Establishment of a tetraploid Meth-A cell line through polyploidization by demecolcine but not by staurosporine, K-252A and paclitaxel

Autotetraploid cell line induced by SP600125 from crucian carp and its developmental potentiality

Polyploidy has many advantages over diploidy, such as rapid growth, sterility, and disease resistance, and has been extensively applied in agriculture and aquaculture. Though generation of new polyploids via polyploidization has been achieved in plants by different ways, it is comparatively rare in animals. In this article, by a chemical compound, SP600125, polyploidization is induced in fish cells in vitro, and a stable autotetraploid cell line has been generated from diploid fibroblast cells of crucian carp. As a c-Jun N-terminal kinase (Jnk) inhibitor, SP600125 does not function during the induction process of polyploidization. Instead, the p53 signal pathway might be involved. Using the SP600125-induced tetraploid cells and eggs of crucian carp as the donors and recipients, respectively, nuclear transplantation was conducted such that tetraploid embryos were obtained. It suggests that combining polyploidization and the somatic cell nuclear transfer technique (SCNT) is an efficient way to generate polyploidy, and the presented method in this research for generating the tetraploid fish from diploid fish can provide a useful platform for polyploid breeding.

Staurosporine analogs promote distinct patterns of process outgrowth and polyploidy in small cell lung carcinoma cells

We have recently shown that staurosporine mediates the conversion of small cell lung carcinoma (SCLC) cells into a neuron-like process-bearing phenotype. Here, we have extended these studies to the staurosporine analogs K252a, lestaurtinib, PKC412, stauprimide, and UCN-01 and analyzed their influence on process extension, cell cycle distribution, and induction of polyploidy in four SCLC cell lines. In GLC-2 cells, all compounds provoked extensive process formation with the exception of PKC412 that showed no response. In H1184 cells, process formation was predominantly induced by staurosporine and, to lesser extent, in lestaurtinib-, stauprimide-, and UCN-01-treated cells. In the presence of K252a or PKC412, cells became bipolar and spindle shaped or showed pronounced cell flattening. In GLC-36 and SCLC-24H cells, only cell flattening was detectable. Process formation was reversible upon drug removal as shown for GLC-2 and H1184 cells. Fluorescence-activated cell sorting (FACS) and fluorescence in situ hybridization (FISH) analysis indicated the induction of polyploidy in all staurosporine and in two out of four stauprimide-treated SCLC cell lines. For other staurosporine analogs, polyploidy was observed only in UCN-01-treated GLC-36 cells and in K252a-treated H1184 and GLC-36 cells. The presence of staurosporine or its analogs did not alter the constitutive activation pattern of the canonical Akt/PI3K or MEK/extracellular signal-regulated kinase (ERK)1/2 signaling pathways nor could we detect an influence of stauprimide application on the expression level of the c-Myc oncogene. These data demonstrate that in SCLC cells, albeit a higher substrate specificity, staurosporine analogs can induce staurosporine-comparable effects.

Establishment of proliferative tetraploid cells from normal human fibroblasts

The chromosomal instability of polyploid cells, which leads to the formation of aneuploid cells, is causally related to carcinogenesis in human tissues. However, the precise link between the chromosomal instability of polyploid cells and oncogenic transformation of them remains elusive. This is partly because we lack an experimental model in which non-transformed polyploid human cells can propagate in vitro. In a previous report, we demonstrated that proliferative tetraploid cells can be established from TIG-1 human fibroblasts by treatment with the spindle poison demecolcine (DC, colcemid) for 4 days. However, this procedure could not be applied to other human fibroblast strains because the resulting cells proliferated as a mixture of diploid and tetraploid populations. Here, we report a modified procedure to establish proliferative tetraploid cells from human fibroblasts of the BJ strain with minimum contamination by diploid cells. In the modified procedure, DC-arrested mitotic cells were collected by mitotic shake-off and treated with DC for an additional 3 days. DC-treated cells restarted proliferation as tetraploid cells after several days of growth arrest and showed similar growth to that of untreated diploid cells. The MDM2 antagonist Nutlin-3a activated p53 in established tetraploid cells and suppressed their growth, indicating that these cells have functional p53. These results contradicted the hypothesis that p53 functions as the tetraploidy checkpoint and prevents proliferation of tetraploid cells. Tetraploid cells established by our method could be a valuable model for the study of chromosomal instability and the oncogenic potential of polyploid cells.

