Functional Characterization of Dma1 and Dma2, the Budding Yeast Homologues of Schizosaccharomyces pombe Dma1 and Human Chfr

Roberta Fraschini, Denis Bilotta, Giovanna Lucchini, and Simonetta Piatti^*

Dipartimento di Biotecnologie e Bioscienze, Piazza della Scienza 2, 20126 Milan, Italy

Submitted February 4, 2004; Accepted May 5, 2004
Monitoring Editor: Tim Stearns

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Proper transmission of genetic information requires correctassembly and positioning of the mitotic spindle, responsiblefor driving each set of sister chromatids to the two daughtercells, followed by cytokinesis. In case of altered spindle orientation,the spindle position checkpoint inhibits Tem1-dependent activationof the mitotic exit network (MEN), thus delaying mitotic exitand cytokinesis until errors are corrected. We report a functionalanalysis of two previously uncharacterized budding yeast proteins,Dma1 and Dma2, 58% identical to each other and homologous tohuman Chfr and Schizosaccharomyces pombe Dma1, both of whichhave been previously implicated in mitotic checkpoints. We showthat Dma1 and Dma2 are involved in proper spindle positioning,likely regulating septin ring deposition at the bud neck. DMA2overexpression causes defects in septin ring disassembly atthe end of mitosis and in cytokinesis. The latter defects canbe rescued by either eliminating the spindle position checkpointprotein Bub2 or overproducing its target, Tem1, both leadingto MEN hyperactivation. In addition, dma1 ${Delta}$ dma2 ${Delta}$ cells fail toactivate the spindle position checkpoint in response to thelack of dynein, whereas ectopic expression of DMA2 preventsunscheduled mitotic exit of spindle checkpoint mutants treatedwith microtubule-depolymerizing drugs. Although their primaryfunctions remain to be defined, our data suggest that Dma1 andDma2 might be required to ensure timely MEN activation in telophase.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Faithful chromosome segregation requires the mitotic spindleto be correctly positioned with respect to the cell divisionaxis. Cytokinesis must take place only after this task is achievedand the two sets of chromosomes are sufficiently far apart.Unscheduled cytokinesis before proper chromosome segregationwould, in fact, lead to formation of anucleate and polyploidcells. Eukaryotic cells prevent these harmful events by a surveillancemechanism, called spindle position checkpoint, that delays cytokinesisin the presence of mispositioned or misoriented spindles untilerrors are corrected. This control is particularly criticalfor organisms, such yeasts and higher plants, that specify thesite of cytokinesis before spindle assembly.

In the budding yeast Saccharomyces cerevisiae, the mitotic spindlefirst gets positioned close to the bud neck, the constrictionwhere cytokinesis will take place later on, and then crossesthe neck to enter the bud, dragging the nucleus along. Spindlepositioning and orientation involve a search- and-capture processand occur in two steps, which depend on two partially overlappingpathways (Schuyler and Pellman, 2001). During the first stepcytoplasmic microtubules (cMTs) try to find and interact withspecific sites on the bud neck cortex. The EB1/Bim1 protein,localized at the plus end of cMTs, is directly involved in searchingcortical sites by promoting cMTs dynamicity (Tirnauer et al.,1999). Nuclear positioning also requires the cortical proteinKar9, with which Bim1 interacts (Miller and Rose, 1998; Korineket al., 2000; Lee et al., 2000); the septin ring, which alsospecifies the site for cytokinesis (Kusch et al., 2002); thekinesin Kip3 (Cottingham and Hoyt, 1997; DeZwaan et al., 1997);and other proteins required for Kar9 localization, such as actin(Cottingham et al., 1999), the formin Bni1 (Lee et al., 1999),and myosin V (Beach et al., 2000; Yin et al., 2000). Duringthe second step, dynein (Dyn1) and its regulators dynactin andPacI mediate lateral interactions between cMTs and the corticalprotein Num1, thus helping the nucleus to be pulled inside thebud (Adames and Cooper, 2000; Heil-Chapdelaine et al., 2000;Lee et al., 2003; Sheeman et al., 2003).

