Duane A. Compton

Examining the link between chromosomal instability and aneuploidy in human cells

Solid tumors can be highly aneuploid and many display high rates of chromosome missegregation in a phenomenon called chromosomal instability (CIN). In principle, aneuploidy is the consequence of CIN, but the relationship between CIN and aneuploidy has not been clearly defined. In this study, we use live cell imaging and clonal cell analyses to evaluate the fidelity of chromosome segregation in chromosomally stable and unstable human cells. We show that improper microtubule–chromosome attachment (merotely) is a cause of chromosome missegregation in unstable cells and that increasing chromosome missegregation rates by elevating merotely during consecutive mitoses generates CIN in otherwise stable, near-diploid cells. However, chromosome missegregation compromises the proliferation of diploid cells, indicating that phenotypic changes that permit the propagation of nondiploid cells must combine with elevated chromosome missegregation rates to generate aneuploid cells with CIN.

Mechanisms of Chromosomal Instability

Most solid tumors are aneuploid, having a chromosome number that is not a multiple of the haploid number, and many frequently mis-segregate whole chromosomes in a phenomenon called chromosomal instability (CIN). CIN positively correlates with poor patient prognosis, indicating that reduced mitotic fidelity contributes to cancer progression by increasing genetic diversity among tumor cells. Here, we review the mechanisms underlying CIN, which include defects in chromosome cohesion, mitotic checkpoint function, centrosome copy number, kinetochore-microtubule attachment dynamics, and cell-cycle regulation. Understanding these mechanisms provides insight into the cellular consequences of CIN and reveals the possibility of exploiting CIN in cancer therapy.

CENP-E, a novel human centromere-associated protein required for progression from metaphase to anaphase.

We have identified a novel human centromere‐associated protein by preparing monoclonal antibodies against a fraction of HeLa chromosome scaffold proteins enriched for centromere/kinetochore components. One monoclonal antibody (mAb177) specifically stains the centromere region of mitotic human chromosomes and binds to a novel, approximately 250–300 kd chromosome scaffold associated protein named CENP‐E. In cells progressing through different parts of the cell cycle, the localization of CENP‐E differed markedly from that observed for the previously identified centromere proteins CENP‐A, CENP‐B, CENP‐C and CENP‐D. In contrast to these antigens, no mAb177 staining is detected during interphase, and staining first appears at the centromere region of chromosomes during prometaphase. This association with chromosomes remains throughout metaphase but is redistributed to the midplate at or just after the onset of anaphase. By telophase, the staining is localized exclusively to the midbody. Microinjection of the mAb177 into metaphase cells blocks or significantly delays progression into anaphase, although the morphology of the spindle and the configuration of the metaphase chromosomes appear normal in these metaphase arrested cells. This demonstrates that CENP‐E function is required for the transition from metaphase to anaphase.

Proliferation of aneuploid human cells is limited by a p53-dependent mechanism

After chromosome missegregation, the growth of nondiploid cells is inhibited thanks to a p53-dependent mechanism.

Genome stability is ensured by temporal control of kinetochore-microtubule dynamics

Most solid tumours are aneuploid and many frequently mis-segregate chromosomes. This chromosomal instability is commonly caused by persistent mal-oriented attachment of chromosomes to spindle microtubules. Chromosome segregation requires stable microtubule attachment at kinetochores, yet those attachments must be sufficiently dynamic to permit correction of mal-orientations. How this balance is achieved is unknown, and the permissible boundaries of attachment stability versus dynamics essential for genome stability remain poorly understood. Here we show that two microtubule-depolymerizing kinesins, Kif2b and MCAK, stimulate kinetochore–microtubule dynamics during distinct phases of mitosis to correct mal-orientations. Few-fold reductions in kinetochore–microtubule turnover, particularly in early mitosis, induce severe chromosome segregation defects. In addition, we show that stimulation of microtubule dynamics at kinetochores restores stability to chromosomally unstable tumour cell lines, establishing a causal relationship between deregulation of kinetochore–microtubule dynamics and chromosomal instability. Thus, temporal control of microtubule attachment to chromosomes during mitosis is central to genome stability in human cells.

Binding of matrix attachment regions to lamin polymers involves single-stranded regions and the minor groove.

Chromatin in eukaryotic nuclei is thought to be partitioned into functional loop domains that are generated by the binding of defined DNA sequences, named MARs (matrix attachment regions), to the nuclear matrix. We have previously identified B-type lamins as MAR-binding matrix components (M. E. E. Ludérus, A. de Graaf, E. Mattia, J. L. den Blaauwen, M. A. Grande, L. de Jong, and R. van Driel, Cell 70:949-959, 1992). Here we show that A-type lamins and the structurally related proteins desmin and NuMA also specifically bind MARs in vitro. We studied the interaction between MARs and lamin polymers in molecular detail and found that the interaction is saturable, of high affinity, and evolutionarily conserved. Competition studies revealed the existence of two different types of interaction related to different structural features of MARs: one involving the minor groove of double-stranded MAR DNA and one involving single-stranded regions. We obtained similar results for the interaction of MARs with intact nuclear matrices from rat liver. A model in which the interaction of nuclear matrix proteins with single-stranded MAR regions serves to stabilize the transcriptionally active state of chromatin is discussed.

