G2 checkpoint targets late replicating DNA.

In the multinucleate cells induced in Allium cepa L. meristems, the nuclei surrounded by the largest cytoplasm environment complete replication earlier (advanced nuclei), but have a longer G2, than the others (delayed nuclei). Thus, all nuclei break down the nuclear envelope and start metaphase simultaneously. The present report shows that this synchronization relies on a checkpoint mechanism. When completion of replication was prevented in the delayed nuclei (due to in vivo 5-aminouracil feeding initiated when the advanced nuclei were already in G2), the metaphase was also further delayed in the advanced ones. In turn, some of the delayed nuclei overrode the G2 checkpoint (adaptation) and entered into mitosis with broken chromatids (Del Campo et al., 1997). Anoxic UVA (313 nm) irradiation apparently prevents the binding of regulatory proteins to Br-DNA. The present report shows that late replicating sequences are the targets of the checkpoint signal produced by the still replicating nuclei. This signal delays metaphase in the advanced nuclei, whose DNA is already fully replicated. Thus, when the already replicated sequences of late replicating DNA was modified in the advanced nuclei by bromosubstitution followed by anoxic UVA irradiation, they entered into mitosis without any delay, ignoring the inhibitory signals produced by the still replicating nuclei.

Synchronous nuclear-envelope breakdown and anaphase onset in plant multinucleate cells.

Multinucleate plant cells with genetically balanced nuclei can be generated by inhibiting cytokinesis in sequential telophases. These cells can be used to relate the effect of changes in the distribution of nuclei in the cytoplasm to the control of the timing of cell cycle transitions. Which mitotic cell cycle events are sensitive to differences in the amount of cytoplasm surrounding each chromosomal complement has not been determined. To address this, we maximized the cell size by transiently inhibiting replication, while cell growth was not affected. The nuclei of 93% of the elongated cells reached prophase asynchronously compared to 46% of normal-sized multinucleate cells. The asynchronous prophases of normal-sized cells became synchronous at the time of nuclear-envelope breakdown, and the ensuing metaphase plate formation and anaphase onset and progression occurred synchronously. The elongated multinucleate cells were also very efficient in synchronizing the prophases at nuclear-envelope breakdown, in the prophase-to-prometaphase transition. However, 2.4% of these cells broke down the nuclear envelope asynchronously, though they became synchronous at the metaphase-to-anaphase transition. The kinetochore-microtubular cycle, responsible for coordinating the metaphase-to-anaphase transition and for the rate of sister segregation to opposite spindle poles during anaphase, remained strictly controlled and synchronous in the different mitoses of a single cell, independently of differences in the amount of cytoplasm surrounding each mitosis or its ploidy. Moreover, the degree of chromosome condensation varied considerably within the different mitotic spindles, being higher in the mitoses with the largest surrounding cytoplasm.

Competence for assembly of sister chromatid cores is progressively acquired during S phase in mammalian cells.

Condensed sister chromatids possess a protein scaffold or axial core to which loops of chromatin are attached. The sister cores are believed to be dynamic frameworks that function in the organization and condensation of chromatids. Chromosome structural proteins are implicated in the establishment of sister chromatid cohesion and in the maintenance of epigenetic phenomena. Both processes of templating are tightly linked to DNA replication itself. It is a question whether the structural basis of sister chromatid cores is templated during S phase. As cells proceed through the cell cycle, chromatid cores undergo changes in their protein composition. Cytologically, cores are first visualized at the start of prometaphase. Still, core assembly can be induced in G1 and G2 when interphase cells are fused with mitotic cells. In this study, we asked if chromatid cores are similarly able to assemble in S-phase cells. We find that the ability to assemble cores is transiently lost during local replication, then regained in chromosome regions shortly after they have been replicated. We propose that core templating occurs coincident with DNA replication and that the competence for the assembly of the sister chromatid cores is acquired shortly after passage of replication forks.

Cell proliferation and cancer.

The discovery that phosphorylation of selected proteins by cyclin-dependent kinases is the engine which makes the cycle run provides a new image of the control of proliferation and of its deregulation. The high conservation of this machinery in the different eukaryotic organisms emphasizes its early origin and its importance for life. It also makes the extrapolation of findings between different species feasible. The control of proliferation relies basically on accelerating and braking mechanisms which act on the engine driving the cycle. This review particularly stresses the importance of checkpoint or tumor suppressor pathways as transduction systems of negative signals which may induce a cycle braking operation. They prevent any important cycle transition, as the initiation of proliferation, that of replication, mitosis, etc., until the DNA and other cellular conditions make such a progression safe. These checkpoint pathways are able to recognize and transduce signals about the adequacy of initiating or continuing proliferation for a cell at a particular time, under a particular set of external and internal conditions. Crucial components of these pathways are proteins encoded by some of the checkpoint genes that evaluate the final balance of mitogenic and antimitogenic pathways reaching them and, if the balance is negative, they prevent temporarily cycle inititation or its progression by inhibiting the corresponding cyclin-dependent kinases. On the other hand, when the balance becomes positive, they allow the activation of the cyclin-dependent kinases. Uncontrolled cell proliferation associated with cancer always depends on the functional abrogation of at least one of the checkpoint pathways. The checkpoint or tumor suppressor protein p53 is one of the proteins in them, and mutations in the gene encoding it are present in more than half of all human tumours. The review touches new pharmacological strategies which have been opened by the discovery of portions of some of the signal transduction cascades involved in the transient brake of cell proliferation. Restoration of checkpoint pathways either prevents further proliferation of cells with damaged genome until repair is over or, alternatively, the dismantling of these checkpoints induce those cells to commit suicide (apoptosis). The fact that both restoration and dismantling of checkpoint pathways sensitive to DNA damage have not disturbing effects on any other proliferating cell with undamaged DNA makes these selective strategies promissing.

