Protein Phosphorylation During the Transitions from G1 Arrest Point to S and G2 Arrest Point to M in Vicia faba Root Meristem

Using monoclonal FITC conjugated antibodies that specifically recognize phosphorylated form of threonine (-T^P-FITC) it was shown that in excised, sugar-starved root meristems of Vicia faba subsp. minor the expression of two principal control points (PCPs) is correlated with a marked decrease in nuclear and nucleolar phosphorylation of proteins. When stationary phase meristems are supplied with 2 % sucrose, the G1-arrested cells start out DNA replication (assessed by pulse ³H-thymidine labeling), while the cells blocked in G2 phase initiate mitotic divisions. Using this model, we have found that depending on the period during which the sucrose-mediated PCP1S and PCP2M transitions are affected by 6-dimethylaminopurine, an inhibitor of protein kinases, the release from G1 and G2 phase arrest-points of the cell cycle become prolonged, showing different time-course modifications. Furthermore, our results seem to implicate that both PCP1 and PCP2 comprise subpopulations of cells differing with respect to the rates at which they commence DNA replication and mitosis.     

Effect of OA-inhibitor of protein phosphatases PP1 and PP2A — on initiation of DNA replication and mitosis in <Emphasis Type="Italic">Vicia faba</Emphasis> root meristems

According to the principal control point (PCP) hypothesis, experiments with excised, carbohydrate-starved stationary root meristems of Vicia faba var. minor have demonstrated that cells which previously divided asynchronously were preferentially blocked in G₁ (PCP1) and G₂ (PCP2) phases. When stationary phase meristems are supplied with exogenous carbohydrate (2 % sucrose), the G1- and G2-arrested cells start out DNA replication and mitotic divisions, respectively. The resumption of DNA synthesis and mitosis is not immediate and the delays of G₁- and G₂-arrested cells are found different. Using this model, we examined the effects of 4 pulse incubations with okadaic acid (OA), a specific inhibitor of PP1 and PP2A, on the duration of intervals elapsing between the provision of sucrose and the first appearance of S- and M-phase cells. We have found that depending on the period during which OA had been applied, the release from G1 and G2 phase arrest-points becomes prolonged, showing different time-course modifications. The obtained data provide evidence that activation of PP1 and PP2A is required to allow the cells for both PCP1→S and PCP2→M transitions in root meristems of V. faba.     

CycD1, a putative G1 cyclin from Antirrhinum majus, accelerates the cell cycle in cultured tobacco BY-2 cells by enhancing both G1/S entry and progression through S and G2 phases

A putative G1 cyclin gene, Antma;CycD1;1 (CycD1), from Antirrhinum majus is known to be expressed throughout the cell cycle in the meristem and other actively proliferating cells. To test its role in cell cycle progression, we examined the effect of CycD1 expression in the tobacco (Nicotiana tabacum) cell suspension culture BY-2. Green fluorescent protein:CycD1 is located in the nucleus throughout interphase. Using epitope-tagged CycD1, we show that it interacts in vivo with CDKA, a cyclin dependent protein kinase that acts at both the G1/S and the G2/M boundaries. We examined the effect of induced expression at different stages of the cell cycle. Expression in G0 cells accelerated entry into both S-phase and mitosis, whereas expression during S-phase accelerated entry into mitosis. Consistent with acceleration of both transitions, the CycD1-associated cyclin dependent kinase can phosphorylate both histone H1 and Rb proteins. The expression of cyclinD1 led to the early activation of total CDK activity, consistent with accelerated cell cycle progression. Continuous expression of CycD1 led to moderate increases in growth rate. Therefore, in contrast with animal D cyclins, CycD1 can promote both G0/G1/S and S/G2/M progression. This indicates that D cyclin function may have diverged between plants and animals.     

Analysis of the interphase accumulation induced by hydroxyurea on proliferating plant cells.

Cell distribution in different compartments of the cell cycle (G1, early, middle and late S, G2 and mitosis) has been studied during continuous treatments with hydroxyurea (HU) in onion root meristems by cytophotometric and autoradiographic methods. A sublethal dosis of HU (0.75 mM) has been chosen to allow a good wave of mitotic synchrony during recovery, with a negligible level of chromosomal aberrations. Proliferating cells begin the S period in the presence of HU and are accumulated in early S, where the maximum value (60%) is reached after 8 h of treatment; at the same time middle and late S are practically empty. In the presence of the drug, residual DNA synthesis allows a slow but continuous progress of cells throughout the S period. Differential sensitivity of S cells to HU can be observed; replication is more affected in early S (85% inhibition) than in the second half of the period (70% inhibition). On the other hand, G1 cells are not apparently affected by HU, while cells in G2 show a delay in their entrance into mitosis.     