Deviant kinetochore-microtubule dynamics underlie chromosomal instability

The persistent malattachment of microtubules to chromosomes at kinetochores is a major mechanism of chromosomal instability (CIN) [1, 2]. In normal diploid cells, malattachments arise spontaneously and are efficiently corrected to preserve genomic stability [3]. However, it is unknown whether cancer cells with CIN possess the ability to efficiently correct attachment errors. Here we show that kinetochore microtubule attachments in cancer cells with CIN are inherently more stable than those in normal diploid RPE-1 cells. The observed differences in attachment stability account for the persistence of malattachments into anaphase, where they cause chromosome missegregation. Furthermore, increasing the stability of kinetochore microtubule attachments in normal diploid RPE-1 cells, either by depleting the tumor suppressor protein APC or the kinesin-13 protein MCAK, is sufficient to promote chromosome segregation defects to levels comparable to those in cancer cells with CIN. Collectively, these data identify that cancer cells have a diminished capacity to correct erroneous kinetochore microtubule attachments and account for the widespread occurrence of CIN in tumors [4].

The KinI kinesin Kif2a is required for bipolar spindle assembly through a functional relationship with MCAK

Although the microtubule-depolymerizing KinI motor Kif2a is abundantly expressed in neuronal cells, we now show it localizes to centrosomes and spindle poles during mitosis in cultured cells. RNAi-induced knockdown of Kif2a expression inhibited cell cycle progression because cells assembled monopolar spindles. Bipolar spindle assembly was restored in cells lacking Kif2a by treatments that altered microtubule assembly (nocodazole), eliminated kinetochore–microtubule attachment (loss of Nuf2), or stabilized microtubule plus ends at kinetochores (loss of MCAK). Thus, two KinI motors, MCAK and Kif2a, play distinct roles in mitosis, and MCAK activity at kinetochores must be balanced by Kif2a activity at poles for spindle bipolarity. These treatments failed to restore bipolarity to cells lacking the activity of the kinesin Eg5. Thus, two independent pathways contribute to spindle bipolarity, with the Eg5-dependent pathway using motor force to drive spindle bipolarity and the Kif2a-dependent pathway relying on microtubule polymer dynamics to generate force for spindle bipolarity.

The chromokinesin Kid is necessary for chromosome arm orientation and oscillation, but not congression, on mitotic spindles

Chromokinesins have been postulated to provide the polar ejection force needed for chromosome congression during mitosis. We have evaluated that possibility by monitoring chromosome movement in vertebrate-cultured cells using time-lapse differential interference contrast microscopy after microinjection with antibodies specific for the chromokinesin Kid. 17.5% of cells injected with Kid-specific antibodies have one or more chromosomes that remain closely opposed to a spindle pole and fail to enter anaphase. In contrast, 82.5% of injected cells align chromosomes in metaphase, progress to anaphase, and display chromosome velocities not significantly different from control cells. However, injected cells lack chromosome oscillations, and chromosome orientation is atypical because chromosome arms extend toward spindle poles during both congression and metaphase. Furthermore, chromosomes cluster into a mass and fail to oscillate when Kid is perturbed in cells containing monopolar spindles. These data indicate that Kid generates the polar ejection force that pushes chromosome arms away from spindle poles in vertebrate-cultured cells. This force increases the efficiency with which chromosomes make bipolar spindle attachments and regulates kinetochore activities necessary for chromosome oscillation, but is not essential for chromosome congression.

Minus-end capture of preformed kinetochore fibers contributes to spindle morphogenesis

Near-simultaneous three-dimensional fluorescence/differential interference contrast microscopy was used to follow the behavior of microtubules and chromosomes in living α-tubulin/GFP-expressing cells after inhibition of the mitotic kinesin Eg5 with monastrol. Kinetochore fibers (K-fibers) were frequently observed forming in association with chromosomes both during monastrol treatment and after monastrol removal. Surprisingly, these K-fibers were oriented away from, and not directly connected to, centrosomes and incorporated into the spindle by the sliding of their distal ends toward centrosomes via a NuMA-dependent mechanism. Similar preformed K-fibers were also observed during spindle formation in untreated cells. In addition, upon monastrol removal, centrosomes established a transient chromosome-free bipolar array whose orientation specified the axis along which chromosomes segregated. We propose that the capture and incorporation of preformed K-fibers complements the microtubule plus-end capture mechanism and contributes to spindle formation in vertebrates.