The cell cycle is the series of molecular events that allows cells to duplicate and segregate their chromosomes to form new cells. The finding that a protein kinase, the product of the yeastcdc2gene, was fundamental in the regulation of the G2/M and G1/S transitions, associated with unstable proteins named cyclins, opened a very exciting and dynamic research area. The number of gene products that participate in the development and regulation of the cell cycle may be in the hundreds, and there is a high degree of conservation in protein sequences and regulatory pathways among eukaryotes. Although there are clear differences between plants and animals in cell structure, organization, growth, development and differentiation, the same types of proteins and very similar regulatory pathways seem to exist. Seed germination appears to be an excellent model system for studying the cell cycle in plants. Imbibition will reactivate meristematic cells – most initially with a G1DNA content – into the cell cycle in preparation for seedling establishment. Early events include a thorough survey of DNA status, since the drying process and seed storage conditions reduce chromosomal integrity. The initiation of cell cycle events leading to G1and S phases, and of the germination process itself, may depend on a G1checkpoint control. Most, if not all, cell cycle proteins appear to be already present in unimbibed embryos, although there is evidence of protein turnover in the early hours, suggesting the need forde novoprotein synthesis. Regulation also may occur at the level of protein modification, because existing G1, S and G2cell cycle proteins appear to be activated at precise times during germination. Thus, cell cycle control during seed germination may be exerted at multiple levels; however, knowledge of cell cycle events and their importance for germination is still scarce and fragmentary, and different species may have developed unique control mechanisms, more suited to specific germination characteristics and habitat.
A cDNA corresponding to 16 kDa of the maize cyclin D2 N-terminus was cloned and this polypeptide was overexpressed to produce homologous antibodies. This antibody recognized a 38 kDa protein in extracts from maize embryonic axes which corresponds to the predicted size for cyclin D2 protein. Expression of cyclin D2 was followed at the transcriptional and protein levels, and the effect of cytokinins and abscisic acid (ABA) was followed during maize germination. Cytokinins importantly stimulated cyclin D2 gene expression at late germination times and sucrose was necessary for stimulation, whereas the effect of ABA was not different from that in controls. However, cyclin D2 protein levels in control axes reached a peak at 6 h germination, declining thereafter, and neither cytokinins nor ABA modified this behavior. Two cyclic-dependent kinase A (Cdk-A)-type proteins and proliferating cell nuclear antigen (PCNA) were found co-immunoprecipitating with cyclin D2, and these immunoprecipitates were able to phosphorylate both histone H1 and the maize retinoblastoma-related protein (RBR). This protein kinase activity differed from the pattern of protein accumulation during germination, and the activity was not modified by either cytokinins or ABA. We discuss these findings in terms of the importance of the cell cycle for the germination process.
Three different DNA polymerase activities can be resolved by passing a protein extract from 24 h imbibed maize axes through DEAE-cellulose. These activities have been numbered 1, 2 and 3, according to their elution order. One of them, DNA polymerase 2, elutes at 100-120 mM phosphates. This enzyme was further purified by passing it through Heparin-Sepharose, Sephacryl S-300 and DNA cellulose. Purification was nearly 5000-fold. The enzyme needs Mg2+, is stimulated by K+, has an optimum pH of 7.0 and its optimum temperature is 30-37 degrees C. Specific inhibitors for different types of polymerases, such as aphidicolin, dideoxythymidine triphosphate and N-ethyl maleimide, gave intermediate values of inhibition, making impossible the definition of the type of enzyme purified by its inhibitory pattern. SDS-PAGE indicated the presence of several bands of molecular masses of 28-40, 56 and 15 kDa. Most of these bands could be visualized when proteins from crude extracts were analyzed by western blot, using an antibody against calf thymus DNA polymerase alpha. A high molecular mass (around 500 kDa) was calculated by western blot of native gels using the same antibody. Finally, specific activity of this enzyme increased 100-fold during maize germination whereas polymerase 3 virtually did not increase. Furthermore, immunoprecipitation experiments with the antipolymerase alpha-antibody showed a decrease in DNA polymerase activity by 70%. The possibility that polymerase 2 is a replicative enzyme is discussed.
