Perturbation of the chromosomal binding of RCC1, Mad2 and survivin causes spindle assembly defects and mitotic catastrophe

Mitotic catastrophe is a form of cell death that results from aberrant mitosis. Currently, the mechanisms involved in this form of cell death remain poorly understood. We found that actinomycin D induces mitotic catastrophe with severe spindle assembly defects. We have studied the nature of three groups of chromosome binding proteins in mitotic cells treated with actinomycin D. We found that actinomycin D reduced the binding affinity of RCC1 to the mitotic chromosome, which led to a reduction of RanGTP level. In addition, Mad2 was not concentrated at the kinetochores, indicating that the mitotic spindle checkpoint was affected. Furthermore, the localization of survivin was altered in cells. These data suggested that chromosomal binding of the mitotic regulators such as RCC1, Mad2 and survivin is essential for mitotic progression. Mitotic chromosomes not only carry the genetic material needed for the newly synthesized daughter cells, but also serve as docking sites for some of the mitotic regulators. Perturbation of their binding to the mitotic chromosome by actinomycin D could affect their functions in regulating mitotic progression thus leading to severe spindle defects and mitotic catastrophe.     

Monoclonal antibody with specificity to mitotic chromosomes of primates

Fusion of a cell in mitosis with a cell in interphase results in the condensation of chromatin in the interphase nucleus into chromosomes. Premature chromosome condensation is caused by certain proteins, called mitotic factors, that are present in the mitotic cell and are localized on chromosomes. Extracts from mitotic cells were used to immunize mice to produce monoclonal antibodies specific for cells in mitosis. Among the antibodies obtained, the MPM-4 antibody defines a 125-kD polypeptide antigen located on mitotic chromosomes by indirect immunofluorescence. Although the polypeptide antigen is present in approximately equal concentrations in extracts of interphase cells and mitotic cells, as revealed by immunoblots, it cannot be detected cytologically in the former. Cell fractionation experiments showed that the 125-kD antigen is found in the cytoplasm of interphase cells and metaphase cells, but is concentrated in fractions containing metaphase chromosomes, although not detectable in interphase nuclei. Even though the antigen is apparently primate-specific, it binds to mitotic chromosomes and prematurely condensed chromosomes in human-rodent cell hybrids without regard to the species of origin of the mitotic inducer. The presence of the antigen in the cytoplasm of interphase cells and the chromosomes of mitotic cells suggests a relationship between the presence of the antigen on chromosomes and the process of chromosome condensation and decondensation.     

Cellular analyses of the mitotic region in the Caenorhabditis elegans adult germ line

The Caenorhabditis elegans germ line provides a model for understanding how signaling from a stem cell niche promotes continued mitotic divisions at the expense of differentiation. Here we report cellular analyses designed to identify germline stem cells within the germline mitotic region of adult hermaphrodites. Our results support several conclusions. First, all germ cells within the mitotic region are actively cycling, as visualized by bromodeoxyuridine (BrdU) labeling. No quiescent cells were found. Second, germ cells in the mitotic region lose BrdU label uniformly, either by movement of labeled cells into the meiotic region or by dilution, probably due to replication. No label-retaining cells were found in the mitotic region. Third, the distal tip cell niche extends processes that nearly encircle adjacent germ cells, a phenomenon that is likely to anchor the distal-most germ cells within the niche. Fourth, germline mitoses are not oriented reproducibly, even within the immediate confines of the niche. We propose that germ cells in the distal-most rows of the mitotic region serve as stem cells and more proximal germ cells embark on the path to differentiation. We also propose that C. elegans adult germline stem cells are maintained by proximity to the niche rather than by programmed asymmetric divisions.     

