The occurrence of multinucleate giant cells in yeasts

Summary The spontaneous occurrence of giant cells has been observed in young cultures ofLipomyces lipofer and three different genotypes ofSaccharomyces. Stained preparations of all abnormal cultures revealed that the giant cells characteristically contained more than one nucleus, the number ranging from one to six. In both genera the phenomenon was found to be transient, for rapidlygrowing cultures arising from isolated giant cells reverted, at varying rates, to populations of small uninucleate cells which appeared normal in all respects.     

A quantitative cytochemical investigation of osteoclasts and multinucleate giant cells

Summary Quantitative cytochemical, immunocytochemical, autoradiographic and electron cytochemical investigations have been used to compare osteoclasts with multinucleate giant cells that had been freshly obtained from the same animal. The levels of -acid galactosidase activity, the DNA in individual nuclei and the cellular protein content were similar in both cell types. However, osteoclasts generally possessed greater acid phosphatase and NADH dehydrogenase activity but lower levels of fluoride-inhibited non-specific esterase activity than multinucleate giant cells. The acid phosphatase activity in multinucleate giant cells was completely inhibited by 100 mM tartrate, but in osteoclasts only a 20% reduction in activity was observed. Formation of multinucleate giant cells in a bone microenvironment (thin bone slices) did not increase their content of tartrate-resistant acid phosphatase activity. Moreover, in osteoclasts, endogenous peroxidase activity was undetectable but present in several granules within the cytoplasm of multinucleate giant cells. Osteoclasts and multinucleate giant cells displayed a similar microtubular distribution, but calcitonin, which induced rearrangement of microtubules and cellular contraction in osteoclasts, had no effect on multinucleate giant cells. Thus, these investigations reveal both similarities and differences between these two syncytia and support the hypothesis that osteoclasts and multinucleate giant cells are related. Possibly osteoclasts arise from monocyte progenitors before commitment to a macrophage lineage has occurred.     

Extracellular matrix receptor and platelet antigens on osteoclasts and foreign body giant cells

Summary Osteoclasts (OCs) and other cells of the mononuclear phagocyte system possess receptors for adhesive proteins present in the extracellular matrix. The antigenic phenotype of OCs and foreign body giant cells (FBGCs) was investigated for the presence of several integrin molecules and other largely platelet-associated antigens involved in cell adhesion reactions. Both OCs and FBGCs expressed the -chains of the vitronectin receptor (CD51) and of the VLA-2 (CDw49b) and VLA-4 (CDw49d) molecules as well as their respective -chains, gpIIIa (CD61) and CD29. OCs and FBGCs also expressed CD9 and CD55 (DAF-Decay Accelerating Factor) and strongly reacted with antibodies directed against fibrinogen, fibronectin and vitronectin; the latter are ligands for several of the above matrix protein receptors. The data suggest that cell-cell and cell-matrix interactions involving adhesive proteins may be important in OC and FBGC function.     

Extracellular matrix receptor and platelet antigens on osteoclasts and foreign body giant cells.

Osteoclasts (OCs) and other cells of the mononuclear phagocyte system possess receptors for adhesive proteins present in the extracellular matrix. The antigenic phenotype of OCs and foreign body giant cells (FBGCs) was investigated for the presence of several integrin molecules and other largely platelet-associated antigens involved in cell adhesion reactions. Both OCs and FBGCs expressed the alpha-chains of the vitronectin receptor (CD51) and of the VLA-2 (CDw49b) and VLA-4 (CDw49d) molecules as well as their respective beta-chains, gpIIIa (CD61) and CD29. OCs and FBGCs also expressed CD9 and CD55 (DAF-Decay Accelerating Factor) and strongly reacted with antibodies directed against fibrinogen, fibronectin and vitronectin; the latter are ligands for several of the above matrix protein receptors. The data suggest that cell-cell and cell-matrix interactions involving adhesive proteins may be important in OC and FBGC function.     

