Adriana Silva Hemerly

cdc2a expression in Arabidopsis is linked with competence for cell division.

A key regulator of the cell cycle is a highly conserved protein kinase whose catalytic subunit, p34(cdc2), is encoded by the cdc2 gene. We studied the control of the expression of the Arabidopsis cdc2a gene in cell suspensions and during plant development. In cell cultures, arrest of the cell cycle did not significantly affect cdc2a mRNA levels, but nutrient conditions were important for cdc2a expression. During plant development, the pattern of cdc2a expression was strongly correlated with the cell proliferation potential. The effects of external signals on cdc2a expression were analyzed. Wounding induced expression in leaves. Lack of light altered temporal regulation of cdc2a in the apical but not root meristem of seedlings. Differential cdc2a responses were obtained after different hormone treatments. Signals present only in intact plants were necessary to mediate these responses. Although other control levels have yet to be analyzed, these results suggest that the regulation of cdc2a expression may contribute greatly to spatial and temporal regulation of cell division in plants. Our results also show that cdc2a expression is not always coupled with cell proliferation but always precedes it. We propose that cdc2a expression may reflect a state of competence to divide, and that the release of other controls is necessary for cell division to occur.

Dominant negative mutants of the Cdc2 kinase uncouple cell division from iterative plant development.

Because plant cells do not move and are surrounded by a rigid cell wall, cell division rates and patterns are believed to be directly responsible for generating new structures throughout development. To study the relationship between cell division and morphogenesis, transgenic tobacco and Arabidopsis plants were constructed expressing dominant mutations in a key regulator of the Arabidopsis cell cycle, the Cdc2a kinase. Plants constitutively overproducing the wild‐type Cdc2a or the mutant form predicted to accelerate the cell cycle did not exhibit a significantly altered development. In contrast, a mutation expected to arrest the cell cycle abolished cell division when expressed in Arabidopsis, whereas some tobacco plants constitutively producing this mutant protein were recovered. These plants had a reduced histone H1 kinase activity and contained considerably fewer cells. These cells were, however, much larger and underwent normal differentiation. Morphogenesis, histogenesis and developmental timing were unaffected. The results indicate that, in plants, the developmental controls defining shape can act independently from cell division rates.

Control of cell proliferation during plant development

Knowledge of the control of cell division in eukaryotes has increased tremendously in recent years. The isolation and characterization of the major players from a number of systems and the study of their interactions have led to a comprehensive understanding of how the different components of the cell cycle apparatus are brought together and assembled in a fine-tuned machinery. Many parts of this machine are highly conserved in organisms as evolutionary distant as yeast and animals. Some key regulators of cell division have also been identified in higher plants and have been shown to be functional homologues of the yeast or animal proteins. Although still in its early days, investigations into the regulation of these molecules have provided some clues on how cell division is coupled to plant development.

A CDC2 GENE OF PETUNIA-HYBRIDA IS DIFFERENTIALLY EXPRESSED IN LEAVES, PROTOPLASTS AND DURING VARIOUS CELL-CYCLE PHASES

Analysis of p34cdc2 kinase in higher eukaryotes has demonstrated that p34cdc2 function is conserved in all eukaryotic cells. The p34cdc2 kinase (the product of the cdc2 gene) is required during the G1 cell cycle phase at the initiation of DNA replication and also in G2-M phases for entry into mitosis. In this paper we report the isolation and characterization of a cdc2 Petunia hybrida PCR fragment (cdc2Pet). Using a DNA probe based on this fragment and a p34cdc2-specific antibody, cdc2Pet transcript and p34 protein levels were found to be constant both in 2C nuclei of highly proliferating mesophyll 2C cells derived from protoplasts and in 2C nuclei isolated directly from expanded petunia leaves.Both the cdc2Pet transcript and p34cdc2 protein levels were found to be higher in nuclei at 4C than in those at 2C, even when these 4C nuclei were from non-proliferating tissue. Thus cdc2Pet mRNA and protein levels measured in different tissues should not be interpreted to reflect exclusively the proliferative state of the tissue but also the frequency of G2 cells including those in the differentiated state.

The Molecular Basis of Cell Cycle Control in Arabidopsis thaliana

Cell division is an integral part of growth and development. Although the basic mechanisms of cell cycle control are apparently conserved in all eukaryotes examined until now, its fine regulation may differ according to the diverse developmental programs of each organism. Plants have several unique properties which distinguish their development from that of animals. Due to the absence of cell migration (plant cells are surrounded by a rigid cell wall) most cells in the embryo have to undergo morphogenesis in the correct position. Furthermore, most cell divisions are taking place in specialized regions, the meristems, which mostly continue to produce new organs throughout the entire plant’s life. Most non-dividing cells retain the potency to divide, allowing them to dedifferentiate and to produce, in suitable tissue culture conditions, new plants. The patterns of cell division are not only determined by intrinsic developmental programs, but they are also influenced by external factors such as light, wounding, gravity, etc. Plant hormones such as auxins and cytokinins, have outspoken effects on cell division and differentiation. The underlying mechanism is yet almost entirely unknown.

Cell cycle control in Arabidopsis thaliana

Summary The crucifer Arabidopsis thaliana is an excellent model plant to study the molecular regulation of cell division. Here, we describe the state of the art of cell cycle research in this organism. The expression of the key regulatory gene, cdc2, has been shown to be correlated with cell division and with the cellular competence to divide. Furthermore, plant hormones, such as auxins and cytokinins, have intriguing cell—specific effects on the expression of the cdc2 gene. The results are discussed in view of future developments.