Association of MAD2 expression with mitotic checkpoint competence in hepatoma cells

Chromosomal instability (CIN) refers to high rates of chromosomal gains and losses and is a major cause of genomic instability of cells. It is thought that CIN caused by loss of mitotic checkpoint contributes to carcinogenesis. In this study, we evaluated the competence of mitotic checkpoint in hepatoma cells and investigated the cause of mitotic checkpoint defects. We found that 6 (54.5%) of the 11 hepatoma cell lines were defective in mitotic checkpoint control as monitored by mitotic indices and flow-cytometric analysis after treatment with microtubule toxins. Interestingly, all 6 hepatoma cell lines with defective mitotic checkpoint showed significant underexpression of mitotic arrest deficient 2 (MAD2), a key mitotic checkpoint protein. The level of MAD2 underexpression was significantly associated with defective mitotic checkpoint response (p<0.001). In addition, no mutations were found in the coding sequences of MAD2 in all 11 hepatoma cell lines. Our findings suggest that MAD2 deficiency may cause a mitotic checkpoint defect in hepatoma cells.     

Instantaneous evaluation of mammalian cell culture growth rates through analysis of the mitotic index

Since a culture increases in cell number when dividing cells separate into two newborn cells, the fraction of mitotic cells in a growing cell population directly reflects the overall growth behavior of a cell culture. To rapidly assess the effects of growth conditions on the fraction of mitotic cells we have employed an antibody specific for the phosphorylated form of histone H3 for the identification of mitotic cells using flow cytometry. The phosphorylation of histone H3 closely correlates with the chromosomal condensation that accompanies the onset of mitosis, and, therefore, it represents a convenient marker for dividing cells. We have optimized the protocol for the staining of mitotic cells for both Chinese hamster ovary and hybridoma cell cultures. Fluorescence micrographs taken of stained cells show that cells in the various stages of mitosis can be detected based on the morphological characteristics of the chromosomes. The variation in the mitotic cell fraction has been determined throughout the batch growth phases of cultures under different growth conditions. The dynamics of the mitotic index show that balanced growth was never truly reached and that the growth rate is in fact quite variable for these cultures since large variations in the mitotic index are observed. In addition, a large increase in the fraction of mitotic cells just prior to the exponential growth phase for all cultures indicates that they are partially synchronized at the exit from the lag phase. According to a two-staged, age structured population balance model, the mitotic index is directly proportional to the growth rate of a culture. The proportionality constant for this case is shown to be the time required for cells to progress through mitosis. This time is believed to be constant for a particular cell line, as shown by experimental data. Thus, growth rates can be determined solely by measurement of the fraction of cells in mitosis. The mitotic index measurements were then used to calculate the growth in cell number of the cultures, and these simulations accurately reflect observed cell counts. Other simulations also show that changes in cell growth can be predicted before they are reflected in the cell count data. This technique can be used as a sensitive indicator of cell growth and could be useful as a process monitoring technique and for developing better feeding strategies for animal cell cultures.     

Targeting mitotic exit with hyperthermia or APC/C inhibition to increase paclitaxel efficacy

Microtubule-poisoning drugs, such as Paclitaxel (or Taxol, PTX), are powerful and commonly used anti-neoplastic agents for the treatment of several malignancies. PTX triggers cell death, mainly through a mitotic arrest following the activation of the spindle assembly checkpoint (SAC). Cells treated with PTX slowly slip from this mitotic block and die by mitotic catastrophe. However, cancer cells can acquire or are intrinsically resistant to this drug, posing one of the main obstacles for PTX clinical effectiveness. In order to override PTX resistance and increase its efficacy, we investigated both the enhancement of mitotic slippage and the block of mitotic exit.

To test these opposing strategies, we used physiological hyperthermia (HT) to force exit from PTX-induced mitotic block and the anaphase-promoting complex/cyclosome (APC/C) inhibitor, proTAME, to block mitotic exit. We observed that application of HT on PTX-treated cells forced mitotic slippage, as shown by the rapid decline of cyclin B levels and by microscopy analysis. Similarly, HT induced mitotic exit in cells blocked in mitosis by other antimitotic drugs, such as Nocodazole and the Aurora A inhibitor MLN8054, indicating a common effect of HT on mitotic cells. On the other hand, proTAME prevented mitotic exit of PTX and MLN8054 arrested cells, prolonged mitosis, and induced apoptosis. In addition, we showed that proTAME prevented HT-mediated mitotic exit, indicating that stress-induced APC/C activation is necessary for HT-induced mitotic slippage.