Formation of bipolar spindles with two centrosomes in tetraploid cells established from normal human fibroblasts

Tetraploid cells with unstable chromosomes frequently arise as an early step in tumorigenesis and lead to the formation of aneuploid cells. The mechanisms responsible for the chromosome instability of polyploid cells are not fully understood, although the supernumerary centrosomes in polyploid cells have been considered the major cause of chromosomal instability. The aim of this study was to examine the integrity of mitotic spindles and centrosomes in proliferative polyploid cells established from normal human fibroblasts. TIG-1 human fibroblasts were treated with demecolcine (DC) for 4 days to induce polyploidy, and the change in DNA content was monitored. Localization of centrosomes and mitotic spindles in polyploid mitotic cells was examined by immunohistochemistry and laser scanning cytometry. TIG-1 cells treated with DC became almost completely tetraploid at 2 weeks after treatment and grew at the same rate as untreated diploid cells. Most mitotic cells with 8C DNA content had only two centrosomes with bipolar spindles in established tetraploid cells, although they had four or more centrosomes with multipolar spindles at 3 days after DC treatment. The frequency of aneuploid cells increased as established tetraploid cells were propagated. These results indicate that tetraploid cells that form bipolar spindles with two centrosomes in mitosis can proliferate as diploid cells. These cells may serve as a useful model for studying the chromosome instability of polyploid cells.

DNA-unstable decaploid mouse H1 (ES) cells established from DNA-stable pentaploid H1 (ES) cells polyploidized using demecolcine

OBJECTIVES

DNA content of diploid H1 (ES) cells (2H1 cells) has been shown to be stable in long-term culture; however, tetraploid and octaploid H1 (ES) cells (4H1 and 8H1 cells, respectively) were DNA-unstable. Pentaploid H1 (ES) cells (5H1 cells) established recently have been found to be DNA-stable; how, then is cell DNA stability determined? To discuss ploidy stability, decaploid H1 (ES) cells (10H1 cells) were established from 5H1 cells and examined for DNA stability.

MATERIALS AND METHODS

5H1 cells were polyploidized using demecolcine (DC) and 10H1 cells were obtained by one-cell cloning.

RESULTS

Number of chromosomes of 10H1 cells was 180 and durations of their G(1), S, and G(2)/M phases were 3, 7 and 6 h respectively. Volume of 10H1 cells was double that of 5H1 cells and morphology of 10H1 cells was flagstone-like in shape. 10H1 cells exhibited alkaline phosphatase activity and their DNA content decayed in 91 days of culture. 10H1 cells injected into mouse abdomen formed solid tumours that contained several kinds of differentiated cells with lower DNA content, suggesting that 10H1 cells were pluripotent and DNA-unstable. Loss of DNA stability was explained using a hypothesis concerning DNA structure of polyploid cells as DNA reconstructed through ploidy doubling was arranged in mirror symmetry in a new configuration.

CONCLUSION

In the pentaploid-decaploid transition of H1 cells, cell cycle parameters and pluripotency were retained, but morphology and DNA stability were altered.

Hexaploid H1 (ES) cells established from octaploid H1 cells are as DNA stable as pentaploid H1 cells

Hexaploid H1 (ES) cells (6H1 cells) were established from octaploid H1 cells (8H1 cells), as were pentaploid H1 cells (5H1 cells). 6H1 cells were compared with 5H1 cells. The number of chromosomes of 6H1 cells was 115, 20 more than the 95 of 5H1 cells. The durations of G(1), S, and G(2)/M phases of 6H1 cells were 3, 7, and 6 h, respectively, almost the same as those of 5H1 cells. The cell volume of 6H1 cells was equivalent that of 5H1 cells. The morphology of 6H1 cells was flattened circular cluster, different from the spherical cluster of 5H1 cells. 6H1 cells exhibited alkaline phosphatase activity as well as 5H1 cells. The DNA content of 6H1 cells was stable and maintained for 300 days of culturing, the same as that of 5H1 cells. The DNA stability of 6H1 cells was explained using a hypothesis concerning the DNA structure of polyploid cells because the asymmetric configuration of homologous chromosomes in 6H1 cells inhibited chromosome loss.