The effect of butyrate on the cell cycle in root meristems of Pisum sativum

Sodium butyrate at 5 mM in aerated White's medium reduced the mitotic index in root meristems of seedlings of Pisum sativum to < 1% after 12 h. This effect was lessened as the butyrate concentrations were lowered. The fraction of the root meristem nuclei in G2 increased to ~ 70% after 12 h in butyrate. After 12 h exposure to butyrate, seedlings transferred lo medium without butyrate gradually re-established their normal root meristem mitotic pattern, with a burst of mitosis at 10 h after the transfer. Even a brief exposure to butyrate inhibited DNA synthesis, and nuclei released from butyrate exposure were still unable to resume normal DNA synthesis even after 12 h. This information suggests that butyrate halts progression through the cell cycle by arresting meristem nuclei in G2 and inhibiting DNA synthesis.     

An improved method for the cell cycle synchronization of <Emphasis Type="Italic">Vicia faba</Emphasis> root meristem cells

Plant root meristem cells divide asynchronously which makes biochemical analysis of cell cycle regulation particularly difficult. In the present article a high level of cell cycle synchronization in Vicia faba root meristems was obtained by using a rich medium (HNS), special culture conditions and a double-block method with replication inhibitor—hydroxyurea (HU). Two HU concentrations were tested and different periods of the first and the second synchronization, and of cycle recommencement between the first and the second blockage. The level of synchronization was estimated on the basis of ³H-thymidine labeling indices, mitotic, and phase indices and indices determining the percentage of G1 and G2 cells, which were identified by cytophotometric measurements of DNA content in individual nuclei. The highest level of cell cycle synchronization was obtained after double treatment of meristems with 1.25 mM HU (18 and 12 h) separated by 6-h incubation in HNS without HU. During the second postincubation in HNS in subsequent hours: 4, 7, 10, 11, over 90% of cells in the S phase, nearly 70% in G2 phase, 86% in mitosis, and nearly 70% in G1 phase were received, respectively. The use of 2.5 mM HU in a similar experimental procedure caused disturbed divisions.     

Involvement of G1-to-S transition and AhAUX-dependent auxin transport in abscisic acid-induced inhibition of lateral root primodia initiation in Arachis hypogaea L

Previous study indicated that increasing endogenous abscisic acid (ABA) level could inhibit the lateral root (LR) formation of peanuts. In this study, we investigated the mechanisms by which ABA regulated lateral root primordia (LRP) initiation in peanuts (Arachis hypogaea L). Results suggested that ABA inhibited LRP initiation through blocking G1-to-S transition in seedlings and mature roots: e.g. 5.8% increase in the proportion of G1 phase and 18% decrease in the proportion of S phase after ABA treatment for 6 days. Further study of the expression of the cell cycle marker gene for G2-to-M transition in peanut roots suggested that AhCYCB1 expression was regulated by ABA. We also investigated the cooperative regulation of LRP initiation by ABA and indole-3-acetic acid (IAA). ABA treatment greatly reduced the effects of endogenous IAA on mature roots. The expression of the IAA polar transport gene AhAUX1 appeared to be regulated by ABA since ABA inhibited auxin-mediated LRP initiation by suppressing AhAUX-dependent auxin transport in peanut roots. We further examined the effect of ABA on the expression of DR5::GUS and AtAUX1 in the model plant Arabidopsis. The results of Arabidopsis were consistent with that of the peanut.     

The timing of synthesis of proteins required for mitotic spindle and phragmoplast in partially synchronized root meristems of Vicia faba L

After cycloheximide treatment (1 h, 2.5 micrograms/ml) protein synthesis was decreased by 70% and was partially restored after 7 h of postincubation (still 20% decrease). In partially synchronized root meristems of Vicia faba L. treated with cycloheximide at middle G2, a strong decrease of the mitotic index was observed. Exposure to the drug at late G2 did not modify the mitotic index; the changes in the phase indices suggested that the course of mitosis was blocked at prophase-metaphase/anaphase-telophase transitions. The use of indirect immunocytochemical staining of tubulin (second antibody labeled with peroxidase) made it possible to show a decreased number of cells with preprophase bands in cycloheximide-treated meristems and the mitotic spindles and phragmoplasts containing a reduced number of shortened bands of microtubules. As a result of these structural and functional disturbances, binucleate cells and polyploid nuclei were observed.     