Finally, HT significantly increased PTX cytotoxicity, regardless of cancer cells’ sensitivity to PTX, and this activity was superior to the combination of PTX with pro-TAME. Our data suggested that forced mitotic exit of cells arrested in mitosis by anti-mitotic drugs, such as PTX, can be a more successful anticancer strategy than blocking mitotic exit by inactivation of the APC/C.     

Cellular compartmentalization of protein kinase activity during the cell cycle

The quantities and types of protein kinases found in the cytoplasmic and nuclear or chromosomal compartments of interphase and mitotic human culture cells were compared. Using histone as substrate, the total quantity of kinases recovered from cytoplasmic and chromosomal fractions of mitotic cells was several times greater than from cytoplasmic and nuclear fractions of interphase cells. In both mitotic and interphase cells, more activity was recovered from cytoplasmic fractions than from chromosomal or nuclear fractions, respectively. When activity against various substrates was examined, mitotic chromosomal extracts were found to display the greatest preference for the H1 fraction of histones. Neither cytoplasmic nor chromosomal fractions from mitotic cells exhibited enhanced activity in the presence of cAMP, whereas the activity of both cytoplasmic and nuclear fractions of interphase cells was enhanced. Protein kinases, previously identified by nondenaturing polyacrylamide gel electrophoresis as present in the cytoplasmic fraction of mitotic but not interphase cells, were also present in chromosomal fractions of mitotic cells; only one of these kinases may be present in nuclear extracts of interphase cells. In addition, the profiles of nuclear extracts of interphase cells differ from their cytoplasmic fractions. These results indicate that there are protein kinases which are restricted to the mitotic phase of the cell cycle and that they apparently partition between the cytoplasmic and chromosomal compartments of cells in mitosis.     

On the mechanism of premeiotic DNA synthesis in the yeast Saccharomyces cerevisiae

Premeiotic DNA synthesis in synchronously sporulating cultures of the yeast, Saccharomyces cerevisiae, was analysed by sedimentation in alkaline sucrose gradients and by DNA-fibre autoradiography. The gradient profiles of cells pulse-labelled for varying times were essentially identical with those obtained with mitotic cultures, revealing a close resemblance between the meiotic and mitotic replication mechanisms. This was supported by the finding that exposure of meiotic cells to a specific concentration of hydroxyurea led to the accumulation of completed, but unjoined replicons, just as it does in mitotic cells. The results of DNA-fibre autoradiography confirmed that replicons in meiotic cells are the same size (20–180 Kb, averaging around 90 Kb) as in mitotic cells, and assuming replication is bi-directional, replication forks must move at round the same rate as in mitosis, i.e. about 0.7 μm/min.     

Frozen DON cells as a source for a cell cycle assay of antitumor agents

This study was intended to determine the feasibility of using frozen mitotic mammalian cells as a source of synchronous cultures to determine the cell cycle phase specificity of cytotoxic agents. We first found that the relative effectiveness of different additives in protecting cells during freezing was DMSO > glycerol of polyvinyl pyrolidone > sucrose > 50% serum. We also found that mitotic cells frozen in glycerol did not progress synchronously through the cell cycle when thawed. However, mitotic cells frozen in DMSO had approximately the same cell cycle time as non-frozen mitotic cells and therefore could be thawed and cultured to determine phase specific cytotoxicity of compounds. However, better results were obtained when cells frozen in different phases were used to determine phase specific toxicity of compounds. The pattern of sensitivity to cytotoxic agents of cells frozen in different phases was the same as that of the non-frozen controls.     