Cyclin proteins, associated to cyclin-dependent kinases (CDKs), play fundamental roles in cell cycle control as they constitute a very important driving force to allow cell cycle progression. D-type cyclins (CycDs) are important both for interpreting external mitogenic signals and in the control of the G1 phase. The maize (Zea mays) genome appears to contain at least 17 different CycD genes, and they fall into the subgroups previously described for other plants. Maize CycDs have been named according to identity percentages of the corresponding orthologs in rice and Arabidopsis. In silico analysis confirmed the presence of characteristic cyclin domains in each maize CycD gene and showed that their genomic organization is similar to their orthologs in rice and Arabidopsis. The expression of maize CycD genes was followed in seeds, during germination in the presence/absence of exogenously added hormones, and also in different plantlet tissues (mesocotyl, root tips and first leaf). Most cyclins were expressed in germinating seeds and at least in one of the plantlet tissues tested; almost all of the detected cyclins show an accumulating pattern of mRNA along germination (0-24 h) and higher levels in root tissue. Interestingly, some cyclins show high levels in non-proliferating tissues as leaf. Addition of auxins or cytokinins does not seem to importantly modify transcript levels; on the other hand, addition of abscisic acid repressed the expression of several cyclins. The role of each CycD during germination and plant growth and its interaction with other cell cycle proteins becomes a topic of the highest interest.
Differential response of PCNA and Cdk-A proteins and associated kinase activities to benzyladenine and abscisic acid during maize seed germination
The proliferating cell nuclear antigen (PCNA) is a protein factor required for processive DNA synthesis that is associated with G(1) cell cycle proteins. It has been demonstrated previously that, in germinating maize (Zea mays) embryonic axes, PCNA forms protein complexes with two Cdk-A proteins (32 and 36 kDa) and with a putative D-type cyclin. These complexes exhibit protein kinase activity on histone H1 and on the maize homologue of the pRB (retinoblastoma) protein. Flow cytometry has been used to study the influence of the phytohormones benzyladenine (BA) and abscisic acid (ABA) on cell cycle advancement during maize germination. It was found that, while BA accelerates the passage of cells from G(1) to G(2), ABA delays cell cycle events so that most cells seem to remain in G(1). The amounts of PCNA and Cdk-A proteins also vary according to the hormone treatment. In embryonic axes, PCNA increases rapidly during early germination in BA, compared with a gradual increase in water, while ABA treatment had only a marginal effect. However, of the two Cdk-A proteins, the 32 kDa protein is strongly reduced after 15 h of imbibition in water while this occurs later when axes are imbibed in BA or ABA. The PCNA-associated protein kinase activity in the BA and ABA treatments falls after 3 h of imbibition compared with activity in the control; however, while kinase activity in the BA treatment continues to decline during imbibition, it remains relatively constant until 24 h of imbibition in the ABA treatment. By contrast, a p13(Suc1)-associated Cdk-A kinase is activated after 15 h of imbibition under all treatments, particularly in ABA. These results suggest that, in maize, ABA delays the germination process by affecting cell cycle advancement, stopping cells mostly in a G(1) state.
The importance of cell proliferation in plant growth and development has been well documented. The majority of studies on basic cell cycle mechanisms in plants have been at the level of gene expression and much less knowledge has accumulated in terms of protein interactions and activation. Two key proteins, cyclins and cyclin-dependent kinases (CDKs) are fundamental for cell cycle regulation and advancement. Our aim has been to understand the role of D-type cyclins and type A and B CDKs in the cell cycle taking place during a developmental process such as maize seed germination. Results indicate that three maize D-type cyclins—D2;2, D4;2, and D5;3—(G1-S cyclins by definition) bind and activate two different types of CDK—A and B1;1—in a differential way during germination. Whereas CDKA–D-type cyclin complexes are more active at early germination times than at later times, it was surprising to observe that CDKB1;1, a supposedly G2-M kinase, bound in a differential way to all D-type cyclins tested during germination. Binding to cyclin D2;2 was detectable at all germination times, forming a complex with kinase activity, whereas binding to D4;2 and D5;3 was more variable; in particular, D5;3 was only detected at late germination times. Results are discussed in terms of cell cycle advancement and its importance for seed germination.
DNA replication is a late event during maize germination and DNA polymerase activity increases as germination proceeds. A replicative a-type DNA polymerase has been purified from maize seeds (DNA polymerase 2) and has been shown to be a multisubunit complex [Coello, P., Rodriguez, R., Garcia, E. Phosphate incorporated into the different polypeptides in the 11 -14-h period remained stable for at least the next 10 h (to 24 h of germination), the period of maximal enzyme activity. However, DNA polymerase 2 processivity was very similar in freshly prepared 3-h and 24-h enzymes, and no evidence was found that polymerase activity was modified by in vitro phosphorylation. The significance of these results is discussed.
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