Mcm2 deficiency results in short deletions allowing high resolution identification of genes contributing to lymphoblastic lymphoma.

Mini-chromosome maintenance (Mcm) proteins are part of the replication-licensing complex that is loaded onto chromatin during the G1-phase of the cell cycle and required for initiation of DNA replication in the subsequent S-phase. Mcm proteins are typically loaded in excess of the number of locations that are used during S-phase. Nonetheless, partial depletion of Mcm proteins leads to cancers and stem cell deficiencies. Mcm2 deficient mice, on a 129Sv genetic background, display a high rate of thymic lymphoblastic lymphoma. Here array comparative genomic hybridization is used to characterize the genetic damage accruing in these tumors. The predominant events are deletions averaging less than 0.5 Mbp, considerably shorter than observed in prior studies using alternative mouse lymphoma models or human tumors. Such deletions facilitate identification of specific genes and pathways responsible for the tumors. Mutations in many genes that have been implicated in human lymphomas are recapitulated in this mouse model. These features, and the fact that the mutation underlying the accelerated genetic damage does not target a specific gene or pathway a priori, are valuable features of this mouse model for identification of tumor suppressor genes. Genes affected in all tumors include Pten, Tcfe2a, Mbd3 and Setd1b. Notch1 and additional genes are affected in subsets of tumors. The high frequency of relatively short deletions is consistent with elevated recombination between nearby stalled replication forks in Mcm2-deficient mice.

DNA damage response and tumorigenesis in Mcm2-deficient mice.

Minichromosome maintenance proteins (Mcm's) are components of the DNA replication licensing complex. In vivo, reduced expression or activity of Mcm's has been shown to result in highly penetrant early onset cancers (Shima et al., 2007; Pruitt et al., 2007) and stem cell deficiencies (Pruitt et al., 2007). Here we use mouse embryonic fibroblasts from an Mcm2-deficient strain of mice to show by DNA fiber analysis that origin usage is decreased in Mcm2-deficient cells under conditions of hydroxyurea (HU)-mediated replication stress. DNA damage responses (DDRs) resulting from HU and additional replication-dependent and replication-independent genotoxic agents were also examined and shown to function at wild-type (wt) levels. Further, basal levels of many components of the DDR were expressed at wt levels, showing that there is no acute replicative stress under normal growth conditions. Only very modest, 1.5- to 2-fold increases in the basal levels of gamma-H2AX, p21(cip1) and 53bp foci were found, consistent with a slight chronic elevation in DDR pathways. The one condition in which a larger difference between wt- and Mcm2-deficient cells was found occurred after ultraviolet irradiation and may reflect the role of Chk1-mediated suppression of dormant origins. In vivo, abrogating p53-mediated DDR in Mcm2-deficient mice results in increased embryonic lethality and accelerated cancer formation in surviving mice. Further, p53 mutation rescues the negative effect of Mcm2 deficiency on the survival of neural stem cells in vitro; however, the enhanced survival correlates with increased genetic damage relative to Mcm2 wt cells carrying the p53 mutation. Together these results show that even relatively minor perturbations to primary or dormant replication origin usage contribute to accelerated genetic damage in vivo. In addition, these studies show that tumor types resulting from Mcm2 deficiency are strongly affected by interaction with both genetic background and p53.

Regulation of DNA synthesis by the higher-order chromatin structure.

Mouse erythroleukemia cells were treated with the topoisomerase II poison VP-16, the intrastrand crosslinking agent cis-DDP, and the ribonucleotide reductase inhibitor hydroxyurea. In all cases, the rate of DNA synthesis decreased as a result of the treatment. To study the mechanism of inhibition of DNA chain elongation, we determined DNA synthesis in a cell-free replication system containing isolated nuclei and cytoplasmic extracts. The rate of DNA synthesis in the reactions containing nuclei isolated from untreated cells and extracts from cells treated with the three drugs were slightly reduced and did not show significant differences between the drugs. In the systems containing nuclei from cells treated with cis-DDP, DNA synthesis was again slightly inhibited; synthesis in nuclei treated with hydroxyurea was enhanced, and synthesis in the systems containing nuclei from cells treated with VP-16 was significantly reduced. DNA synthesis was reduced to the same extent in a system containing nuclei isolated from untreated cells that had been briefly sonicated to introduce a limited number of double-strand breaks in the DNA. As VP-16 and sonication mediate changes in chromatin topology, these results suggest that, along with the trans-acting signal transduction pathways, there is a topologic mechanism for regulation of DNA synthesis in the S phase of the cell cycle.

Clusters of replicons that fire simultaneously may be organized into superloops.

To study the relation between replicon initiation and nuclear organization of DNA, mouse erythroleukemia F4N cells were irradiated with 60Co source and the rates of initiation of DNA synthesis were determined by a sensitive assay based on the introduction of Trioxsalen cross-links in DNA in vivo and determination of the amount of short nascent DNA fragments synthesized between the cross-links. In parallel, nuclear organization of DNA was monitored using the nucleoid sedimentation technique. The results show that DNA initiation rate and relative nucleoid sedimentation change sharply and simultaneously at doses of about 1 Gy, which suggests the existence of relationship between them. This suggestion was supported by the finding, that during the after-irradiation period, first DNA organization was restored and only after this process had been completed, the restoration of replicon initiation commenced. When cells were treated with novobiocin, an agent that is known to slow down the recovery of nucleoid sedimentation rate, initiation of DNA synthesis was also postponed. A hypothesis is put forward that replicon clusters represent groups of adjacent DNA loops organized in superloop domains and that the intact superloop domain structure is necessary for activation of the cluster.