Cell cycles in the male accessory glands of mealworm pupae

During the pupal stage of Tenebrio molitor, the accessory reproductive glands of males grow by cell division. Within the secretory epithelium of the bean-shaped accessory glands (BAGs), cell numbers triple. In the tubular accessory glands (TAGs), the increase is 14-fold. There are two mitotic maxima in each gland. The first maximum occurs at 1-2 days while the second is at 4-5 days. The second maximum coincides with the major ecdysteroid peak described by Delbecque et al. [Dev. Biol. 64, 11-30 (1978)]. Nuclei were isolated from TAGs during the pupal mitotic bouts and during mitotic inactivity in the adult. After Feulgen or propidium iodide staining, the DNA content of these nuclear populations was measured by absorption cytophotometry or by fluorescence flow cytometry, respectively. The proportion of cells in each phase of the cycle was calculated using an iterative model. After mitoses have ended in the late pupa, the cells were arrested in G2. [3H]Thymidine was injected into 1- and 4-day pupae to pulse-label cells of the TAGs. After allowing various periods from 4 to 60 hr for cells to progress through G2 to reach mitosis, fractions of labelled mitoses were determined by autoradiography. From the combined cytometric and autoradiographic data, the duration of each phase of the cell cycle was calculated assuming the population was in exponential growth. Cell cycles in 4-day pupal TAGs take 48 hr. G1, S, G2, and, M lasted 13, 14, 17, and 4 hr, respectively.     

Influence of infralow-frequency magnetic fields of high and ultrahigh intensity on the division of mammalian cells in vivo

The influence of an infralow-frequency magnetic field (IMF) with intensity 3-127 k0e for 1 h on the mitotic activity, frequency of chromosome aberrations, and number of corneal epithelial cells of mice was studied. It was shown that the changes in mitotic activity that arise can be explained by a reversible inhibition of cell division at late stages of the mitotic cycle and synchronous entry into mitosis after the removal of this inhibition. The nature of the dependence of the effect on the intensity of the IMF is evidence of a difference in its molecular mechanisms in the region of high and ultrahigh intensities. As a result of the influence of an IMF of the intensity and duration used, no increase in the frequency of aberrant mitoses in corneal epithelial cells was detected. The number of cells in a standard visual field of the microscope also was practically unchanged.     

Circadian rhythm of the mitotic activity and of the number of nuclei synthesizing DNA in sarcoma 37 in white mice]

Circadian variations in the frequency of mitoses and the number of nuclei labed with thymidine-H3 in sarcoma-37 of mice were investigated. It was shown that the circadian rhythm of mitotic activity was composed of diurnal variations in the frequency of labeled and unlabeled mitoses. The G2-phase of mitotic cycle of the cells with labeled mitosis was approximately one hour. The G2-phase of the cells with unlabed mitosis lasted four hours and more. It is suggested that there are two cell populations in sarcoma-37.     

A comparative investigation of the antimitotic action of 2-mercaptoethanol and colcemid on V-79 Chinese hamster cells

Abstract. The current study was performed to characterize the antimitotic action of 2-mercaptoethanol (MET) on mammalian cells.
At concentrations of 2.5 × 10^-2 M, MET arrests V-79 Chinese hamster cells in metaphase. Smaller concentrations (from 5 × 10^-3 M) only produce a mitotic block after several hours, only arresting those mitoses which have gone through one cell cycle in the presence of MET. The accumulation of mitoses by MET is smaller in comparison with colcemid, explained by an effect reducing the number of cells which enter mitosis. In contrast to colcemid, MET-concentrations which do not lead to a mitotic block cause a delay in proliferation. It was shown, by means of the BUdR-labelling method that cells in the presence of colcemid concentrations which arrest mitosis again enter interphase and become polyploid, whereas MET leads to an irreversible arrest of mitosis and does not produce polyploidy in V-79 cells.     

