The plant cell cycle

The first aim of this paper is to review recent progress in identifying genes in plants homologous to cell division cycle (cdc) genes of fission yeast. In the latter, cdc genes are well-characterised. Arguably, most is known about cdc2 which encodes a 34 kDa protein kinase (p34^cdc2) that functions at the G2-M and G1-S transition points of the cell cycle. At G2-M, the p34^cdc2 protein kinase is regulated by a number of gene products that function in independent regulatory pathways. The cdc2 kinase is switched on by a phosphatase encoded by cdc25, and switched off by a protein kinase encoded by weel. p34 Must also bind with a cyclin protein to form maturation promoting factor before exhibiting protein kinase activity. In plants, homologues to p34^cdc2 have been identified in pea, wheat, Arabidopsis, alfalfa, maize and Chlamydomonas. They all exhibit the PSTAIRE motif, an absolutely conserved amino acid sequence in all functional homologues sequenced so far. As in animals, some plant species contain more than one cdc2 protein kinase gene. but in contrast to animals where one functions at G2-M and the other (CDK2 in humans and Egl in Xenopus) at G1-S, it is still unclear whether there are functional differences between the plant p34^cdc2 protein kinases. Again, whereas in animals cyclins are well characterised on the basis of sequence analysis, into class A, class B (G2-M) and CLN (G1 cyclins), cyclins isolated from several plant species cannot be so clearly characterised. The differences between plant and animal homologues to p34^cdc2 and cyclins raises the possibility that some of the regulatory controls of the plant genes may be different from those of their animal counterparts. The second aim of the paper is to review how planes of cell division and cell size are regulated at the molecular level. We focus on reports showing that p34^cdc2 binds to the preprophase band (ppb) in late G2 of the cell cycle. The binding of p34^cdc2 to ppbs may be important in regulating changes in directional growth but, more importantly, there is a requirement to understand what controls the positioning of ppbs. Thus, we highlight work resolving proteins such as the microtubule associated proteins (MAPs) and those mitogen activated protein kinases (MAP kinases), which act on, or bind to, mitotic microtubules. Plant homologues to MAP kinases have been identified in alfalfa. Finally, some consideration is given to cell size at division and how alterations in cell size can alter plant development. Transgenic tobacco plants expressing the fission yeast gene, cdc25, exhibited various perturbations of development and a reduced cell size at division. Hence, cdc25 affected the cell cycle (and as a consequence, cell size at division) and cdc25 expression was correlated with various alterations to development including precocious flowering and altered floral morphogenesis. Our view is that the cell cycle is a growth cycle in which a cell achieves an optimal size for division and that this size control has an important bearing on differentiation and development. Understanding how cell size is controlled, and how plant cdc genes are regulated, will be essential keys to ‘the cell cycle locks’, which when ‘opened’, will provide further clues about how the cell cycle is linked to plant development.     

Cdc2-kinases,cyclins, and the switch from proliferation to polyploidization

Summary Almost all organisms, from protists to humans, and from algae to orchids, display somatic polyploidy, including polyteny. In insects and higher plants, nearly all normal, differentiated cells are polyploid, corresponding to the majority of living matter. So far, no universal mechanism controlling the switch from proliferation to polyploidization has been proposed. However, recent progress in understanding regulation of the mitotic cell cycle by protein kinases and cyclins allows some unifying ideas which can be experimentally tested to be put forward. The key events are the abolishment of the dependence of DNA replication on mitosis, and changes in the expression and activity of the complexes formed by cyclin-dependent kinases and cyclins. In addition, repression of further cell cycle control genes may allow underreplication of DNA, characteristic of endo-cycles in many insects and angiosperms. Change to a different checkpoint may be responsible for gene amplification. The switch in cell cycle control is developmentally regulated by signal transduction cascades, which are briefly discussed. Polyploidy is also known from many cancers, where genetic and metabolic disturbances lead to a similar switch to that in normal cells. The related literature is reviewed and some possible lines of future research are suggested.Abbreviations CAK p34^cdc2-activating kinase - cdc2 cell division cycle gene inSchizosaccharomyces pombe (fission yeast), named cdk1 in mammals - CDKs cyclin-dependent kinases - cdk2 S-phase specific CDK gene in higher organisms - MAP kinase mitogen-activated protein kinase - MAPs microtubule-associated proteins - MPF maturation (or mitosis) promoting factor - p34^cdc2 mitosis specific protein kinase     

Expression of a dominant negative allele of cdc2 prevents activation of the endogenous p34cdc2 kinase