Nucleoli in large (giant) bi- and multinucleate cells after apoptosis-inducing photodynamic treatment

The present experimental study was undertaken to provide information on nucleolar changes accompanying the apoptotic process in large or giant binucleate and multinucleate cells (LBMNCs). Such cells were present in a small but constant percentage in cultures of HL-60 cells. The apoptotic process was induced by photodynamic treatment (PDT) by means of 5-aminolaevulinic acid (ALA) as the precursor of the photosensitizer protoporphyrin IX and irradiation with broad spectrum blue light (BL). Nucleolar changes in LBMNCs were characterized by marked reduction or disappearance of silver stained particles representing AgNORs in nucleoli including the large ones. In addition, PDT also significantly reduced the number of nucleoli regardless of their size. These changes apparently reflected the decrease or cessation of nucleolar biosynthetic activities and resembled those which were previously observed in naturally maturing bone marrow megakaryocytes (Janoutová et al., 2001).     

Ultrastructural interaction between multinucleate giant cells and the fungus in aspergillomas of human paranasal sinuses

The interaction between multinucleate giant cells (MGCs) and the fungusAspergillus flavus as seen by transmission electron microscopy (TEM) is described in paranasal granulomas occurring in a Saudi patient dying from chronic aspergillosis. Two morphologically different types of MGCs were recognized; these were: a) ‘Unhealthy looking’ type I cells, rich in well organized organelles and containing few, partially degenerated and necrotic fungal elements. b) ‘Healthy looking’ type II cells that contained scanty, randomly dispersed cell organelles and normal, or partially degenerated fungal hyphae. The fungal elements had very thick and multilayered cell walls, and were found either in close contact to the host cell cytoplasm, or enclosed within phagosomes. The mechanism of the fungus destruction by the host MGCs is described and compared with that previous reports of MGCs involved in the elimination of extracellular microorganisms. The morphology and the various physiological activities of MGCs seemed to depend mainly on whether the pathogen is extra- or intracellular. However, this study showed that MGCs are the cells best suited for killing pathogenic fungi.     

Three-dimensional study of the cytoskeleton in macrophages and multinucleate giant cells by quick-freezing and deep-etching method

The three-dimensional ultrastructure of multinucleate giant cells in subcutaneous granulomas was compared with those of peritoneal macrophages using a quick-freezing and deep-etching method. Subcutaneous granulomas were induced by implanting plastic coverslips in the dorsal subcutaneous tissue of rats. The quick-freezing and deep-etching replicas were prepared from the cells attached to the coverslips. Dense networks of actin filaments were distributed along all peripheral aspects (beneath the plasma membrane, and on free and coverslip-attached surfaces) of the multinucleate giant cells. On the coverslip-attached surface, numerous clathrin-coated pits and vesicles occurred between the actin filaments. In these cells, intermediate filaments, but not actin filaments, were the predominant cytoskeletal components in perinuclear regions and were attached to the cell nucleus, mitochondria and other vesicular cell organelles. A similar distribution of cytoskeletal components was observed in the mononuclear macrophages of the granulomas and the peritoneal macrophages. These results show that the cytoskeletal organization varies in different regions of the cytoplasm of multinucleate giant cells, while the characteristic cytoskeletal arrangement, resembling that of mononuclear macrophages, is maintained.     

Centrosome-kinetochore interaction in multinucleate cells

The interaction between centrosomes and kinetochores was studied in multinucleate cells induced by Colcemid treatment or by random cell fusion. Except for prematurely condensed chromosomes (PCC) of the G₂-phase, PCCs do not develop their own spindle area. Perhaps the maturation promoting factor (MPF) fails to activate these centrosomes. In such PCCs, the kinetochore-centrosome interaction was found to be non-specific: sometimes only a few chromosomes of a group could establish connections with centrosomes, sometimes chromosomes from the same PCC group developed microtubule (MT) attachment with different centrosomes (not the pair), and sometimes kinetochores of PCC groups failed to interact with MTs. These findings explain the abnormal mitotic behaviour of PCCs as seen in the light microscope. These PCCs develop micronuclei or normal nuclei by nuclear re-formation in telophase. All the different PCC groups revealed kinetochores with kinetochore plates. It was shown that transformation of presumptive kinetochores to a trilaminar kinetochore does not depend on nuclear envelope breakdown or on the degree of chromosome condensation. This may be induced by the MPF which may initiate different events like chromosome condensation, nuclear envelope breakdown and kinetochore transformation by secondary factors. Other observations like establishment of connections by different chromosome groups to a common centrosome, kinetochore attachment of PCCs to different centrosomes, interaction of one kinetochore with two centrosomes, kinetochores being stretched and bent to receive microtubules and finally the failure of some kinetochores to develop MT attachment, all strongly suggest that the kinetochores serve as the point of termination rather than the nucleation sites of kinetochore MTs.     