The positional control of mitosis and cytokinesis in higher-plant cells.

The present work establishes a correlation between cell length and patterns of mitotic microtubular assemblies in Allium cepa L. root meristems. Binucleate cells were formed by a short caffeine treatment which aborted the formation of the phragmoplast during telophase. The largest binucleate cells (about 50 microns in length) behaved as two contiguous mononucleate cells in their next mitosis: they developed two preprophase bands (PPBs), one around each nucleus, where two spindles and two phragmoplasts were subsequently formed. On the other hand, the shortest binucleate cells (about 36 microns in length) formed a single PPB at the site of the aborted phragmoplast and, in the medium-sized cells (about 44 microns) in which the single PPB formed around the nucleus possessing the largest cytoplasmic environment, the two mitotic spindles and the new phragmoplasts moved to, or were assembled in the position of the phragmoplast that had been aborted one cycle earlier. Some rules derive from these observations. First of all, the aborted phragmoplast left a signal for microtubule positioning which was still operative one cycle later, in two-thirds of the bimitoses. Also, that formation of the PPB is dispensable. Moreover, its development does not always predict the future division plane, because of the presence of competing old signals which are stronger than those shed by the PPB in the same mitosis, but which fade away with distance. Finally, the positional signals were reinforced when the ratio of monomeric to fibrillar actin was increased by cytochalasin D during their shedding. When this drug was given simultaneously with caffeine, the frequency of bimitoses which, one cycle later, developed spindles and phragmoplasts in the positions of the old phragmoplast increased. On the other hand, those frequencies dropped in relation to control when the cytochalasin D treatment took place during bimitosis, indicating that at this time the treatment reinforced the signals produced in bimitosis itself.

Frailty of two cell cycle checkpoints which prevent entry into mitosis and progression through early mitotic stages in higher plant cells.

Allium cepa L. root meristems were given two short caffeine treatments spaced by 15 hours, the time which roughly corresponds to the duration of one cell cycle. In this way two subsequent cytokineses were prevented, and multinucleate cells with their in complement distributed into two, three or four nuclei were formed. Though all nuclei started to replicate synchronously in these cells, some of them (fast nuclei) completed their replication earlier than others (slow nuclei). The present report shows that two successive checkpoints operate before prometaphase in these cells. The first one prevents the entry of the fast nuclei into prophase until the slow ones have completed their replication. The second checkpoint ensures the synchronous entry into prometaphase after all nuclei have reached and finished prophase. By treating the multinucleate cells with an inhibitor of DNA synthesis at that time when fast but not slow nuclei had finished their replication, it was observed that both checkpoint mechanisms became leaky with time. Under these conditions the fast nuclei entered prophase in the presence of nuclei which were prevented from finishing the replication of their DNA. Subsequently, even prometaphase was triggered after a prolonged prophase. Finally, as expected from the presence of mitotic stages in these cells, nuclei with incompletely replicated DNA endured premature chromosome condensation. The prematurely condensed chromosomes either remained in a prometaphase-like stage until reconstitution nuclei formed or they followed the progression of the fast nuclei into metaphase and anaphase leading to the appearance of acentric chromosomal segments which after reconstitution gave rise to aneuploid nuclei containing unstable and broken DNA.

Competence for nuclear replication and the NOR-chromosomes of Allium cepa L.

Autotetraploid (4n = 32) cells were induced in Allium cepa L. root meristems by successively treating with a multipolarizing agent in anaphase (carbetamide) and an inhibitor of cell plate formation in telophase (caffeine). This treatment produced cells with their 32 chromosomes distributed in more than two nuclei. During G1, one of the nuclei in the resulting trinucleate cells had a DNA content which was equivalent to an average of 16 chromosomes, while the other 16 chromosomes were randomly distributed in two aneuploid nuclei. In the set of 16 chromosomes forming the onion diploid complement, there are 4 NOR-chromosomes and 5 chromosomes carrying DNA domains providing a nucleus with the competence to replicate, as previously shown. Expected probabilities derived from the different possible models for cosegregation of both kinds of chromosomes in the two aneuploid nuclei of the trinucleate cells were estimated by a computer simulation. These expected values were compared with the recorded frequencies of aneuploid nuclei which were able to organize a nucleolus and to respond to inducers of replication. The present data are compatible with the existence of sequences providing a nucleus with the competence to replicate in three out of the four NOR-bearing chromosomes, as well as in two other chromosomes of this diploid complement. The scarcity of chromosomes bearing early origins able to initiate replication in a nucleus is a striking feature of this huge onion genome.

