Polyploid cell dynamics and death before and after PEG-treatment of a NIH/3T3 derived culture: vinblastine effects on the regulation of cell subpopulations heterogeneity.

BACKGROUND: Neoplastic subpopulations can include polyploid cells that can be involved in tumor evolution and recurrence. Their origin can be traced back to the tumor microenvironment or chemotherapeutic treatment, which can alter cell division or favor cell fusion, generating multinucleated cells. Their progeny, frequently genetically unstable, can result in new aggressive and more resistant to chemotherapy subpopulations. In our work, we used NIHs cells, previously derived from the NIH/3T3 line after serum deprivation, that induced a polyploidization increase with the appearance of cells with DNA content ranging from 4 to 24c. This study aimed to analyze the cellular dynamics of NIHs culture subpopulations before and after treatment with the fusogenic agent polyethylene glycol (PEG), which allowed us to obtain new giant polyploid cells. Successively, PEG-untreated and PEG-treated cultures were incubated with the antimicrotubular poison vinblastine. The dynamics of appearance, decrease and loss of cell subpopulations were evaluated by correlating cell DNA content to mono-multinuclearity resulting from cell fusion and division process alteration and to the peculiarities of cell death events. RESULTS: DNA microfluorimetry and morphological techniques (phase contrast, fluorescence and TEM microscopies) indicated that PEG treatment induced a 4-24c cell increase and the appearance of new giant elements (64-140c DNA content). Ultrastructural analysis and autophagosomal-lysosomal compartment fluorochromization, which allowed us to correlate cytoplasmic changes to death events, indicated that cell depletion occurred through distinct mechanisms: apoptotic death involved 2c, 4c and 8c cells, while autophagic-like death involved intermediate 12-24c cells, showing nuclear (lobulation/micronucleation) and autophagic cytoplasm alterations. Death, spontaneously occurring, especially in intermediate-sized cells, was increased after vinblastine treatment. No evident cell loss by death events was detected in the 64-140c range. CONCLUSIONS: PEG-treated NIHs cultures can represent a model of heterogeneous subpopulations originating from cell fusion and division process anomalies. Altogether, our results suggest that the different cell dynamics of NIHs subpopulations can affect the variability of responses to stimuli able to induce cell degeneration and death. Apoptptic, autophagic or hybrid forms of cell death can also depend on the DNA content and ability to progress through the cell cycle, which may influence the persistence and fate of polyploid cell descendants, also concerning chemotherapeutic agent action.

Specific rearrangement of the microtubular network during the cell cycle phases and correlation with micronucleation and death induced by anticancer drugs in NIH/3T3 subcultures.

The changes of the microtubular network induced by microtubule destabilizing (Vinblastine, VBL) and stabilizing (Taxol, TAX) agents were studied in NIH/3T3 fibroblastic cells in conventional culture conditions (NIHb) and in a subpopulation (NIHs), obtained after serum deprivation and expressing different morphofunctional features and higher cytokinetic activity. In this cell model, we analyzed VBL and TAX effects on cell cycle and microtubular network, in relation to cell death. In NIHb cells, VBL induced higher microtubule depolymerization, prevalence of tubulin paracrystals and micronucleation, while, in NIHs cells, lower depolymerization and appearance of tubulin spiral-like structures, with lower micronucleation, increase of apoptosis and disappearance of high polyploid cells. DNA static cytofluorometry of cells showing paracrystals or spirals permitted correlation of the appearance of these tubulin aggregation forms with the cell cycle phases. In NIHb cultures, the DNA content curves, in cells with paracrystals or spirals, showed a similar trend, with a higher frequency of the two anomalies in the G2/M phase. In NIHs cultures, paracrystals and spirals are found in G2/M cells, while G1 cells showed prevailingly paracrystals. TAX induced the appearance of microtubule bundles in the two cultures. The prevalence of circular bundles was found in NIHb cells, while a higher number of linear bundles was shown in NIHs cells. In NIHb cells, circular bundles were related to higher apoptosis and micronucleation. DNA cytofluorometry, in cells with linear or circular bundles, showed that the latter was present with high frequency in NIHb cells in all the cell cycle phases; in NIHs cells, they appeared, with lower frequency, prevailing in the S-G2/M phase. Furthermore, in NIHs cells, the appearance of linear bundles in G1 cells was related to a lower micronucleation. These finding showed that microtubule reorganization in different cell cycle phases could play a role in the progression of nuclear fragmentation/micronucleation relating to cell death.

Cisplatin treatment of NIH/3T3 cultures induces a form of autophagic death in polyploid cells.

The effects induced by different concentrations (50, 75, 100 microM) of the cytostatic drug cisplatin (cDDP) in NIH/3T3 cells were analyzed. Sub-confluent cultures of this mouse fibroblast line, obtained after serum deprivation, showed the presence of aneuploid/polyploid cells with ploidy values ranging from 4c to 24c. DNA content cytofluorometry demonstrated that 50 and 75 microM cDDP induced a cytostatic effect; 100 microM concentration showed lower antiproliferative action. All treatments caused a partial cell detachment and apoptosis, the incidence of which appeared to be cDDP concentration-dependent. Ultrastructural and fluorescence microscopy integrated analyses of the still adherent cells demonstrated the presence of alternative degeneration patterns, especially in polyploid cells, with extensive modifications at both nuclear and cytoplasmic levels. There were events of micronucleation and phenomena of multilobulation and furrows of the nucleus that preceded the formation of heterogeneous fragments. These events were correlated, at cytoplasmic level, with actin reorganization and the appearance of autophagocytotic processes. In our cell model, the same pharmacological treatment was able to induce different cell death phenomena relating to cell dimension and ploidy. More actively proliferating cells (2c-4c DNA content) die throughout canonical apoptosis, while polyploid cells prevailingly degenerate by mechanisms partly referable to autophagic cell death.