RIBONUCLEIC ACID AND PROTEIN SYNTHESIS IN MITOTIC HELA CELLS

HeLa cells arrested in mitosis were obtained in large numbers, with only very slight interphase cell contamination, by employing the agitation method of Terasima and Tolmach, and Robbins and Marcus. Protein synthesis and RNA synthesis were almost completely suppressed in mitotic cells. Active polyribosomes were nearly absent in mitotic cells as compared with interphase cells treated in the same way. Cell-free protein synthesis and RNA polymerase activity were also greatly depressed in extracts of metaphase cells. The deoxyribonucleoprotein (DNP) of condensed chromosomes from mitotic cells was less efficient as a template for Escherichia coli RNA polymerase than was DNP from interphase cells, although isolated DNA from both sources was equally active as a primer. Despite very poor endogenous amino acid incorporation by extracts of metaphase cells, polyuridylate stimulated phenylalanine incorporation by a larger factor in mitotic cell extracts than it did in interphase cell extracts. These results suggest that RNA synthesis is suppressed in mitotic cells because the condensed chromosomes cannot act as a template, and that protein synthesis is depressed at least in part because messenger RNA becomes unavailable to ribosomes. This conclusion was supported by the demonstration that cells arrested in metaphase supported multiplication of normal yields of poliovirus, thereby showing that the mitotic cell is capable of considerable synthesis of RNA and protein.     

Effects of chemical manipulation of mitotic arrest and slippage on cancer cell survival and proliferation

Microtubule-targeting cancer therapies interfere with mitotic spindle dynamics and block cells in mitosis by activating the mitotic checkpoint. Cells arrested in mitosis may remain arrested for extended periods of time or undergo mitotic slippage and enter interphase without having separated their chromosomes. How extended mitotic arrest and mitotic slippage contribute to subsequent cell death or survival is incompletely understood. To address this question, automated fluorescence microscopy assays were designed and used to screen chemical libraries for modulators of mitotic slippage. Chlorpromazine and triflupromazine were identified as drugs that inhibit mitotic slippage and SU6656 and geraldol as chemicals that stimulate mitotic slippage. Using the drugs to extend mitotic arrest imposed by low concentrations of paclitaxel led to increased cell survival and proliferation after drug removal. Cells arrested at mitosis with paclitaxel or vinblastine and chemically induced to undergo mitotic slippage underwent several rounds of DNA replication without cell division and exhibited signs of senescence but eventually all died. By contrast, cells arrested at mitosis with the KSP/Eg5 inhibitor S-trityl-L-cysteine and induced to undergo mitotic slippage were able to successfully divide and continued to proliferate after drug removal. These results show that reinforcing mitotic arrest with drugs that inhibit mitotic slippage can lead to increased cell survival and proliferation, while inducing mitotic slippage in cells treated with microtubule-targeting drugs seems to invariably lead to protracted cell death.     

Clonal growth of normal human epidermal keratinocytes in a defined medium

Early studies on the duration of mitotic stages and on metaphase-to-prophase ratios in a number of normal and neoplastic cells indicated that the process of mitosis becomes altered during the course of oncogenesis. However, the nature of these changes and their effects on each of the mitotic stages are still unclear. With the use of time lapse cinemicrography, we have compared the durations of mitotic stages of SV40/Wl-38 and SV40/Wl-26 cells to those of their normal counterparts and to other nontransformed human fibroblasts. We also examined the relative frequencies of the individual mitotic stages in fixed preparations of Wl-38 and SV40/Wl-38 cells. The data show that metaphase durations are increased in the transformed cells and as much as 3-4.7-fold in SV40/Wl-38 cells compared to Wl-38 and other nontransformed cells. Other stages are also prolonged though to lesser degrees. These findings suggest that increased metaphase/prophase ratios observed in many tumors are due to increases in duration of metaphase rather than to shorter prophases, and that increased mitotic indices commonly observed in malignant tumors and sometimes used as an index of growth rate are at least in part due to the prolongation of mitotic stages.     