The role of sister chromatid cohesiveness and structure in meiotic behaviour.

Sister chromatid cores, kinetochores and the connecting strand between sister kinetochores were differentially silver stained to analyse the behaviour of these structures during meiosis in normal and two spontaneous desynaptic individuals of Chorthippus jucundus (Orthoptera). In these desynaptic individuals most of the chromosomes appear as univalents and orient equationally in the first meiotic division. Despite this abnormal segregation pattern, the changes in chromosome structure follow the same timing as in normal individuals and seem to be strictly phase dependent. Chromosomes in the first prometaphase have associated sister kinetochores and sister chromatid cores that lie in the chromosome midline; we propose that this promotes the initial monopolar orientation of chromosomes. However, the requirements of tension for stable attachment to the spindle force the autosomal univalents to acquire amphitelic orientation. Sister kinetochores behave in a chromosome orientation-dependent manner and, in the first metaphase, they appear to be interconnected by a strand that can be detected by silver impregnation, as seen in the second metaphase of wild-type individuals. The disappearance of the sister kinetochore-connecting strand, needed for equational chromatid segregation, however, can only take place in the second meiotic division. This connecting strand is ultimately responsible for the inability of chromosomes to segregate sister chromatids in the first anaphase.

Nucleolar organizer expression in Allium cepa L. chromosomes.

Roots from Allium cepa L. (cv. Francesa) bulbs in which a maximum of two nucleoli per nucleus developed were selected for this study. Five rDNA clusters were detected by fluorescent in situ hybridization on chromosomal squashes (2n = 16) with a rhodamine-labelled wheat rDNA repeat. The rDNA clusters were located on four chromosomes: the largest cluster occurred on the small arm of a single homologue of the smallest pair 8. Its homologue showed two different small rDNA clusters, one near each telomere. The two homologues of the satellited chromosomes 6 also showed different rDNA contents, which were intermediate to those found in pair 8. The same five well-differentiated hybridization signals were observed in interphase cells that were inactive in transcription because they were in dormant roots, or in proliferating ones in which the synthesis of the large rRNA precursor was prevented. After multipolarizing agent was applied in anaphase followed by inhibition of cytokinesis, multinucleate autotetraploid cells were formed, which often contained more than four nucleoli. Thus, at least two of the three nucleolar organizer regions that consistently failed to develop a nucleolus in normal mononucleate cells were capable of developing nucleoli when segregated into different nuclei in multinucleate cells.

A limited number of chromosomes makes a nucleus competent to respond to inducers of replication and mitosis in a plant.

Multinucleate tetraploid cells with unbalanced chromosomal distribution in aneuploid nuclei were obtained in Allium cepa L. root meristems. For this, their natural diploid cells were treated with a multipolarizing agent (1 h carbetamide) followed by an inhibitor of cytokinesis (1 h caffeine). Data from these multinucleate cells with aneuploid nuclei suggest that only four out of the thirty-two chromosomes of their autotetraploid complement possess DNA sequences making the nucleus competent to respond to inducers of replication and mitosis. Direct observation of cells where a single replicated chromosome had reached mitosis showed that this chromosome was the one bearing the nucleolar organizer. Six specific chromosomes would confer competence to the nucleus to respond to inducers of replication but not to those producing chromosome condensation. Another four different chromosomes would confer the nucleus with the ability to respond to mitotic inducers but not to replication inducers. The rest of the chromosomal complement seemed to lack any of the DNA sequences needed for these two important cycle transitions. In a nutshell, certain DNA sequences distributed in a few chromosomes of the onion complement are an intranuclear requirement to initiate replication and mitosis in these plant cells.

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.

Regulation of cycle progression in plant cells.

Induction of polynucleate cells in onion root meristems by inhibition of two sequential cytokineses is used to study controls operating in cell cycle progression. Triggering of both replication and metaphase occurs synchronously in nuclei sharing a common cytoplasm, independent of their ploidy or intracellular position. The replication rate appears to be activated by the simultaneous intracytoplasm presence of other replicating nuclei. On the other hand, central position of a nucleus in the cell as well as increase in ploidy leads to slowing down of replication rate. The relative advance and lag of S period in the different nuclei in a common cytoplasm is partially counter-balanced by differential times of G2. Moreover prophase lengthening in the fast interphase nuclei points ot a negative control exerted by the lagging nuclei mediated by cytoplasm. Finally, it could be worth emphasizing similarities in the control mechanism operating in cycle progression both in animal and plant cells.