PPF1 inhibits programmed cell death in apical meristems of both G2 pea and transgenic Arabidopsis plants possibly by delaying cytosolic Ca2+ elevation

PPF1 encodes a putative calcium ion carrier that affects the flowering time of transgenic Arabidopsis by modulating Ca(2+) storage capacities in chloroplasts of a plant cell. In the current work, we found that differential expression of PPF1 might affect processes of programmed cell death (PCD) since DNA fragmentation was detected in senescencing apical buds of long day-grown G2 pea (Pisum sativum L.) plants, but was not in non-senescencing short day-grown counterparts at all growth stages. An animal inhibitor of caspase-activated DNase (ICAD) homologue was detected in short day-grown plant continuously throughout the whole experiment and only in early stages of long day-grown pre-floral G2 pea apical buds. DNA fragmentation was significantly inhibited in apical meristems of transgenic Arabidopsis that over-expressed the PPF1 gene when compared to that of either wild-type control or to PPF1 (-) plants. The expression of ICAD-like protein decreased to undetectable level at 45 dpg in apical tissues of PPF1 (-) Arabidopsis, which was much earlier than that found in PPF1 (+) or wild-type controls. In epidermal cells of PPF1 (-) plants, we recorded significantly earlier calcium transient prior to PCD. We suggest that the expression of PPF1, a chloroplast localized Ca(2+) ion channel may inhibit programmed cell death in apical meristems of flowering plants by keeping a low cytoplasmic calcium content that might inhibit DNA fragmentation in plant cells.     

Changes in the Duration of the Mitotic Cycle Induced by Colchicine and Indol-3yl-acetic Acid in Vicia faba Roots

Cells of root meristems of Vicia faba were labelled with tritiatedthymidine and treated with colchicine or IAA or both. The effectsof these compounds on the duration of the mitotic cycle andits constituent phases have been determined using the labelledmitoses wave method of Quastler and Sherman. Colchicine shortensthe mitotic cycle of the cells in interphase at the time oftreatment; it appears to stimulate cells in G1 or early S tocomplete interphase faster than untreated cells. The affectedcells arrive at mitosis 9–12 h after the beginning oftreatment and contribute to the increase in mitotic index seenafter treatment with colchicine. Treatment with IAA did notaffect cells in G2 but it delayed cells in S; this results ina temporary fall in M.I. The effect of IAA in prolonging interphasewas also seen in roots treated with colchicine and IAA; thetetraploid cells induced by colchicine take longer to reachmetaphase than cells treated only with colchicine. The resultssuggest that colchicine and IAA affect different phases of thecell cycle.     

Activation of Cdh1-dependent APC is required for G1 cell cycle arrest and DNA damage-induced G2 checkpoint in vertebrate cells.

Anaphase-promoting complex (APC) is activated by two regulatory proteins, Cdc20 and Cdh1. In yeast and Drosophila, Cdh1-dependent APC (Cdh1-APC) activity targets mitotic cyclins from the end of mitosis to the G1 phase. To investigate the function of Cdh1 in vertebrate cells, we generated clones of chicken DT40 cells disrupted in their Cdh1 loci. Cdh1 was dispensable for viability and cell cycle progression. However, similarly to yeast and Drosophila, loss of Cdh1 induced unscheduled accumulation of mitotic cyclins in G1, resulting in abrogation of G1 arrest caused by treatment with rapamycin, an inducer of p27(Kip1). Further more, we found that Cdh1(-/-) cells fail to maintain DNA damage-induced G2 arrest and that Cdh1-APC is activated by X-irradiation-induced DNA damage. Thus, activation of Cdh1-APC plays a crucial role in both cdk inhibitor-dependent G1 arrest and DNA damage-induced G2 arrest.     

Discrepancies among the metaphase, telophase, and the G0/G1 and G2 DNA peaks of heteroploid cell lines

Heteroploid cell populations often show narrow peaks of G0/G1 and G2/M DNA content and broadly distributed chromosome numbers. This was originally explained by the selective metaphase arrest of the cells that have non-modal chromosome numbers. To test whether this explanation applies, we have measured the chromosome number distributions, as well as the G0/G1, G2, metaphase (M), and telophase (T) DNA distributions, of the cell lines WCHE-5, MCa-11, and HL-60. The WCHE-5 cells had narrowly distributed chromosome numbers and G0/G1 G2, M, and T DNA peaks. The MCa-11 and HL-60 cells also had narrowly distributed G0/G1 and G2 DNA peaks, but broadly distributed chromosome numbers and M and T DNA peaks. The widths of the MCa-11 and HL-60 M- and T-cell DNA peaks were similar to those of their chromosome number peaks, suggesting that all cells were completing mitosis, regardless of chromosome number or DNA content. Thus, selective metaphase arrest does not seem to be the cause of the narrow G0/G1 and G2 DNA peaks of heteroploid cell populations.     