Three-dimensional study of the cytoskeleton in macrophages and multinucleate giant cells by quick-freezing and deep-etching method.

The three-dimensional ultrastructure of multinucleate giant cells in subcutaneous granulomas was compared with those of peritoneal macrophages using a quick-freezing and deep-etching method. Subcutaneous granulomas were induced by implanting plastic coverslips in the dorsal subcutaneous tissue of rats. The quick-freezing and deep-etching replicas were prepared from the cells attached to the coverslips. Dense networks of actin filaments were distributed along all peripheral aspects (beneath the plasma membrane, and on free and coverslip-attached surfaces) of the multinucleate giant cells. On the coverslip-attached surface, numerous clathrin-coated pits and vesicles occurred between the actin filaments. In these cells, intermediate filaments, but not actin filaments, were the predominant cytoskeletal components in perinuclear regions and were attached to the cell nucleus, mitochondria and other vesicular cell organelles. A similar distribution of cytoskeletal components was observed in the mononuclear macrophages of the granulomas and the peritoneal macrophages. These results show that the cytoskeletal organization varies in different regions of the cytoplasm of multinucleate giant cells, while the characteristic cytoskeletal arrangement, resembling that of mononuclear macrophages, is maintained.     

Proliferation of multinucleate cells with unbalanced nuclei

When onion root meristems are treated with gamma-hexachlorocyclohexane the anaphase chromatids are distributed in discrete unbalanced groups and subsequent inhibition of cytokinesis in these cells produced a synchronous population of viable multinucleate cells with two, three of four aneuploid nuclei. When we compare the duration of G1, S and G2 periods in diploid cells with that obtained for multinucleate cells in the present study it seems clear that the differences, if they occur, are negligible. These results are consistent with the hypothesis that the cell mass/genome ratio can play an essential role in controlling cycle rate and that most of the genic requirements for interphase development must complement between the nuclei sharing a common cytoplasm, even though some factor inside every nucleus appears to be required for replicative capacity to be effective.     

Role of macrophages and multinucleate giant cells in the resorption of corpora amylacea in the involuting bovine mammary gland

Summary Microscopic examination of involuting bovine mammary tissue revealed elevated concentrations of corpora amylacea in alveolar lumina. Morphologic relationships between amyloid bodies, macrophages, and multinucleate giant cells (MGCs) suggested phagocytosis and degradation of the deposits by the phagocytic cells. Resorption of amyloid material by macrophages and MGCs during the process of mammary involution may be instrumental in preventing accumulation of corpora amylacea in secretory tissue which may interfere with mechanisms of milk synthesis and secretion.     

Microtubule rearrangements during mitosis in multinucleate cells

The peroxidase-antiperoxidase (PAP) method for the detection of polymerized tubulin has been used to study the microtubule rearrangements during mitosis in PtK1 and HeLa multinucleate cells obtained by polyethyleneglycol (PEG)-mediated fusion. We demonstrate here that the transition of the microtubular cytoskeleton from interphase to mitosis is an inducible event and independent of the factor(s) responsible for chromatin condensation and nuclear envelope breakdown. However, for the induction of the microtubule rearrangements nuclear envelope breakdown is required. At midprophase, cytoskeletal microtubule rearrangements start for multinucleate PtK1 cells, whereas in HeLa cells such changes are delayed, and a more abrupt transition is observed here. After complete nuclear envelope breakdown (prometaphase) mitotic asters and spindles but no cytoplasmic (interphase) microtubuli can be observed in both systems. Metaphase is characterized by an interaction between the different mitotic poles which show the form of bipolar spindles, but individual separated mitotic poles far removed from the chromatin can also be seen.     