Cell cycle, morphology and pluripotency of octaploid embryonic stem cells in comparison with those of tetraploid and diploid cells

To examine the alteration of cellular characteristics on ploidy transition of embryonic stem (ES) cells, octaploid cells (8H1 cells) were established from tetraploid H-1 (ES) cells, and compared with tetraploid and diploid H-1 (ES) cells (4H1 and 2H1 cells, respectively). The duration of G(1), S, and G(2)/M phases were essentially the same among 2H1, 4H1, and 8H1 cells, suggesting that cell cycle progression is conserved. The ratio of cell volume of 2H1, 4H1, and 8H1 cells was about 1 : 2 : 4, indicating that these polyploid cells were generated through cell cycle progression without cell division. The morphology of 8H1 cells was flagstone-like and flatter than that of 4H1 cells, and differed from the spindle-like shape of 2H1 cells, suggesting that transformation occurred during the ploidy transitions. Alkaline phosphatase activity was expressed equivalently in 2H1, 4H1, and 8H1 cells, and solid tumors that contained endodermal, mesodermal, and ectodermal cells were formed by 2H1, 4H1 or 8H1 cells after interperitoneal injection into the mouse abdomen, suggesting that pluripotency was preserved in the ploidy transition.

Polyploidization of 2nH1 (ES) cells by K-252a and staurosporine

Mouse 2nH1 (ES) cells were examined for polyploidization using K-252a and staurosporine. Though 2nH1 cells were polyploidized by both K-252a and staurosporine, tetraploid cells, 4nH1K cells, were obtained only from cell populations exposed to K-252a. The probability of successful establishment of tetraploid cells was 2/9, suggesting that the highly polyploidized-tetraploid transition might occur infrequently. Cell cycle parameters of 4nH1K cells were almost the same as those of 2nH1 cells, suggesting that the rate of DNA synthesis was about twice that of the diploid cells. The cell volume of 4nH1K cells was about twice of that of diploid cells, indicating that 4nH1K cells contained about twice as much total intracellular material as 2nH1 cells. The morphology of the 4nH1K cells was flagstone-like, thus differing from that of the spindle-shaped 2nH1 cells, suggesting that morphological transformation occurred during the diploid-tetraploid transition. 4nH1K cells exhibited alkaline phosphatase activity and formed teratocarcinomas, implying that they were pluripotent. These characteristics of 4nH1K cells were similar to those of tetraploid 4nH1 cells that have been established through polyploidization by demecolcine, suggesting that 4nH1K and 4nH1 cells are similar irrespective of the different mechanisms of polyploidization.

Establishment of a tetraploid cell line from mouse H-1 (ES) cells highly polyploidized with demecolcine

OBJECTIVE

Establishment of tetraploid ES cells.

MATERIALS AND METHODS

Mouse H-1 (ES) cells were polyploidized by demecolcine and released from the drug.

RESULTS

A tetraploid cell line (4nH1 cells) was established from mouse H-1 (ES) cells (2nH1 cells) highly polyploidized by treatment with demecolcine. Cell cycle parameters of 4nH1 cells were almost the same as those of 2nH1 cells, suggesting that the rate of DNA synthesis was about twice that of the diploid cells. Mode of chromosome number of 4nH1 cells was 76, about twice that of 2nH1 cells. Cell volume of 4nH1 cells was about twice of that of diploid cells, indicating that 4nH1 cells contained about twice as much total intracellular material as 2nH1 cells. Morphology of the 4nH1 cells was flagstone-like, thus differing from that of the spindle-shaped 2nH1 cells, suggesting that the transformation had occurred during the diploid-tetraploid transition. 4nH1 cells exhibited alkaline phosphatase activity and formed teratocarcinomas, implying that they would be pluripotent.

CONCLUSION

A pluripotent tetraploid cell line (4nH1 cells) was established.