Circardian rhythm of mitoses in the epithelium of the cornea after splenectomy]

In corneal epithelium of CBA mice the index of colchicine mitoses diminished after splenectomy in the day period characterized by rising mitotic activity in control animals. The duration of active phase of cell division rhythm shortened while the maximum of mitotic activity delayed in comparison with control animals. The total amount of cells entering mitosis during 24 hours diminished by 27.7% and the rate of physiological regeneration of corneal epithelium decreased.     

Photodynamic effects of Photofrin II on cell division in human NHIK 3025 cells

Human cervix carcinoma cells of the line NHIK 3025 were exposed to light after 18 h incubation with Photofrin II. After this photodynamic treatment cells in the interphase were retarded with respect to entry into mitosis for a period which increased with increasing light dose. Following the prolonged interphase, an increase in the mitotic index was observed, giving rise to a 3-fold higher level of mitotic cells compared to the control level. Staining of methanol-fixed cells with the DNA-specific dye mithramycin indicated that the increase in mitotic index was due to a prolongation of the metaphase. For all the light doses studied most of the metaphase cells could be characterized as three-group metaphases or c-metaphase-like structures for the first 8 h after treatment. An approximately 10-fold increase above the control level in the number of tripolar mitoses was also observed. A 2h incubation in a Photofrin II-free medium after the 18 h incubation with Photofrin II and before light exposure reduced the fluorescence of the cells by 30 per cent. However, this wash-out period had no effect on the increase in mitotic index after light exposure. A light dose corresponding to 80 per cent survival (as assayed on asynchronous cells) was given to cells in mitosis after Photofrin II incubation. This treatment delayed more than 90 per cent of the metaphase cells from entering the anaphase for at least 1 h. Cells photodynamically treated in the anaphase and telophase entered the interphase at a similar rate as control cells. These observations indicate a temporary block in the initiation of the anaphase and a prolongation of the metaphase. A microscopic study of cells immunologically stained for beta-tubulin 1 h after photodynamic treatment indicated that the organization of the spindle apparatus was disturbed by the photodynamic treatment. Such perturbations are suggested to be the cause of the observed accumulation of cells in mitosis.     

Changes in the proliferative activity of the corneal epithelium and the regenerating liver in partial splenectomy in mice

The mitotic activity in epithelial cells of the mouse cornea was studied 4 h, 1, 2, 5, 8 and 14 days after a sham operation or partial (2/3) splenectomy. The decrease in the number of dividing cells in the corneal epithelium was observed within two days after a sham operation and within five days after partial splenectomy. On the contrary, partial hepatectomy increased the number of mitoses in the corneal epithelium. Liver regeneration against the background of a sham operation or partial splenectomy was accompanied by a lesser number of mitoses (by a factor of 2.5-4) in hepatocytes than in the animals subjected to partial hepatectomy only.     

Control of cell division: a unifying hypothesis.

A constant feature of the initiation of cell division in a number of different cells is a rise in the intracellular level of calcium. The importance of cyclic nucleotides may depend on the way they interact with calcium. Cyclic AMP is apparently not an essential regulator of cell division but through its ability to modulate the intracellular level of calcium this cyclic nucleotide can exert profound effects on cell growth. In some systems (liver and salivary glands) cyclic AMP seems to augment the calcium signal whereas in others (lymphocytes and fibroblasts) it opposes calcium and can thus inhibit cell division. A rise in the level of calcium may be responsible for the parallel increase in cyclic GMP level which is usually associated with the stimulus to divide. An appealing feature of this calcium hypothesis is that it can account for the growth characteristics revealed by fibroblasts in tissue culture or embryonic cells during development. In both cases there is an initial phase of exponential growth during which I have proposed that the high level of calcium at mitosis persists into early G1 to provide the signal for the next division. In order to account for the sudden cessation of cell division at confluency, or at a specific stage during development, it is necessary to postulate that there is something different about the final mitosis which sets it apart from earlier mitoses. It is proposed that as the cells leave the last mitosis the level of calcium falls much more rapidly than it did during preceeding mitoses perhaps as a result of a more rapid rise in the level of cyclic AMP. This rapid rise in cyclic AMP level may have a dual function. Not only will it lower the level of calcium thus preventing further division, but it may also stimulate differentiation. Many of the embryonic cells which differentiate into specialized cells (lymphocytes, liver, salivary gland) retain the ability to divide if provided with appropriate stimuli. Although the nature of these stimuli vary considerably, they all seem to act by elevating the intracellular level of calcium.     