Targeting mitosis exit: A brake for cancer cell proliferation

The transition from mitosis to interphase, referred to as mitotic exit, is a critical mitotic process which involves activation and inactivation of multiple mitotic kinases and counteracting protein phosphatases. Loss of mitotic exit checkpoints is a common feature of cancer cells, leading to mitotic dysregulation and confers cancer cells with oncogenic characteristics, such as aberrant proliferation and microtubule-targeting agent (MTA) resistance. Since MTA resistance results from cancer cells prematurely exiting mitosis (mitotic slippage), blocking mitotic exit is believed to be a promising anticancer strategy. Moreover, based on this theory, simultaneous inhibition of mitotic exit and additional cell cycle phases would likely achieve synergistic antitumor effects. In this review, we divide the molecular regulators of mitotic exit into four categories based on their different regulatory functions: 1) the anaphase-promoting complex/cyclosome (APC/C, a ubiquitin ligase), 2) cyclin B, 3) mitotic kinases and phosphatases, 4) kinesins and microtubule-binding proteins. We also review the regulators of mitotic exit and propose prospective anticancer strategies targeting mitotic exit, including their strengths and possible challenges to their use.     

Mitosis-specific phosphorylation of p60c-src by p34cdc2-associated protein kinase

As cells enter mitosis, the protein-tyrosine kinase, p60c-src, is known to be extensively phosphorylated on threonine in its amino-terminal region. In the present work, extracts of mitotic cells were searched for the protein kinase responsible for this phosphorylation. HeLa cells and Xenopus eggs were found to contain a mitosis-specific protein kinase activity capable of phosphorylating highly purified p60c-src in vitro on threonine residues. Tryptic phosphopeptide maps indicate that the mitotic HeLa kinase phosphorylates the same sites in vitro as those used during mitosis in vivo. In addition, this mitotic HeLa kinase comigrates on gel filtration with p34cdc2-associated histone H1 kinase, a well known regulator of mitotic events. Finally, antibodies to the C-terminal peptide of human p34cdc2 specifically deplete p60c-src-phosphorylating activity from mitotic extracts. These results suggest that p60c-src may act as an effector of p34cdc2 in certain mitotic processes.     

Involvement of the 24-kDa cap-binding protein in regulation of protein synthesis in mitosis

The rate of protein synthesis in metaphase-arrested cells is reduced as compared to interphase cells. The reduction occurs at the translation initiation step. Here, we show that, whereas poliovirus RNA translation is not affected by the mitotic translational block, the translation of vesicular stomatitis virus mRNAs is. In an attempt to elucidate the mechanism by which initiation of protein synthesis is reduced in mitotic cells, we found that the interaction of the mRNA 24-kDa cap-binding protein (CBP) with the mRNA 5' cap structure is reduced in mitotic cell extracts, consistent with their lower translational efficiency. Addition of cap-binding protein complex stimulated the translation of endogenous mRNA in extracts from mitotic but not interphase cells. In addition, we found that the 24-kDa CBP from mitotic cells was metabolically labeled with 32P to a lesser extent than the protein purified from interphase cells. These results are consistent with a hypothesis that the 24-kDa CBP is implicated in the inhibition of protein synthesis in metaphase-arrested cells. Possible mechanisms for this inhibition are offered.     

Nucleophosmin is required for chromosome congression, proper mitotic spindle formation, and kinetochore-microtubule attachment in HeLa cells

Nucleophosmin (NPM) is an abundantly expressed multifunctional nucleolar phosphoprotein. Here we show that depletion of NPM by RNA interference causes defects in cell division, followed by an arrest of DNA synthesis due to activation of a p53-dependent checkpoint response in HeLa cells. Depletion of NPM leads to mitotic arrest due to spindle checkpoint activation. The mitotic cells arrested by NPM depletion have defects in chromosome congression, proper mitotic spindle and centrosome formation, as well as defects in kinetochore-microtubule attachments. Loss of NPM thus causes severe mitotic defects and delayed mitotic progression. These findings indicate that NPM is essential for mitotic progression and cell proliferation.     