Summary The cdc2 gene of the fission yeast Schizosaccharomyces pombe encodes a 34 kDa phosphoprotein with serine/threonine protein kinase activity that acts as the key component in regulation of the eukaryotic cell cycle. We used a repressible promoter fused to the cdc2 cDNA to isolate conditionally dominant negative mutants of cdc2. One of these mutants, DL5, is described in this paper. Overexpression of the mutant protein in a wild-type cdc2 background is lethal and confers cell cycle arrest with a typical cdc phenotype. Sequencing of the mutant cdc2 gene revealed a single amino acid substitution in a region highly conserved in cdc2-like proteins. The mutant protein exhibits no protein kinase activity, but is able to bind a component(s) required for an active protein kinase complex and thereby prevents binding of this component(s) to the co-existing wild-type cdc2 protein. We also demonstrate that S. pombe p34^cdc2 contains no phosphoserine.     

Molecular cloning and sequence analysis of mutant alleles of the fission yeast cdc2 protein kinase gene: Implications for cdc2+ protein structure and function

Summary The cdc2 ⁺ gene function plays a central role in the control of the mitotic cell cycle of the fission yeast Schizosaccharomyces pombe. Recessive temperature-sensitive mutations in the cdc2 gene cause cell cycle arrest when shifted to the restrictive temperature, while a second class of mutations within the cdc2 gene causes a premature advancement into mitosis. Previously the cdc2 ⁺ gene has been cloned and has been shown to encode a 34 kDa phosphoprotein with in vitro protein kinase activity. Here we describe the cloning of 11 mutant alleles of the cdc2 gene using two simple methods, one of which is presented here for the first time. We have sequenced these alleles and find a variety of single amino acid substitutions mapping throughtout the cdc2 protein. Analysis of these mutations has identified a number of regions within the cdc2 protein that are important for cdc2 ⁺ activity and regulation. These include regions which may be involved in the interaction of the cdc2 ⁺ gene product with the proteins encoded by the wee1 ⁺, cdc13 ⁺ and suc1 ⁺ genes.     

Cytokinin controls the cell cycle at mitosis by stimulating the tyrosine dephosphorylation and activation of p34cdc2-like H1 histone kinase

In excised pith parenchyma from Nicotiana tabacum L. cv. Wisconsin Havana 38, auxin (naphthalene-1-acetic acid) together with cytokinin (6-benzylaminopurine) induced a greater than 40-fold increase in a p34^cdc2-like protein, recoverable in the p13^suc1-binding fraction, that had high H1 histone kinase activity, but enzyme induced without cytokinin was inactive. In suspension-cultured N. plumbaginifolia Viv., cytokinin (kinetin) was stringently required only in late G2 phase of the cell division cycle (cdc) and cells lacking kinetin arrested in G2 phase with inactive p34^cdc2-like H1 histone kinase. Control of the Cdc2 kinase by inhibitory tyrosine phosphorylation was indicated by high phosphotyrosine in the inactive enzyme of arrested pith and suspension cells. Yeast cdc25 phosphatase, which is specific for removal of phosphate from tyrosine at the active site of p34^cdc2 enzyme, was expressed in bacteria and caused extensive in-vitro activation of p13^suc1-purified enzyme from pith and suspension cells cultured without cytokinin. Cytokinin stimulated the removal of phosphate, activation of the enzyme and rapid synchronous entry into mitosis. Therefore, plants can control cell division by tyrosine phosphorylation of Cdc2 but differ from somatic animal cells in coupling this mitotic control to hormonal signals.Abbreviations BAP 6-benzylaminopurine - BrdUrd 5-bromo-2-deoxyuridine - cdc cell division cycle - Cdc25 cdc phospho-protein phosphatase - CKI cyclin dependent kinase inhibitor - 2,4-D 2,4-dichlorophenoxyacetic acid - DAPI 4,6 diamidino-2-phenylindole - GST-cdc25 glutathione sulfur transferase-truncated cdc25 fusion - MS Murashige and Skoog (1962) - NAA naphthalene-1-acetic acid - p34^cdc2 34-kDa product of the cdc2 gene     

The function of the chicken p34CDC2 protein kinase in fission yeast is cold sensitive for cell cycle progression through the G1 phase and temperature sensitive for traversal of mitosis.