Role of multipolar mitoses in the proliferation of multinucleate cells induced by cytochalasin B

A prolonged action of cytochalasin B results in the formation of numerous multipolar mitoses (26%) in Chinese hamster cell cultures. The transition to multipolar mitoses in the presence of cytochalasin B is not accompanied by K-mitotic delay. It is shown that a multipolar mitosis without cytoplasmic division is one of the main causes of multinucleation development in cytochalasin B-treated cultures. After stopping the drug action the cytochalasin B-induced multinucleate cells continue to divide by multipolar mitosis. In this case it completes with cytokinesis and, probably, leads to a decrease in the number of nuclei per cell. The origin of multipolar mitotic apparatus after the action of cytochalasin B is discussed in addition to the role of multipolar mitosis in formation and proliferation of multinucleate cells.     

The terminal basal mitosis of chicken retinal Lim1 horizontal cells is not sensitive to cisplatin-induced cell cycle arrest

For proper development, cells need to coordinate proliferation and cell cycle-exit. This is mediated by a cascade of proteins making sure that each phase of the cell cycle is controlled before the initiation of the next. Retinal progenitor cells divide during the process of interkinetic nuclear migration, where they undergo S-phase on the basal side, followed by mitoses on the apical side of the neuroepithelium. The final cell cycle of chicken retinal horizontal cells (HCs) is an exception to this general cell cycle behavior. Lim1 expressing (+) horizontal progenitor cells (HPCs) have a heterogenic final cell cycle, with some cells undergoing a terminal mitosis on the basal side of the retina. The results in this study show that this terminal basal mitosis of Lim1+ HPCs is not dependent on Chk1/2 for its regulation compared to retinal cells undergoing interkinetic nuclear migration. Neither activating nor blocking Chk1 had an effect on the basal mitosis of Lim1+ HPCs. Furthermore, the Lim1+ HPCs were not sensitive to cisplatin-induced DNA damage and were able to continue into mitosis in the presence of γ-H2AX without activation of caspase-3. However, Nutlin3a-induced expression of p21 did reduce the mitoses, suggesting the presence of a functional p53/p21 response in HPCs. In contrast, the apical mitoses were blocked upon activation of either Chk1/2 or p21, indicating the importance of these proteins during the process of interkinetic nuclear migration. Inhibiting Cdk1 blocked M-phase transition both for apical and basal mitoses. This confirmed that the cyclin B1-Cdk1 complex was active and functional during the basal mitosis of Lim1+ HPCs. The regulation of the final cell cycle of Lim1+ HPCs is of particular interest since it has been shown that the HCs are able to sustain persistent DNA damage, remain in the cell cycle for an extended period of time and, consequently, survive for months.     

Arrangement of spindle apparatus in mitoses of different ploidy

In non-hypotonically treated mitoses from tissue cultures of Microtus agrestis, both the constitutive heterochromatin of the sex chromosomes and the spindle apparatus were stained by the Giemsa C-banding technique. By means of counting the heterochromatic chromosomes, we determined the cell ploidy and studied the number of centrioles and the spindle arrangement of diploid, triploid, tetraploid and octoploid mitoses. Diploid and triploid prophases contained 2 centrioles in most cases, tetraploid prophases 4, binucleate cells with 2 diploid nuclei likewise 4 and binucleate cells with 2 tetraploid nuclei 8 centrioles. Nearly 99% of diploid and triploid metaphases were bipolar. Of the tetraploid metaphases only 45% were bipolar, 29.5% tripolar, 7.5% quadripolar and 18% formed as a parallel mitosis. In all examined binucleate cells that had had an asynchronous DNA synthesis, a multipolar mitosis was found.     