Significance of cell kinetic parameters in the prognosis of malignant melanoma: a review

Malignant melanoma has been extensively studied concerning methods of predicting progression and clinical outcome. The maximum tumor thickness as measured by Breslow's method is the cornerstone prognostic criterion, but despite this, evolution of the disease in some patients remains unpredictable, confirming that new reliable prognostic factors are awaited. Cell kinetic evaluation has been shown to be a useful tool for assessing the prognosis of breast and gastrointestinal cancer patients. Indeed, in these fields, the mitotic index and MIB-1 expression index, which are indirect estimates of the growth fraction of tumor cell population, are commonly shown to correlate with tumor grade and patient survival and presented as prognostic factors. In melanoma, results of cell kinetic investigations are conflicting: some studies have established a link between high proliferative activity and a bad prognosis, whereas other reports suggest the opposite. The aim of this review is to discuss these findings.

An hypothesis about genome structures in mammalian polyploid cells based on a new concept that genome is fractal of six hierarchies

A new model for the spatial configurations of DNA is proposed to solve the problem of DNA loss in mammalian polyploid cells. The ordinary concept that chromosomes are situated independently in nuclei cannot account well for the DNA loss in polyploid cells. A new concept about the DNA configurations in diploid cells is constructed based on observations that have been reported. Briefly, the DNA structure is self-similar fractal with a unit of opposite-handed twin-circles. In human diploid cells, DNA is constructed with six hierarchies whose sizes are 32(5), 32(4), 32(3), 32(2), 32(1) and 32(0) with a unit of 200 DNA base pairs, corresponding to a genome, a chromosome, a chromosome band, a replicon, a rosette loop (a gene) and a nucleosome, respectively. A model assuming particular spatial configurations of chromosomes in polyploid cells is deduced from this new concept about chromosome configurations in diploid cells. It can account satisfactorily for the problem of DNA loss in polyploid cells. When cell division is inhibited and DNA synthesis progresses, replicated DNA will be stacked. When inhibitors are removed, the polyploidized cells may return to the initial ploidy, because the stacked DNA loops have not been linked. When the stacked DNA twin-loops are linked with a proper configuration, the cells may become polyploid cells. There is a distinct difference in genome structure between polyploidized and polyploid cells. The homologous chromosomes of polyploid cells are arrayed mirror-symmetrically and they can come close to each other in the folded structure. If DNA synthesis is bypassed at the paired homologous chromosomes, DNA content is lost at every cell division. As the DNA loss progresses, the chromosome configuration of polyploid cells deviates gradually from mirror-symmetry and the DNA loss ceases, resulting in the establishment of semi-stable hypoploid.

Octaploid Meth-A cells are established from a highly polyploidized cell population

Tetraploid Meth-A cells were polyploidized by demecolcin, an inhibitor of spindle fibre formation in M phase, and then released from the drug 1, 2, 3 and 4 days after the addition. Octaploid cells were successfully established from cell populations including hexadecaploid cells produced by 2, 3 and 4 days of exposure to demecolcin. One-day-treated cells were polyploidized octaploid cells, but they returned to tetraploid cells. All of the octaploid Meth-A cells showed essentially the same features. The octaploid Meth-A cells had eight homologous chromosomes and double the DNA content of the parent tetraploid cells. The doubling time of octaploid Meth-A cells was 30.2 h, somewhat longer than the 28.3 and 24.0 h of tetraploid and diploid cells, respectively. The fractions of cells in the G1, S and G2/M phases were essentially the same in diploid, tetraploid and octaploid Meth-A cells. The cell volume of octaploid Meth-A cells was about two times that of the tetraploid cells. It was concluded that octaploid Meth-A cells were established from transient hexadecaploid cells produced by the polyploidization of tetraploid cells that had been established from diploid cells.

Temperature dependence in proliferation of tetraploid Meth-A cells in comparison with the parent diploid cells

The temperature dependency for the growth of tetraploid Meth-A cells established from diploid cells was examined in comparison with the parent diploid cells. Proliferation of the tetraploid cells was markedly suppressed below 35 degrees C. At above 40 degrees C, both the diploid and tetraploid Meth-A cells ceased growing. Flow cytometry (FCM) analysis showed that the hyperploid cell fraction increased in the tetraploid Meth-A cell population at low temperatures. The fluidity of cell membranes at different temperatures was measured by means of electron spin resonance (ESR), and it was almost the same between the diploid and tetraploid Meth-A cells. It was suggested that the decreased proliferation below 35 degrees C of the tetraploid Meth-A cells might be due to the increased volume of the cells.