Effect of Brassinolide on Growth and Shikonin Formation in Cultured Onosma paniculatum Cells

The effect of brassinolide (BR) on cell growth and shikonin and its derivative formation in Onosma paniculatum cell culture was studied. BR addition with IAA and BAP (+BR/+IAA/+BAP) in B₅ medium slightly increased the cell growth at 0.01–0.1 ppb concentration compared with a growth control (−BR/+IAA/+BAP). Only BR addition (+BR/−IAA/−BAP) at 0.001–100 ppb in B₅ medium significantly increased the cell fresh weight compared with a growth control (−BR/−IAA/−BAP). The same concentration of BR tested at 0–1000 ppb increased the cell fresh weight of +IAA/+BAP significantly more than that of −IAA/−BAP. BR at 0.001–0.1 ppb with IAA and BAP added (+BR/+IAA/+BAP) in M₉ medium increased shikonin and its derivative content markedly by 31–87%, compared with its control (−BR/+IAA/+BAP). BR at 0.001–1000 ppb without IAA and BAP added to M₉ medium (+BR/−IAA/−BAP) also increased shikonin and its derivative content compared with its control (−BR/−IAA/−BAP). However, the amount of shikonin and derivative formed of +IAA/+BAP was greater than that of −IAA/−BAP only at the same concentration of BR at 0–1 ppb. These combined results show that BR at 0.01 ppb with IAA and BAP added was the best for cell growth and shikonin formation. Formation of shikonin and its derivative by adding BR at 0.01 ppb with IAA and BAP (+BR/+IAA/+BAP) in M₉ medium was significantly enhanced 4 days after BR addition compared with a production control (−BR/+IAA/+BAP). In contrast, +BR/−IAA/−BAP vs. −BR/−IAA/−BAP was not as effective as +BR/+IAA/+BAP vs. −BR/+IAA/+BAP for the shikonin formation. The time course study for shikonin formation also showed that +BR/+IAA/+BAP and −BP/+IAA/+BAP only slightly increased cell growth in M₉ medium. Similarly, soluble protein content in the cells treated by BR at 0.01 ppb with IAA and BAP (+BR/+IAA/+BAP) exceeded that of the control (−BR/+IAA/+BAP) 4 days after BR addition. And +BR/−IAA/−BAP only slightly increased the soluble protein content over that of −BR/−IAA/−BAP. Received November 2, 1998; accepted August 25, 1999     

H2AX foci in late S/G2- and M-phase cells after hydroxyurea- and aphidicolin-induced DNA replication stress in Vicia

Immunocytochemistry using α-phospho-H2AX antibodies shows that hydroxyurea (HU), an inhibitor of ribonucleotide reductase, and aphidicolin (APH), an inhibitor of DNA-polymerases α and δ, may promote formation of phospho-H2AX foci in late S/G2-phase cells in root meristems of Vicia faba. Although fluorescent foci spread throughout the whole area of nucleoplasm, large phospho-H2AX aggregates in HU-treated cells allocate mainly in perinucleolar regions. A strong tendency of ATR/ATM-dependent phospho-Chk1^S317 kinase to focus in analogous compartments, as opposed to phospho-Chk2^T68 and to both effector kinases in APH-treated cells, may suggest that selected elements of the intra-S-phase cell cycle checkpoints share overlapping locations with DNA repair factors known to concentrate in phospho-H2AX aggregates. APH-induced phosphorylation of H2AX exhibits little or no overlap with the areas positioned close to nucleoli. Following G2-M transition of the HU- and APH-pretreated cells, altered chromatin structures are still discernible as large phospho-H2AX foci in the vicinity of chromosomes. Both in HU- and APH-treated roots, immunofluorescence analysis revealed a dominant fraction of small foci and a less frequent population of large phospho-H2AX agregates, similar to those observed in animal cells exposed to ionizing radiation. The extent of H2AX phosphorylation has been found considerably reduced in root meristem cells treated with HU and caffeine. The frequencies of phospho-H2AX foci observed during mitosis and caffeine-mediated premature chromosome condensation (PCC) suggest that there may be functional links between the checkpoint mechanisms that control genome integrity and those activities which operate throughout the unperturbed mitosis in plants.     