The protein kinase p34^cdc2 is required at the onset of DNA replication and for entry into mitosis. The catalytic subunit and its regulatory proteins, notably the cyclins, are conserved from yeast to man. This suggests that the control mechanisms necessary for progression through the cell cycle in fission yeast are conserved throughout evolution. This work describes the characterization of a fission yeast strain that is dependent for cell cycle progression on the activity of the p34^CDC2 protein kinase from chicken. The response of the chicken p34^CDC2 protein kinase to cell cycle components of fission yeast was examined. Cells expressing the chicken p34^CDC2 protein divide at reduced size at 31° C. Cells are temperature sensitive at 35.5° C and die as a result of mitotic catastrophe. This phenotype can be rescued by delaying cell cycle progression at the G1-S transition by adding low concentrations of hydroxyurea. Schizosaccharomyces pombe cells that are dependent on chicken p34^CDC2 are cold sensitive. At 19° C to 25° C cells arrest in the G1 phase, while traversal of the G2-M transition is not blocked at low temperature. Expression of chicken p34^CDC2 in the cold-sensitive G2-M mutant cdc2A21 suppresses the G1 arrest. Received: 14 October 1998 / Accepted: 15 March 1999     

Phorbol Ester TPA Rapidly Prevents Activation of p34 Histone H1 Kinase and Concomitantly the Transition from G2 Phase to Mitosis in Synchronized HeLa Cells

HeLa cells in G2 phase are temporarily inhibited and prevented from entering mitosis by treatment with the phorbol ester TPA (12-O-tetradecanoylphorbol-13-acetate), whereas cells in mitosis are refractory to TPA and divide. In this study the possibility was tested that TPA may interfere with the regulatory cycle of MPF (mitosis promoting factor), the rate-limiting protein kinase for cell division. MPF, consisting of the catalytic subunit p34^cdc2 and the regulatory subunit Cyclin B, is known to be activated at the transition from G2 phase to mitosis through dephosphorylation at Tyr¹⁵ and to become inactivated after metaphase by proteolysis. Treatment of HeLa cells (synchronized around the G2-M transition) with TPA (10^-7M) has now been shown to induce an overall decrease of the histone H1 kinase activity associated with anti-p34^cdc2 immunoprecipitates after about 20 to 30 min. In metaphase cells, the histone H1 kinase activity of p34^cdc2 was shown to remain unaffected by TPA treatment. In cultures enriched in G2 cells neither the amount of p34^cdc2 protein nor that of Cyclin B was influenced by TPA. Moreover, the p34^cdc2/Cyclin B complex formation was also unaffected. However, p34^cdc2 from cultures treated with TPA was more intensely stained by anti-phosphotyrosine antibodies than that of control cells, indicating that TPA treatment probably prevented the tyrosine dephosphorylation required for expression of the histone H1 kinase activity of the complex. The results indicate that TPA treatment of HeLa cultures rapidly stops the G2-M transition because it very rapidly prevents the p34^cdc2/Cyclin B complex in G2 cells from developing histone H1 kinase activity.     

Identification of CDK- and cyclin-like proteins in the eye of Bulla gouldiana

The ocular circadian rhythm in the eye of Bulla gouldiana is generated by a rhythm in membrane potential of retinal neurons that is driven by alterations in potassium conductance. Since potassium conductance may be modulated by the phosphorylation of potassium channels, the circadian rhythm may reflect rhythmic changes in protein kinase activity. Furthermore, the circadian rhythm recorded from the Bulla eye can be phase shifted by agents that affect protein synthesis and protein phosphorylation on tyrosine residues. Interestingly, the eukaryotic cell division residues. Interestingly, the eukaryotic cell division cycle is generated by similar processes. Rhythmic cell division is regulated by periodic synthesis and degradation of a protein, cyclin, and periodic tyrosine phosphorylation of a cyclin-dependent kinase (cdk), p34^cdc2. The interaction between these two proteins results in rhythmic kinase activity of p34^cdc2. Both cyclin and p34^cdc2 are pat of two diverse gene families, some of whose members have been localized to postmitotic cell types with no function yet determined. In the current work, we identify proteins similar to the cdks and cyclin in the eye of Bulla. Neither of these ocular proteins are found in mitotic cells in Bulla, and the cdk-like protein (p40) is specific to the eye. Furthermore, the concentration of the cyclin-like protein (p66) is affected by treatments that phase shift the circadain rhythm. The identification of cdk and cyclin-like proteins in the Bulla eye is consistent with the hypothesis that the biochemical mechanism responsible for generating the ocular circadian rhythm in Bulla is related to the biochemical mechnism that regulates the eukaryotic cell division cycle. 1994 John Wiley & Sons, Inc.     