G2 sub-population in mouse liver induced into mitosis by lead acetate

A single intracardiac dose of lead acetate (40 microgram lead/g body weight) induced a 25-fold increase in mitosis of mouse hepatocytes 5 hr after injection, as determined by autoradiography. The prompt appearance of a mitotic wave and the relatively large number of mitoses suggest that the mitotic cells were derived from a hepatocyte sub-population arrested in the G2 phase. The injection of lead also stimulated a small increase in labeled hepatocytes within 6 hr. Analysis of grain counts gave no evidence for unscheduled DNA synthesis. The incremental labeled cells may have originated from a small fraction of the G1 population that was ready to enter the S phase without the usual pre-synthetic delay.     

Mitotic activity changes in the corneal epithelium of rats of different ages following exposure to pain]

A study was made of pain stimulus (amputation of 1/3 of the tail) on the mitotic activity in the corneal epithelium of 21-day fetuses, 1-, 3-, 4-, 5-, 7-, 10-, 15-, 20- and 25-day rats. In 45 minutes after the infliction of trauma no significant change was seen in the cornea of the fetuses and of the one-day-old ratlings. A gradual establishment of the reactive inhibition of mitoses in response to pain occurred between the 3rd and the 10th day of postnatal development. This reaction became more intense after the 10th day, reaching the maximum by the 25th day. Reactive inhibition of the mitotic activity was connected with the inhibition of the entrance of cells into mitosis.     

Thymus involution and recovery in mice after the administration of lipopolysaccharide

The single injection of 50 micrograms LPS induces polyclonal immune response in the spleen of (CBA x C57B1/6) F1 mice. It is accompanied by the thymic involution and depletion of blasts and mitoses, as showed morphometric analysis. Vinblastin does not induce: accumulation of the mitoses during the first and second days after LPS injection. The regeneration of the thymus begins already from the second day with increasing of blast cells, reaching a maximum at the 3rd day. The mitosis wave retards two days and achieves peak at the 5th day. The regeneration of the thymus finishes at the 13th day aster LPS injection, but the blast number is higher, than the control level.     

Variable pathways for developmental changes of mitosis and cytokinesis in Physarum polycephalum

The development of a uninucleate ameba into a multinucleate, syncytial plasmodium in myxomycetes involves a change from the open, astral mitosis of the ameba to the intranuclear, anastral mitosis of the plasmodium, and the omission of cytokinesis from the cell cycle. We describe immunofluorescence microscopic studies of the amebal-plasmodial transition (APT) in Physarum polycephalum. We demonstrate that the reorganization of mitotic spindles commences in uninucleate cells after commitment to plasmodium formation, is completed by the binucleate stage, and occurs via different routes in individual developing cells. Most uninucleate developing cells formed mitotic spindles characteristic either of amebae or of plasmodia. However, chimeric mitotic figures exhibiting features of both amebal and plasmodial mitoses, and a novel star microtubular array were also observed. The loss of the ameba-specific alpha 3-tubulin and the accumulation of the plasmodium-specific beta 2-tubulin isotypes during development were not sufficient to explain the changes in the organization of mitotic spindles. The majority of uninucleate developing cells undergoing astral mitoses (amebal and chimeric) exhibited cytokinetic furrows, whereas cells with the anastral plasmodial mitosis exhibited no furrows. Thus, the transition from astral to anastral mitosis during the APT could be sufficient for the omission of cytokinesis from the cell cycle. However, astral mitosis may not ensure cytokinesis: some cells undergoing amebal or chimeric mitosis contained unilateral cytokinetic furrows or no furrow at all. These cells would, most probably, fail to divide. We suggest that a uninucleate committed cell undergoing amebal or chimeric mitosis can either divide or else form a binucleate cell. In contrast, a uninucleate cell with a mitotic spindle of the plasmodial type gives rise only to a binucleate cells. Further, the decision to enter mitosis after commitment to the APT is independent of the developmental changes in the organization of the mitotic spindle and cytokinesis.     