The lack of correlation between the rate of rRNA transport from nucleoli into cytoplasm and the duration of G1 and G2 phases in root meristem cells

In root meristems of 3 species (Secale cereale L., Vicia faba L. subsp. minor, Allium cepa L.) the durations of cell cycles and their phases were calculated using 3H-thymidine labelling. In the above species and in Helianthus annuus L. (parameters of the cell cycle determined earlier) the G1 and G2 phase durations were different: G1 + 1/2 M from 3 h to 6.1 h, G2 + 1/2 M from 1.1. h to 8.3 h, depending on the species. The rate of rRNA transport from nucleoli into cytoplasm during recovery after cold treatment was calculated from our data presented earlier. The results indicate that in 4 species studied there is no correlation (at P = 0.05) between the rate of rRNA transport and the duration of G1 and G2 phases.     

Paclitaxel Induces Primary and Postmitotic G1 Arrest in Human Arterial Smooth Muscle Cells

Paclitaxel (PTX), a microtubule-active drug, causes mitotic arrest leading to apoptosis in certain tumor cell lines. Here we investigated the effects of PTX on human arterial smooth muscle cell (SMC) cells. In SMC, PTX caused both (a) primary arrest in G1 and (b) post-mitotic arrest in G1. Post-mitotic cells were multinucleated (MN) with either 2C (near-diploid) or 4C (tetraploid) DNA content. At PTX concentrations above12 ng/ml, MN cells had 4C DNA content consistent with the lack of cytokinesis during abortive mitosis. Treatment with 6-12 ng/ml PTX yielded MN cells with 2C DNA content. Finally, 1-6 ng/ml of PTX, the lowest concentrations that affected cell proliferation, caused G1 arrest without multinucleation. It is important that PTX did not cause apoptosis in SMC. The absence of apoptosis could be explained by mitotic exit and G1 arrest as well as by low constitutive levels of caspase expression and by p53 and p21 induction. Thus, following transient mitotic arrest, SMC exit mitosis to form MN cells. These post-mitotic cells were subsequently arrested in G1 but maintained normal elongated morphology and were viable for at least 21 days. We conclude that in SMC PTX causes post-mitotic cell cycle arrest rather than cell death.     

The level of induced DNA double-strand breaks does not correlate with cell killing in X-irradiated mitotic and G1-phase CHO cells

The neutral (pH 9.6) filter elution technique was used to evaluate DNA damage induced in CHO cells irradiated at mitosis or in G1-phase under various incubation and postirradiation treatment conditions. Mitotic and G1/S border cells were more sensitive to radiation than G1 cells with respect to cell killing, but showed similar (G1/S) or lower (M) DNA elution dose--response curves. Similar cell survival and DNA/elution dose--response curves were obtained with plateau-phase cultures containing mainly G1-cells, as well as with G1 cells obtained after division of mitotic cells in either fresh or conditioned medium. However, survival of plateau-phase cells could be modified substantially by delayed-plating or postirradiation treatment with araA. These results, together with previously published observations, indicate that induction of DNA dsb cannot be invoked as an explanation for the variations in radiosensitivity observed through the cycle, or as an explanation for the formation of the survival curve shoulder. It is proposed that repair and fixation of radiation-induced DNA damage, expressed at the cell survival level as repair and fixation of alpha-PLD, are responsible for these effects.     

Regulation of Polo-like kinase 1 by DNA damage in mitosis. Inhibition of mitotic PLK-1 by protein phosphatase 2A

DNA damage triggers multiple checkpoint pathways to arrest cell cycle progression. Polo-like kinase 1 (Plk1) is an important regulator of several events during mitosis. In addition to Plk1 functions in cell cycle, Plk1 is involved in DNA damage check-point in G2 phase. Normally, ataxia telangiectasia-mutated kinase (ATM) is a key enzyme involved in G2 phase cell cycle arrest following DNA damage, and inhibition of Plk1 by DNA damage during G2 occurs in a ATM/ATR-dependent manner. However, it is still unclear how Plk1 is regulated in response to DNA damage in mitosis in which Plk1 is already activated. Here, we show that treatment of mitotic cells with doxorubicin and gamma-irradiation inhibits Plk1 activity through dephosphorylation of Plk1, and cells were arrested in G2 phase. Treatments of the phosphatase inhibitors and siRNA experiments suggested that PP2A pathway might be involved in regulating mitotic Plk1 activity in mitotic DNA damage. Finally, we propose a novel pathway, which is connected between ATM/ATR/Chk and protein phosphatase-Plk1 in DNA damage response in mitosis.