p 34cdc2 kinase homologue in the preprophase band

Summary Immunofluorescence microscopy with a monoclonal antibody raised against the PSTAIR sequence, which corresponds to a peptide conserved in the p 34^cdc2 protein kinase throughout the phylogenetic scale including higher plants, was used to study the intracellular localization of p 34^cdc2 during the cell cycle in onion root tip cells. Although p 34^cdc2 was evenly distributed in the cytoplasm throughout the cell cycle, a more intense staining was observed in the cortical region, where the preprophase band of microtubules (MTs) was located. Double staining with the PSTAIR and plant tubulin antibodies showed that the width of p 34^cdc2 band was narrower than that of MT band. These data raise the interesting question regarding the possible role of p 34^cdc2 protein kinase in determining the division site in plant cells.     

Mutational analysis of the fission yeast p34cdc2 protein kinase gene

Summary The p34^cdc2 protein serine-threonine kinase plays an essential role in the life cycle of fission yeast, being required for both the G1-S and G2-M transitions during mitotic growth, and also for the second meiotic nuclear division. Functional homologues of p34^cdc2 (each ca. 60 % identical to the fission yeast prototype) have been isolated from organisms as diverse as humans, insects and plants, and there is now considerable evidence supporting the view that fundamental aspects of the cell cycle controls uncovered in fission yeast will prove to be conserved in all eukaryotes. By comparing the amino acid sequences of fission yeast p34^cdc2 with its higher eukaryotic counterparts it is possible to identify conserved residues that are likely to be centrally important for p34^cdc2 function. Here the effects are described of mutating a number of these conserved residues. Twenty-three new mutant alleles have been constructed and tested. We show that replacing cysteine 67 with trypthophan renders the resulting mutant protein p80^cdc25-independent (while neither leucine, isoleucine nor valine has this effect) and that several of the amino acids within the highly conserved PSTAIRE region are not absolutely required for p34^cdc2 function. Five acidic amino acids have also been mutated within p34^cdc2, which are invariant across the eukaryotic protein kinase family. Acid-to-base mutations at three of these residues resulted in a dominant-negative, cell cycle arrest phenotype while similar mutations at the other two simply abolished p34^cdc2 protein function. The results are discussed with reference to the predicted tertiary structure of the p34^cdc2 enzyme.     

A phosphorylation site mutant of Schizosaccharomyces pombe cdc2p fails to promote the metaphase to anaphase transition

The protein kinase cdc2p is a key regulator of the G1-S and G2-M cell cycle transitions in the yeast Schizosaccharomyces pombe. Activation of cdc2p is regulated by its phosphorylation state and by interaction with other proteins. We have analyzed the consequences for cell cycle progression of altering the conserved threonine phosphorylation site, within the activation loop of cdc2p, to glutamic acid. This mutant, T167 E, promotes entry into mitosis, as judged by the accumulation of mitotic spindles and condensed chromosomes, despite the fact that it lacks demonstrable kinase activity both in vitro and in vivo. However, T167 E cannot promote the metaphase-anaphase transition. Since a component of the anaphase-promoting complex (APC) in S. pombe, cut9p, remains hypophosphorylated at the T167 E arrest point, the cell cycle block might be due to the inability of T167 E to activate the APC. T167 E is lethal when overexpressed, and overproduction also causes a mitotic arrest. Multicopy suppressors of the dominant negative phenotype were isolated, and identified as cdc13 ⁺ and suc1 ⁺ . Overexpression of suc1 ⁺ suppresses the effects of T167 E overproduction by restoring sufficient amounts of suc1p to the cell to allow passage through mitosis. Received: 3 April 1998 / Accepted: 23 May 1998     

Genetic analysis of human p34CDC2 function in fission yeast

The p34^cdc2 protein kinase plays a key role in the control of the mitotic cell cycle of fission yeast, being required for both entry into S-phase and for entry into mitosis in the mitotic cell cycle, as well as for the initiation of the second meiotic nuclear division. In recent years, structural and functional homologues of p34^cdc2, as well as several of the proteins that interact with and regulate p34^cdc2 function in fission yeast, have been identified in a wide range of higher eukaryotic cell types, suggesting that the control mechanisms uncovered in this simple eukaryote are likely to be well conserved across evolution. Here we describe the construction and characterisation of a fission yeast strain in which the endogenous p34^cdc2 protein is entirely absent and is replaced by its human functional homologue p34^CDC2, We have used this strain to analyse aspects of the function of the human p34^CDC2 protein genetically. We show that the function of the human p34^CDC2 protein in fission yeast cells is dependent upon the action of the protein tyrosine phosphatase p80^cdc25 that it responds to altered levels of both the mitotic inhibitor p107²³³¹ and the p34^cdc2-binding protein p13^suc1, and is lethal in combination with the mutant B-type cyclin p56^cdc13-117. In addition, we demonstrate that the human p34^CDC2 protein is proficient for fission yeast meiosis, and examine the behaviour of two mutant p34^CDC2 proteins in fission yeast.     