Nutritional Requirements for Polyploid Mitoses in Cultured Pea Root Segments

Diploid and polyploid mitoses could be stimulated in excised segments of the mature region of pea roots grown on a sterile culture medium. Diploid mitoses were observed in segments cultured on water alone for 72 hours. Their frequency was increased by the presence of salts, sucrose, vitamins, and any two or all three of the following: an amino mixture, auxins, and kinetin. Polyploid mitoses were observed 72 hours after the beginning of the culture period in segments cultured on salts, sucrose, vitamins, auxins, and kinetin. Polyploid mitoses required the presence of auxins and kinetin in the culture medium. Their frequency was not affected by the presence of a reduced nitrogen source. Light treatments had no effect on the frequency of diploid or polyploid mitoses. Diploid mitoses were first observed about 24 hours after the beginning of the culture and their frequency increased thereafter. Experiments with colchicine showed that diploid cells were entering mitosis for the first time as late as 60 hours after the beginning of the culture. Polyploid mitoses showed a long lag time when compared with diploid mitoses. They began at about 60 hours and their frequency increased thereafter. Experiments with colchicine showed that polyploid cells were entering mitosis for the first time as late as 84 hours after the beginning of the culture. The presence of kinetin in the medium was not required during the first 24 hours in culture for the appearance of polyploid mitoses at 74 hours. However, the presence of kinetin was required after 24 hours. Auxin was required at some time during the first 24 hours of the culture and its continuous presence may be required for the stimulation of polyploid mitoses.     

CELL CLASSIFICATION AND KINETIC ASPECTS OF NORMOBLASTIC AND MEGALOBLASTIC ERYTHROPOIESIS

Mitotic indices and ³H-thymidine flash labelling indices have been determined in a total of 6000 erythroid cells from patients with megaloblastic anaemia (vitamin B₁₂ deficiency) and 4000 erythroid cells from patients with increased, normoblastic erythropoiesis. In the anaemic states there is a lack of mitoses in the more mature erythroid compartments relative to the number of mitoses in the early erythroid precursors; this must reflect skipped division and/or cell death in the later precursors. In order to further locate the deficit of mitoses, erythropoietic cells were subdivided in a way which aimed at stratifying them according to cell generations. It appears that there are four consecutive generations of recognizable proliferating red cell precursors. Balance considerations of mitotic figures suggest that in stressed normopoiesis all cells which enter generation III divide, whereas only about one-half of cells leaving generation III divide again in generation IV. In megaloblastic erythropoiesis it appears that only about one of three cells which leave generation III divide in generation IV. The data suggest that in megaloblastic anaemia, skipped division and/or cell death to a large extent take place in generation IV or at the transition from III to IV. In normoblastic erythropoiesis, the ratio labelled cells/mitotic cells is rather independent of cell maturation. In contrast, this ratio varies considerably in megaloblastic erythropoiesis, from 25:1 in early forms to 4-5:1 in late forms. As an explanation of the lack of mitoses, relative to cells in DNA-synthesis, in the early stages and the relative surplus of mitoses in the late stages it is proposed that cell cycle and cytological boundaries do not coincide in all cells. The present observations can be accounted for if a significant fraction of cells change their morphology (from basophilia to polychromasia) between their DNA-synthesis phase and the subsequent mitosis. It cannot be decided whether in addition there is a death function between DNA-synthesis and mitosis in the large basophilic megaloblasts, megaloblastic system could absorb a direct entry from the large basophilic cells amounting to perhaps about one-half of the flux through the S-pool of the large basophilic cells without being more dominated by very large cells than is actually the case; still, in large measure this will depend on the time from entry into the polychromatic pool until the subsequent mitosis or possible cell death. The alternative is a significant death function between S-phase and mitosis at the level of the large basophilic E1-E2 cells (generation I + II).     

