-replicated their DNA only when both Geminin and cyclin A1 were suppressed. Cdk2-cyclin A1 is required in three of the fi ve pathways that prevent DNA re-replication. In vivo, Geminin is largely dispensable for embryonic and adult mammalian neurogenesis [12], and it is not required for self-renewal of hematopoietic stem cells or baseline production of granulocytes or monocytes [13]. Th us, Geminin depletion is a promising therapy for killing cancer cells without interfering with normal cell proliferation.
Remarkably, over-expression of Geminin in HME cells triggers DNA re-replication (production of cells with >4N DNA). Under these conditions, TopoIIα cleaves the DNA without resealing the duplex and then dissociates from chromatin, leaving behind damaged DNA. However, since Geminin over-expression in HME cells is accom panied by suppression of both CHK1 and H2AX (components of the DNA damage response mechanism), and upregulation of cyclin A1 and Cdk1 expression, this allows these cells to re-replicate their DNA and become aneuploid. Since TopoIIα is not associated with chroma tin under these conditions, cells that over-express Geminin will be less sensitive to TopoIIα inhibitors that rely on trapping the TopoIIα-DNA adduct at the site of TopoIIα cleavage. Th us, the natural tendency of cancer cells to over-express Geminin may facilitate their ability to undergo chromosomal rearrangements and to resist the eff ects of TopoIIα inhibitors. Perhaps the high percentage of patients who do not respond to chemotherapeutic inhibitors of TopoIIα would respond if TopoIIα inhibitors were combined with anti-Geminin agents.
Th e eff ects of altering Geminin levels appear to depend on the cell and its genotype. Geminin depletion induces DNA re-replication in most, but not all, cancer cells [1,9]. Conversely, Geminin depletion does not arrest proliferation of non-cancer cells in vitro [9], nor does ablation of the Geminin gene prevent proliferation of all cell types in vivo [12,13]. However, some non-cancer breast cells may arrest in mitosis without inducing DNA re-replication or apoptosis [11]. Over-expression of a nondegradable form of Geminin in primary human fi broblasts arrests them in G1 without apoptosis, whereas over-expression in osteosarcoma cells induces apoptosis [14]. Th e fact that osteosarcoma cells expressing both p53 and Rb arrest in early S phase, whereas osteosarcoma cells that lack these genes accumulate in late S and G2/M, suggests that normal cells contain an 'origin licensing checkpoint' that prevents premature entrance into S phase [15], a hypothesis also supported by suppression of origin licensing proteins [16]. Cancer cells that lack this checkpoint would be vulnerable to drugs that increase Geminin activity. Th us, the ability to selectively kill cancer cells by either depletion or over-expression of Geminin bodes well for Geminin-based chemotherapies, but it remains to be determined through live animal studies just how useful such therapies will be.