THE EFFECT OF A MEDIUM DOSE (430 ROENTGENS) OF X-RAY IRRADIATION ON RESTING CELLS OF THE LIVER

The mitotic activity of regenerating liver cells after a single dose (430 r) of x-ray irradiation was studied. In every group of the experimental animals (white rats), the mitotic activity (mitotic index) and the number of abnormal mitotic figures were determined. The results indicated that resting cells irradiated a short time before mitotic activity showed reactions similar to those of cells irradiated during mitotic activity. The disturbances in the irradiated mitotically active cells were only quantitatively different from those in the irradiated resting cells. The disturbances in the irradiated resting cells depended upon the time interval between the irradiation and the beginning of mitotic activity stimulated by partial hepatectomy. It was found that the shorter the time interval, the more pronounced were the disturbances and the more similar they became to those of irradiated mitotically active cells. Conversely, the longer the time interval between the irradiation and the beginning of mitotic activity, the less pronounced were the disturbances and the more similar they became to those of the non-irradiated control cells. A discussion is presented as to whether or not the lesions of resting cells caused by a single medium dose of x-ray irradiation are reversible, and whether such lesions are only brought to light by the process of mitosis or whether the process of mitosis renders it possible for these lesions to develop.     

The effects of fungicide benomyl (benlate) on growth and mitosis in onion (Allium cepa L.) root apical meristem

In this study, the effects of benomyl, a systemic fungicide were investigated in the mitotic cell division in onion (Allium cepa) root tip cells during germination. For this aim, different concentrations (1, 2, 5, 10 and 20 mM) of benomyl solutions were used. All the concentrations used caused several abnormalities in mitotic cell divisions and the mitotic frequency in the onion root tip cells decreased as the concentration of benomyl solution increased. Based on our findings, it is reported that benomyl has some negative effects on mitotic divisions in onion root tip cells.     

Mitotic catastrophe triggered in human cancer cells by the viral protein apoptin

Mitotic catastrophe is an oncosuppressive mechanism that senses mitotic failure leading to cell death or senescence. As such, it protects against aneuploidy and genetic instability, and its induction in cancer cells by exogenous agents is currently seen as a promising therapeutic end point. Apoptin, a small protein from Chicken Anemia Virus (CAV), is known for its ability to selectively induce cell death in human tumor cells. Here, we show that apoptin triggers p53-independent abnormal spindle formation in osteosarcoma cells. Approximately 50% of apoptin-positive cells displayed non-bipolar spindles, a 10-fold increase as compared to control cells. Besides, tumor cells expressing apoptin are greatly limited in their progress through anaphase and telophase, and a significant drop in mitotic cells past the meta-to-anaphase transition is observed. Time-lapse microscopy showed that mitotic osteosarcoma cells expressing apoptin displayed aberrant mitotic figures and/or had a prolonged cycling time during mitosis. Importantly, all dividing cells expressing apoptin eventually underwent cell death either during mitosis or during the following interphase. We infer that apoptin can efficiently trigger cell death in dividing human tumor cells through induction of mitotic catastrophe. However, the killing activity of apoptin is not only confined to dividing cells, as the CAV-derived protein is also able to trigger caspase-3 activation and apoptosis in non-mitotic cancer cells.     

Mitosis in Milk Secreting Epithelial Cells of Mammary Gland An Ultrastructural Study

In all stages of lactation mitotic configurations were observed in mammary gland epithelial cells of rats. An electron microscopic study is presented which shows that ultrastructure of such mitotic stages is normal and that mitotic cells contain typical products of milk secreting cells such as casein micelle-containing vesicles and milk fat droplets. Such secretory products can even be observed in the immediate vicinity of the chromosomes and microtubules of the spindle apparatus. The endoplasmic reticulum of mitotic cells appeared altered in that it did not show typical cisternal stacks characteristic of interphase cells. While the numbers of such mitotic cells were very low, especially from the second week of lactation on (always less than 0.1% of the milk secreting epithelial cells encountered), the observations clearly demonstrate that differentiation for milk secretory activity and cells division are not mutually exclusive. We conclude that postpartum growth of mammary gland epithelium and replacement of epithelial cells lost during desquamation into the milk liquids can occur by division of existing differentiated milk secreting cells and does not require mitotic activity of non-lactating 'stem cells' which are not observed in lactating alveoli.