Mechanism of the myeloinhibitory effect of carminomycin]

The proliferative activity and level of aberrant mitoses in the cells of the bone marrow were studied experimentally on 223 noninbred mice treated with carminomycin administered intraperitoneally in single (LD50) and repeated doses. When the antibiotic was used in a single dose the values of the mitotic activity of the bone marrow elements did not correspond to the severity of depression and thir quantitative composition, which was explained by an impairement of the mitosis quality and possible interkinetic destruction of a significant part of both erythroid and immature myeloid cells capable of division at early stages after the exposure. At the same time the level of the bone marrow devastation under conditions of the treatment with repeated doses was mainly determined by inhibition of the erythronormoblast proliferative activity.     

Heterogenic Final Cell Cycle by Chicken Retinal Lim1 Horizontal Progenitor Cells Leads to Heteroploid Cells with a Remaining Replicated Genome

Retinal progenitor cells undergo apical mitoses during the process of interkinetic nuclear migration and newly generated post-mitotic neurons migrate to their prospective retinal layer. Whereas this is valid for most types of retinal neurons, chicken horizontal cells are generated by delayed non-apical mitoses from dedicated progenitors. The regulation of such final cell cycle is not well understood and we have studied how Lim1 expressing horizontal progenitor cells (HPCs) exit the cell cycle. We have used markers for S- and G2/M-phase in combination with markers for cell cycle regulators Rb1, cyclin B1, cdc25C and p27Kip1 to characterise the final cell cycle of HPCs. The results show that Lim1+ HPCs are heterogenic with regards to when and during what phase they leave the final cell cycle. Not all horizontal cells were generated by a non-apical (basal) mitosis; instead, the HPCs exhibited three different behaviours during the final cell cycle. Thirty-five percent of the Lim1+ horizontal cells was estimated to be generated by non-apical mitoses. The other horizontal cells were either generated by an interkinetic nuclear migration with an apical mitosis or by a cell cycle with an S-phase that was not followed by any mitosis. Such cells remain with replicated DNA and may be regarded as somatic heteroploids. The observed heterogeneity of the final cell cycle was also seen in the expression of Rb1, cyclin B1, cdc25C and p27Kip1. Phosphorylated Rb1-Ser608 was restricted to the Lim1+ cells that entered S-phase while cyclin B1 and cdc25C were exclusively expressed in HPCs having a basal mitosis. Only HPCs that leave the cell cycle after an apical mitosis expressed p27Kip1. We speculate that the cell cycle heterogeneity with formation of heteroploid cells may present a cellular context that contributes to the suggested propensity of these cells to generate cancer when the retinoblastoma gene is mutated.     

Contact regulation of cell division in an epithelial-like cell line

The rate of cell division in an epithelial-like cell line, 1S1, was examined by time-lapse cinemicrography. When precautions were taken to insure a sufficient nutrient supply, the number of mitoses per unit time in any given area of a confluent monolayer remained constant. This “contact regulation of cell division” resulted in a steadily decreasing frequency of mitosis per cell as the culture became crowded. With the decrease was associated a gradual change in cell shape, from maximally flattened to maximally compact, due to contact inhibition of the movement of cells across one another. When cells were removed along a line scraped on a dense culture, the cells at the edge of the scrape flattened, migrated into the vacant area, and subsequently increased their frequency of mitosis to that characteristic of non-confluent cells. Inhibition of mitosis caused by a limitation on the nutrient supply was also reversed at a line-scrape. These observations suggest that cell flattening promoted mitosis by causing the cell membrane to expand, thereby facilitating the uptake of nutrients. The cell membrane would thus function in the mechanism of contact regulation as a transducer, for converting the pressure of the surrounding cell population into a restraining force upon the metabolism of cell division.