Phosphorylation of nonhistone proteins during the HeLa cell cycle. Relationship to DNA synthesis and mitotic chromosome condensation

Cell cycle variations in the phosphorylation of chromatin-associated nonhistones were determined. Cells were radiolabeled with [32P]orthophosphate and chromatin was obtained by mild digestion of nuclei with micrococcal nuclease. The experiments were performed in the presence of a substrate inhibitor of alkaline phosphatase, beta-glycerophosphate. The results show that, while similar molecular weight species of phosphorylated nonhistones are associated with interphase chromatin through the HeLa cell cycle, the incorporation (32P cpm/micrograms of protein) profiles of selected major phosphononhistones show substantial changes. The most prominent peaks of specific radioactivity occur in the DNA synthesis phase (S phase). The phosphorylation states of the proteins of isolated metaphase chromosomes were also determined. Nonhistone proteins of isolated metaphase chromosomes are strikingly dephosphorylated, especially in comparison to histone H1. The phosphorylation of the major phosphononhistone of chromatin, which has a molecular weight of 55,000, was further characterized by techniques that included one-dimensional peptide mapping in sodium dodecyl sulfate-polyacrylamide gels and nonequilibrium pH gradient slab gel electrophoresis. Phosphoproteins are also components of the nuclear scaffold, and cell cycle variations in these proteins were investigated. The primary phosphorylated species has a molecular weight of 119,000. As with chromatin-associated nonhistones, this nuclear scaffold protein shows substantial incorporation of 32P in S phase, and a high level of incorporation also occurs close to mitosis.     

The effect of 5-fluorouracil on the mitotic cycle and DNA synthesis in the epithelium of mouse small intestine.

The examinations were performed on 42 mice of the Porton strain. The experimental animals were injected intraperitoneally with the dose of 75 mg of 5-fluorouracil per kg body weight. The first experimental group received injections of [3H]thymidine within 48 hours and the second group within 96 hours of the injection of 5-fluorouracil. Two mice from each group were killed at within 1, 2, 4, 8, 12, 24, and 48 hours of the [3H]thymidine injection. Calculations of the mitotic index and time of duration of individual phases of the mitotic cycle in epithelial cells of the small intestine were based on application of the autoradiographic method. These studies lead to the conclusion that 5-fluorouracil disturbs the course of metabolic processes in the cell, which are also related with the distribution of the genetic material. Histological examinations show that 5-fluorouracil produces profound morphological changes in the intestine, which affect both the intestinal epithelium and the connective tissue stroma. The autoradiographic tests revealed a considerable suppression of the mitotic activity of the epithelium of intestinal crypts. Moreover, it was shown that 5-fluorouracil inhibits the mitotic activity of the intestinal epithelium by diminishing the number of cells capable of entering into mitosis. Nevertheless, by 96 hours following introduction of a single dose of 5-fluorouracil normal morphological structure and mitotic activity of the intestinal wall cells are restored.     

The relationship of DNA synthesis to protein accumulation in the cell nucleus

The relationship between DNA synthesis and protein accumulation in cell nucleus and cytoplasm has been investigated by the use of a combination of ultramicrointerferometric and ultramicrospectrophotometric methods. 5-Fluoro-2'-deoxyuridine (FUdR) inhibited DNA synthesis, resulting in inhibition of cell proliferation in G-1 and early S-phase. However, synthesis and accumulation of protein continued in the presence of FUdR, as indicated by a 54% increase in the average dry mass value per individual cell during 18-hour exposure to FUdR; due primarily to protein accumulation in the cytoplasm, the average cytoplasmic dry mass increased by as much as 85%, while the dry mass of the nucleus increased by only 21%. The dry mass values of individual nuclei were well-correlated to the nuclear DNA content throughout the period of exposure to FUdR. In contrast to the continued accumulation of protein in the cytoplasm during inhibition of DNA synthesis, protein accumulation in the nucleus was inhibited. When cells were released from inhibition of DNA synthesis by the addition of 2'-deoxythymidine, the nuclear DNA content and nuclear dry mass increased in near-synchrony, there being some evidence that DNA synthesis was initiated somewhat prior to initiation of increase in nuclear dry mass. Thus, it appears that DNA synthesis (or an increase in nuclear DNA content) is intimately related to the regulation of protein accumulation in the nucleus.     