Cyclin B (p56cdc13) localization in the yeast Schizosaccharomyces pombe: An ultrastructural and immunocytochemical study

Summary— The eucaryote cell cycle is driven by a set of cyclin dependent kinases (CDKs) associated to cyclins, which confer not only the activity but also the substrate specificity and the proper localization of the kinase activity. In the fission yeast Schizosaccharomyces pombe, only one cyclin, the product of the cdc13 gene (p56^cdc13), is required to be associated with p34^cdc2, to control the complete cell cycle. Earlier studies have localized this complex mainly in the nucleus and its periphery. Using new improved electron microscopy (EM) technologies, based on high pressure freezing fixation, we refined previous studies, evidencing cytoplasmic localization of p56^cdc13, in addition to the nuclear localization previously observed. Further immunofluorescence studies, performed on aldehydically fixed cells, confirmed our EM results, emphasizing the major cytoplasmic localization of p56^cdc13 in interphase cells and the relocalization towards the nucleus in mitotic cells, suggesting that the S pombe cyclin B localization is cell cycle-regulated.     

Regulation of maturation-promoting factor by protein kinase C in Chaetopterus oocytes

Summary

We present the results of a variety of studies showing that activation of protein kinase C (PKC) in oocytes of Chaetopterus pergamentaceus results in germinal vesicle breakdown (GVBD). Phorbol esters and diacylglycerol can initiate a morphologically normal GVBD accompanied by a spectrum of associated biochemical processes, including increased protein phosphorylation, a shift in protein synthesis and activation of a protein kinase, maturation promoting factor (MPF). MPF activation is essential for GVBD in response to phorbol esters. In addition, inhibitors of PKC can block naturally-induced GVBD. We also present evidence that PKC can phosphorylate p34^cde2, the catalytic subunit of MPF and that phosphorylation by PKC increases the histone H1 kinase activity of immunoprecipitated MPF. Immunoblot studies show that Chaetopterus oocyte p34^cdc2 is not tyrosine phosphorylated prior to the initiation of GVBD, indicating that activation of MPF at GVBD in this species does not require p80^cdc25, the activator of MPF at mitosis. These results suggest that PKC is an essential regulator of GVBD which can directly phosphorylate and regulate p34^cdc2. Since PKC is the intracellular receptor for and is directly activated by tumor-promoters, tumor promotion might involve acceleration of the cell cycle through modification of the enzymatic activity of MPF by PKC.     

Genetic analysis of human p34CDC2 function in fission yeast

The p34^cdc2 protein kinase plays a key role in the control of the mitotic cell cycle of fission yeast, being required for both entry into S-phase and for entry into mitosis in the mitotic cell cycle, as well as for the initiation of the second meiotic nuclear division. In recent years, structural and functional homologues of p34^cdc2, as well as several of the proteins that interact with and regulate p34^cdc2 function in fission yeast, have been identified in a wide range of higher eukaryotic cell types, suggesting that the control mechanisms uncovered in this simple eukaryote are likely to be well conserved across evolution. Here we describe the construction and characterisation of a fission yeast strain in which the endogenous p34^cdc2 protein is entirely absent and is replaced by its human functional homologue p34^CDC2, We have used this strain to analyse aspects of the function of the human p34^CDC2 protein genetically. We show that the function of the human p34^CDC2 protein in fission yeast cells is dependent upon the action of the protein tyrosine phosphatase p80^cdc25 that it responds to altered levels of both the mitotic inhibitor p107²³³¹ and the p34^cdc2-binding protein p13^suc1, and is lethal in combination with the mutant B-type cyclin p56^cdc13-117. In addition, we demonstrate that the human p34^CDC2 protein is proficient for fission yeast meiosis, and examine the behaviour of two mutant p34^CDC2 proteins in fission yeast.     