Expression of cell kinetics and death during monocyte-macrophage differentiation: effects of Actinomycin D and Vinblastine treatments.

The different effects of two cytostatic drugs, Actinomycin D and Vinblastine, during macrophage-like differentiation induced in THP-1 monocytic cell line by phorbol ester phorbol 12-myristate 13-acetate (PMA) (6, 30, and 60 nM), were studied by morpho-cytochemical approaches. In PMA-unstimulated monocytic cells, the cytostatic effects of Actinomycin D (an antimetabolic drug) were characterized by a drastic reduction of the G2/M cells accompanied by dramatic death of the G1 cells; on the contrary, Vinblastine (a microtubule-depolymerizating drug) induced an accumulation of the G2/M cells with the appearance of aneugenic micronuclei and scarce cell death mainly from the G1 cells. After 60 nM PMA stimulation, the culture was mostly composed by macrophagic cells characterized by low proliferation and the appearance of mono-/binucleated polyploid cells; in this condition, the cytotoxicity of the two drugs, more effective for Vinblastine, induced cell death in the different ploidy classes (2c, 4c, 8c). Cell death appeared to be of apoptotic nature, but with some morpho-phenotypic differences due to the action mechanism of the drugs and dependent on cell culture growth and differentiation. As a consequence of the different block-action of the two drugs on the cell cycle phases and in relation to the different subcellular targets, the effects changed during the transition from not-adhering/proliferating monocytes to adhering/low-proliferating differentiated macrophages.

Different apoptotic responses and patterns in adhering and floating neoplastic cell cultures: effects of microtubule antagonists.

The relationship between apoptotic progression and cell cycle perturbation induced by microtubule-destabilising (vinblastine, Colcemid) and -stabilising (taxol) drugs was studied in two mesenchyme-derived neoplastic cell lines, growing as suspension (Jurkat) and monolayer (SGS/3A) culture, by morphocytochemical and biochemical approaches. The same kind of drug induced different effects on the cell kinetics (proliferation, polyploidisation, death) of the two cell lines. In floating cells, the drugs appeared more effective during the S phase, while in adherent cells they were more effective during the G2/M phase. Moreover two distinct neoplasia-associated apoptotic phenotypes emerged: the first pattern was the typical one and was found in cells with a low transition through the S/G2 phase (Jurkat), and the second one was mainly characterised by a cell death derived from micronucleated and mitotic cells, as a consequence of a low transition through the M/G1 phase (SGS/3A). Our data show that the machinery required for the trigger and progression of apoptosis is present in every cell cycle phase, also in conditions of karyological alterations (aneugenic micronucleations). On the other hand, a different sensitivity of the two microtubular components (interphasic network and mitotic spindle) appears to be related to the anchorage-dependence or -independence during the cell growth disturbances after exposure to antimicrotubular drugs.

Prevention of diabetes-induced microangiopathy by human tissue kallikrein gene transfer.

BACKGROUND: Microvascular insufficiency represents a major cause of end-organ failure among diabetics. METHODS AND RESULTS: In streptozotocin-induced diabetic mice, we evaluated the potential of human tissue kallikrein (hTK) gene as a sole therapy against peripheral microangiopathy. Local delivery of hTK gene halted the progression of microvascular rarefaction in hindlimb skeletal muscle by inhibiting apoptosis, thus ensuring an improved hemodynamic recovery in case of supervening vascular occlusion. The curative action of hTK did not necessitate insulin supplementation. Application of gene therapy at a stage of established microangiopathy stimulated vascular regeneration. CONCLUSIONS: Our studies indicate that hTK may represent a useful tool for the treatment of microvascular complications in diabetics.

The neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine induces apoptosis in mouse nigrostriatal glia. Relevance to nigral neuronal death and striatal neurochemical changes.

Swiss mice were given 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), 25 mg/kg/day, for 5 consecutive days and killed at different days after MPTP discontinuance. Decreases in striatal tyrosine hydroxylase activity and levels of dopamine and its metabolites were observed 1 day after MPTP discontinuance. Ascorbic acid and glutamate levels had increased, dehydroascorbic acid and GSH decreased, whereas catabolites of high-energy phosphates (inosine, hypoxanthine, xanthine, and uric acid) were unchanged. In addition, gliosis was observed in both striatum and substantia nigra compacta (SNc). Sections of SNc showed some terminal deoxynucleotidyl transferase-mediated 2'-deoxyuridine 5'-triphosphate nick end labeling (TUNEL)-positive cells. Neurochemical parameters of dopaminergic activity showed a trend toward recovery 3 days after MPTP discontinuance. At this time point, TUNEL-positive cells were detected in SNc; some of them showed nuclei with neuronal morphology. A late (days 6-11) increase in striatal dopamine oxidative metabolism, ascorbic acid oxidative status, and catabolites of high-energy phosphates were observed concomitant with nigral neuron and nigrostriatal glial cell apoptotic death, as revealed by TUNEL, acridine orange, and Hoechst staining, and transmission electron microscopy. These data suggest that MPTP-induced activation/apoptotic death of glial cells plays a key role in the sequential linkage of neurochemical and cellular events leading to dopaminergic nigral neuron apoptotic death.