The mitotic cycle and DNA repair in UV-irradiated murine neuroblastoma cells]

A correlation has been shown between a reduced rate of movement of UV-irradiated neuroblastoma cells from G1 into S phase, an essential increase of cells in S phase while progressing through the cell cycle, and a defect in free DNA synthesis on a damaged template. These indices may reflect one and the same cell response to the UV light.     

Contribution of caspase(s) to the cell cycle regulation at mitotic phase

Caspases have been suggested to contribute to not only apoptosis regulation but also non-apoptotic cellular phenomena. Recently, we have reported the involvement of caspase-7 to the cell cycle progression at mitotic phase by knockdown of caspase-7 using small interfering RNAs and short hairpin RNA. Here we showed that chemically synthesized broad-spectrum caspase inhibitors, which have been used to suppress apoptosis, prevented the cell proliferation in a dose-dependent manner, and that the subtype-specific peptide-based caspase inhibitor for caspase-3 and -7, but not for caspase-9, inhibited cell proliferation. It was also indicated that the BIR2 domain of X-linked inhibitor of apoptosis protein, functioning as an inhibitor for caspase-3 and -7, but not the BIR3 domain which plays as a caspase-9 inhibitor, induced cell cycle arrest. Furthermore, flow cytometry revealed that the cells treated with caspase inhibitors arrested at G(2)/M phase. By using HeLa.S-Fucci (fluorescent ubiquitination-based cell cycle indicator) cells, the prevention of the cell proliferation by caspase inhibitors induced cell cycle arrest at mitotic phase accompanying the accumulation of the substrates for APC/C, suggesting the impairment of the APC/C activity at the transition from M to G(1) phases. These results indicate that caspase(s) contribute to the cell cycle regulation at mitotic phase.     

The centrosome cycle in the mitotic cycle of sea urchin eggs

When sea urchin eggs entering mitosis are exposed to an appropriate concentration of mercaptoethanol, the chromosome cycle is restrained while the centrosome cycle advances. The two poles of the mitotic apparatus separate into four poles, while the chromosomes remain in their metaphase arrangements until released by the removal of the mercaptoethanol. We follow the centrosomes through the stages of the generation of two poles by each original pole. In electron microscopic studies, the osmiophilic component of the centrosomes serves as an indicator of their changing forms as each pole generates two poles. In light microscopic studies, including observations of birefringence, the shapes of the polar ends of the spindles are taken as indicators of the shapes of the centrosomes. The successive stages of the centrosome cycle are (1) compact spherical centrosomes at the time of formation of the mitotic apparatus; (2) expansion and flattening of the centrosomes, leading to (3) formation of thin flat plates, perpendicular to the spindle axis. Corresponding to the extended flat shape of the centrosomes, the spindle poles are flat; microtubules 'point' to the centrosomal plate and not the centrioles. The centrioles are separated in the flattening of the centrosomes. (4) The flat plate divides into two and each of the two halves becomes more compact, defining two separate poles. Our findings resurrect and update Boveri's [5] observations and interpretations of the centrosome. Centrosomes have shapes. The shapes may be imparted to the microtubular structures that they generate. The formation of two separate centrosomes from one, in the formation of mitotic poles, is describable as a sequence of changes in shape.     

Stepwise effects of cytokinin activity and DNA synthesis upon mitotic cycle events in partially synchronized tobacco cells

Cytokinin addition to tobacco cell suspensions induced synchronous cell division after an 18 h lag period. Although continuous presence of the cytokinin in the culture medium during this lag period was essential to division, cytokinin was not required during mitosis itself. For each cell generation, cytokinin-dependent events are thus completed before mitosis occurs.Two experiments suggested that these cytokinin-dependent events are independent of DNA synthesis:

1. (i) With or without cytokinin, DNA synthesis proceeded normally in the presence of auxin, for at least the time required for one cell generation in complete medium.

2. (ii) In the presence of cytokinin, when DNA synthesis in the lag period was inhibited by FUdR, one normal cell division occurred when cytokinin was withdrawn and DNA synthesis restored by thymidine addition.

In cytokinin-starved cells, metaphase was greatly prolonged although prophase was unaffected.