Ectopic Expression of cdc2/cdc28 Kinase Subunit Homo sapiens 1 Uncouples Cyclin B Metabolism from the Mitotic Spindle Cell Cycle Checkpoint

Primary human fibroblasts arrest growth in response to the inhibition of mitosis by mitotic spindle-depolymerizing drugs. We show that the mechanism of mitotic arrest is transient and implicates a decrease in the expression of cdc2/cdc28 kinase subunit Homo sapiens 1 (CKsHs1) and a delay in the metabolism of cyclin B. Primary human fibroblasts infected with a retroviral vector that drives the expression of a mutant p53 protein failed to downregulate CKsHs1 expression, degraded cyclin B despite the absence of chromosomal segregation, and underwent DNA endoreduplication. In addition, ectopic expression of CKsHs1 interfered with the control of cyclin B metabolism by the mitotic spindle cell cycle checkpoint and resulted in a higher tendency to undergo DNA endoreduplication. These results demonstrate that an altered regulation of CKsHs1 and cyclin B in cells that carry mutant p53 undermines the mitotic spindle cell cycle checkpoint and facilitates the development of aneuploidy. These data may contribute to the understanding of the origin of heteroploidy in mutant p53 cells.     

Cloning and characterization of a cdc25 phosphatase from mouse lymphocytes

Members of the cdc25 phosphatase family are proposed to function as important regulators of the eukaryotic cell cycle, particularly in the induction of mitotic events. A new cdc25 tyrosine phosphatase, cdc25M1, has been cloned from a mouse pre-B cell cDNA library and characterized. The cdc25M1 protein consists of 465 amino acids with a predicted relative molecular mass (M_r) of 51 750. Over the highly conserved carboxyl terminal region, the amino acid sequence similarity to the human cdc25 C or Hs1 isoform is 89%, while the overall similarity is 67%. The phosphatase active site is located within residues 367–374. Tissue expression of the cdc25M1 was highest in mouse spleen and thymus by northern blot analysis. The cdc25M1 mRNA was detected in a number of cloned mouse lymphocyte cell lines including both CD8⁺ and CD4⁺ cells. cdc25M1 mRNA was shown to be cell cycle-regulated in T cells following interleukin-2 (IL-2)-stimulation. Accumulation of cdc25M1 mRNA occured at 48 h after IL-2 stimulation, when lymphocytes were progressing from S phase to G₂/M phase of the cell cycle. This pattern of expression is in contrast to that observed for other protein tyrosine phosphatases expressed in T lymphocytes including CD45, LRP, SHP, and PEP. The elevation in cdc25M1 mRNA level occurred concomittant to the appearance of the hyperphosphorylated form of p34^cdc2 protein kinase. A purified, bacterial-expressed recombinant cdc25M1 phosphatase domain catalyzed the dephosphorylation of p-nitrophenol phosphate, as well as [³²P-Tyr] and [³²P-Ser/Thr]-containing substrates. Preincubation of p34^cdc2 kinase with cdc25M1 activated its histone H1 kinase activity in vitro. These results suggest that cdc25M1 may be involved in regulating the proliferation of mouse T lymphocytes following cytokine stimulation, through its action on p34^cdc2 kinase.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number L16926.     

Isolation and characterization of cDNA clones encoding cdc2 homologues from Oryza sativa: a functional homologue and cognate variants.

Summary Using probes obtained by PCR amplification, we have isolated two cognate rice cDNAs (cdc2Os-1 andcdc2Os-2) encoding structural homologues of thecdc2 ⁺/CDC28(cdc2) protein kinase from a cDNA library prepared from cultured rice cells. Comparison of the deduced amino acid sequences of cdc2Os-1 and cdc2Os-2 showed that they are 83 % identical. They are 62 % identical toCDC28 ofSaccharomyces cerevisiae and much more similar to the yeast and mammalian p34^cdc2 kinases than to riceR2, acdc2-related kinase isolated previously by screening the same rice cDNA library with a different oligonucleotide probe. Southern blot analysis indicated that the three rice clones (cdc2Os-1,cdc2Os-2 andR2) are derived from distinct genes and are each found in a single copy per rice haploid genome. RNA blot analysis revealed that these genes are expressed in proliferating rice cells and in young rice seedlings.cdc2Os-1 could complement a temperature-sensitive yeast mutant ofcdc28. However, despite the similarity in structure, bothcdc2Os-2 andR2 were unable to complement the same mutant. Thus, the present results demonstrate the presence of structurally related, but functionally distinct cognates of thecdc2 cell cycle kinase in rice.The nucleotide sequence data in this paper have been deposited in the EMBL database under accession number X60374 (cdc2Os-1) and X60375 (cdc2Os-2)