Chemical inhibitors: a tool for plant cell cycle studies.

Synchrony provides a large number of cells at defined points of the cell cycle. Highly synchronised cells are powerful and effective tools for molecular analyses and for studying the biochemical events of the cell cycle in plants. Usually, plant cell suspensions can be synchronised by chemical agents, which arrest the cell cycle by acting on the driving forces of the cell cycle engine such as cyclin-dependent kinase activity, enzymes involved in DNA synthesis or proteolysis of cell cycle regulators or by acting on the cell cycle apparatus (mitotic spindle). The specificity, reversibility and efficiency of each type of cell cycle inhibitor are described and related to their mode of action.

An improved protocol for the preparation of protoplasts from an established Arabidopsis thaliana cell suspension culture and infection with RNA of turnip yellow mosaic tymovirus: a simple and reliable method.

An improved method for preparation of protoplasts of Arabidopsis thaliana cells grown in suspension culture is presented. This method is fast, reliable and can be used for the production of virtually an unlimited number of protoplasts at any time. These protoplasts can be transformed efficiently with RNA from turnip yellow mosaic tymovirus (TYMV) by polyethyleneglycol-mediated transfection. The simple transfection procedure has been optimized at various steps. Replication of TYMV can be monitored routinely by detection of the coat protein in as few as 2 x 10(4) infected protoplasts.

Is arcA3 a possible mediator in the signal transduction pathway during agonist cell cycle arrest by salicylic acid and UV irradiation?

Progression of BY-2 tobacco cells through the cell cycle was followed after treatments with ultra violet (UV) and salicylic acid (SA) used as a potent inhibitor of the octadecanoid pathway which can mediate response to UV irradiation. Cells in S phase were more sensitive than G0/G1 or G2 cells to UV irradiation. Although SA efficiently blocked cells in G0/G1 or G2, it did not block S phase synchronized cells. UV and SA applied simultaneously to cells in G0/G1 delayed the cell cycle progression more than each one separately. Therefore UV irradiation and SA act as agonists to arrest BY-2 cells at cell cycle entry. To further investigate the signalling pathway mediating UV response, we complemented a UV-sensitive Escherichia coli strain with a Nicotiana xanthi cDNA expression library. A cDNA (arcA3) whose coding sequence is identical to the 2,4-D induced arcA cDNA cloned by Ishida et al. (1993) was isolated. We show that arcA3 transcription is induced at cell cycle entry but not directly by the 2,4-D treatment. Moreover, arcA3 transcription is induced prior to the restriction point as shown with the CDK inhibitor roscovitine. The arcA3 transcription level is increased by UV irradiation but prevented by SA. Indeed, addition of SA prior to UV irradiation blocks the induction of arcA3 transcription. This suggests that arcA3 gene is modulated in both UV and SA responses, the SA effect preceding the UV step. Since arcA3 is 67% similar to RACK1 (functional homology), a rat intracellular receptor for protein kinase C, and possesses identical PKC fixation motifs, it is hypothesised that the arcA3 gene is involved in UV and SA cell cycle arrest.

Cell cycle regulation by plant growth regulators: involvement of auxin and cytokinin in the re-entry of Petunia protoplasts into the cell cycle.

In order to understand the mode of action of auxins and cytokinins in the induction of cell division, the effects of the two plant growth regulators 2,4-dichlorophenoxyacetic acid (2,4-D) and N6-benzyladenine (BA) were investigated using mesophyll protoplasts of Petunia hybrida, cultivated in either complete medium or in medium deficient in cytokinin, auxin or both. Firstly we studied DNA synthesis, using 5-bromodeoxyuridine/bisbenzimide Hoechst/propidium iodide flow cytometry analyses and by the monitoring of histone H4 transcript levels. Roscovitine, a cyclin-dependent kinase (CDK) inhibitor, was found to block the cell cycle prior to entry into the S and M phases in the cultured P. hybrida protoplasts. This suggests that in Petunia cell there is a requirement for CDK activity in order to complete the G1 and G2 phases. Further experiments using roscovitine showed that neither 2,4-D nor BA were individually able to induce cell cycle progression beyond the roscovitine G1 arrest. We also monitored the phytohormonal induction of S phase by studying variations in transcript levels of the gene for mitogenactivated protein kinase (PMEK1) and transcript levels of the cell division cycle gene cdc2Pet. Only 2,4-D, and not BA, was able to stimulate PMEK1 gene transcription; thus, the more rapid S-phase induction in 2,4-D-treated protoplasts may be attributable to the activation of this transduction pathway. In contrast, both plant growth regulators were required to induce the appearance of cdc2Pet mRNA transcripts prior to S-phase engagement.

Roscovitine, a novel cyclin-dependent kinase inhibitor, characterizes restriction point and G2/M transition in tobacco BY-2 cell suspension.

Although the developmental programs of plants and animals differ, key regulatory components of their cell cycle have been conserved. Particular attention has been paid to the role of the complexes between highly conserved cyclin and cyclin-dependent kinases in regulating progression through the cell cycle. The recent demonstration that roscovitine is a potent and selective inhibitor of the animal cyclin-dependent kinases cdc2 (CDK1), CDK2 and CDK5 prompted an investigation into its effects on progression through the plant cell cycle. Roscovitine induced arrests both in late G1 and late G2 phase in BY-2 tobacco cell suspensions. Both block were fully reversible when roscovitine was used at concentrations similar to those used in the animal system. Stationary-phase cells subcultured in the presence of roscovitine were arrested at a 2C DNA content. This arrest was more efficient without exogenous addition of plant growth regulator. Roscovitine induced a block in G1 earlier than that induced by aphidicolin. S-phase synchronized cells treated with roscovitine were arrested at a 4C DNA content at the G2/ M transition. The expression analysis of a mitotic cyclin (NTCYC1) indicated that the roscovitine-induced G2 block probably occurs in late G2. Finally, cells in metaphase were insensitive to roscovitine. The purified CDK/cyclin kinase activities of late G1 and early M arrested cells were inhibited in vitro by roscovitine. The implications of these experimental observations for the requirement for CDK activity during progression through the plant cell cycle are discussed.