The behavior of centrosomes in multinucleate cells formed after colcemid treatment

Multinucleate PtK1 cells were generated by treating the cells with colcemid for up to 60 h. Cells with scattered chromosomes reconstructed nuclear envelopes around these chromosomes. After recovery of up to 36 h these multinucleate cells went into mitosis. In such cells mainly two types of spindles are found: a bipolar spindle with some "accessory" half-spindles and multipolar mitotic apparatus with several equally-sized half-spindles ordered in an irregular way. Ultrastructural studies revealed centrosomes within such spindles which had not developed a microtubular connection to chromosomes and obviously could not act as mitotic pole. This result is interpreted in the way that centrosomes undergo a maturation cycle. Immature centrosomes cannot form mitotic poles. The asynchrony of the cycles of the multiple centrosomes seems to be generated by an uneven distribution of special factor(s).     

Nuclear asynchrony in multinucleate rat kangaroo cells

Multinucleate (MN) cells were induced in PtK1 cells by colcemid treatment. A large percentage of cells developed nuclear asynchrony both in relation to DNA synthesis and mitosis within one cell cycle. Asynchrony could be traced even in metaphase and anaphase cells in which interphase nuclei, PCC of S-phase nuclei and less condensed prophase-like chromosomes could be observed along with normally condensed chromosomes. The occurrence of such abnormalities in these large MN cells may be explained on the basis of an uneven distribution of inducer molecules of DNA synthesis and mitosis due to cytoplasmic compartmentation. The less condensed form of all the chromosomes except chromosome 4 could be traced in asynchronous metaphase. The failure of the less condensed chromosomes to undergo complete condensation does not always appear to result from late entry of nuclei containing these chromosomes into G2 phase. It is likely that chromosome 4 carries gene(s) for chromosome condensation, as this chromosome itself never appears in a less condensed form. The inducers for chromosome condensation may not always be available at equal concentrations to all chromosomes located in separate nuclei, thus they may sometimes fail to undergo complete condensation before other nuclei reach the end of prophase, when the nuclear envelopes of all nuclei present in the cell break down simultaneously.     

Heterogeneity in mitochondrial morphology and membrane potential is independent of the nuclear division cycle in multinucleate fungal cells

In the multinucleate filamentous fungus Ashbya gossypii, nuclei divide asynchronously in a common cytoplasm. We hypothesize that the division cycle machinery has a limited zone of influence in the cytoplasm to promote nuclear autonomy. Mitochondria in cultured mammalian cells undergo cell cycle-specific changes in morphology and membrane potential and therefore can serve as a reporter of the cell cycle state of the cytoplasm. To evaluate if the cell cycle state of nuclei in A. gossypii can influence the adjacent cytoplasm, we tested whether local mitochondrial morphology and membrane potential in A. gossypii are associated with the division state of a nearby nucleus. We found that mitochondria exhibit substantial heterogeneity in both morphology and membrane potential within a single multinucleated cell. Notably, differences in mitochondrial morphology or potential are not associated with a specific nuclear division state. Heterokaryon mutants with a mixture of nuclei with deletions of and wild type for the mitochondrial fusion/fission genes DNM1 and FZO1 exhibit altered mitochondrial morphology and severe growth and sporulation defects. This dominant effect suggests that the gene products may be required locally near their expression site rather than diffusing widely in the cell. Our results demonstrate that mitochondrial dynamics are essential in these large syncytial cells, yet morphology and membrane potential are independent of nuclear cycle state.     

Mitotic asynchrony of multinucleate cells in tissue culture

A high degree of mitotic asynchrony is reported for spontaneously arising multinucleate cells of HeLa and Pt-K1, tissue culture cell lines. Neither nuclear number, nor nuclear size nor the presence or absence of nucleoli, could be directly related to the asynchronous behaviour of the cells. Suboptimal levels of nutrients led to a higher frequency of asynchrony. A partial compartmentation of the cytoplasm could be detected in some of the multinucleate cells. The compartmentation of the cytoplasm may lead to an uneven distribution of inducer and non-inducer metabolites. All these factors together may be responsible for the high degree of mitotic asynchrony.