The spindle position checkpoint is well characterized in S.cerevisiae and requires the Bub2 and Bfa1 proteins (Bardin etal., 2000; Bloecher et al., 2000; Pereira et al., 2000), whichform a two-component GTPase-activating protein inhibiting theG protein Tem1 (Geymonat et al., 2002), which is in turn requiredto activate the mitotic exit network (MEN) in telophase (Simanis,2003). Tem1-dependent activation of the MEN leads to the releasefrom the nucleolus of the Cdc14 protein phosphatase, which iscrucial to promote inactivation of cyclinB-dependent CDKs atthe end of mitosis (Visintin et al., 1998). Inhibition of suchCDKs is an essential prerequisite for spindle disassembly andcytokinesis at the end of the cell cycle and is obtained inbudding yeast by both anaphase promoting complex (APC)-mediatedproteolysis of their cyclin subunits and accumulation of theCDK inhibitor Sic1 (Zachariae and Nasmyth, 1999). In additionto its role in MEN activation, however, Tem1 also has been implicatedin a MEN-independent cytokinetic process, leading to septinring splitting into an hourglass-shaped structure (Lippincottet al., 2001). The MEN has a similar structural organizationto fission yeast septation initiation network (SIN), which isrequired for cytokinesis but not for mitotic exit (Simanis,2003). Unlike budding yeast Bub2, its fission yeast homologueCdc16 performs an essential cell cycle function, and its inactivationleads to unscheduled formation of septa, generating multinucleatecells. In addition, Cdc16, like Bub2, is involved in the spindlecheckpoint (Fankhauser et al., 1993).

Several aspects of MEN regulation and its connections with mitoticexit and cytokinesis control are still obscure, and new playersin these important processes still await discovery. In thisarticle, we provide the first characterization of the buddingyeast open reading frames YHR115c and YNL116w, which we renamedDMA1 and DMA2, based on the homology of their gene productswith that of the fission yeast dma1⁺ gene, which was originallyisolated as multicopy suppressor of the temperature-sensitivegrowth phenotype caused by cdc16 mutations (Murone and Simanis,1996). Schizosaccharomyces pombe Dma1 is required for SIN inhibitionin the presence of spindle damage (Murone and Simanis, 1996;Guertin et al., 2002) and is homologous, like S. cerevisiaeDma1 and Dma2, to human Chfr, which is missing in several cancercell lines and has been shown to be a component of a stress-inducedmitotic checkpoint (Scolnick and Halazonetis, 2000). All theseproteins share a forkhead-associated domain and a ring fingermotif, the latter being typical of ubiquitin ligase subunits(Joazeiro and Weissman, 2000). We show here that S. cerevisiaeDma1 and Dma2, which seem to be functionally redundant, areinvolved in proper septin ring positioning and cytokinesis.The simultaneous lack of Dma1 and Dma2 leads to spindle mispositioningand defects in the spindle position checkpoint. Conversely,overexpression of DMA2 causes cytokinetic defects that are partiallysuppressed by either BUB2 deletion or TEM1 overexpression, consistentlywith a lack of proper Tem1 activation.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Strains, Media, and Reagents
All yeast strains (Table 1) were derivatives of or were backcrossedat least three times to W303 (ade2-1, trp1-1, leu2-3112, his3-11,15,ura3, ssd1). Cells were grown in YEP medium (1% yeast extract,2% bactopeptone, 50 mg/l adenine) supplemented with 2% glucose(YEPD), 2% raffinose (YEPR), or 2% raffinose and 1% galactose(YEPRG). Unless otherwise stated, ${alpha}$ -factor was used at 2 µg/ml,nocodazole at 15 µg/ml, and hydroxyurea at 100 mM. Synchronizationexperiments were carried out at 25°C, and unless otherwisestated, galactose was added 0.5 h before release from either ${alpha}$ -factor or nocodazole.

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Table 1. Strains used in this study

Plasmid Constructions and Genetic Manipulations
Standard techniques were used for genetic manipulations (Sherman,1991; Maniatis et al., 1992). To clone DMA2 under the GAL1–10promoter (plasmid pSP185), a XbaI PCR product containing theDMA2 coding region was cloned in the XbaI site of a GAL1–10-bearingYIplac211 vector. pSP185 integration was directed either tothe URA3 locus by EcoRV digestion (strains ySP3016 and ySP3018)or to the DMA2 locus by HpaI digestion (strains ySP3656 andySP3657). Copy number of the integrated plasmid was verifiedby Southern blot analysis. Because this analysis did not allowto assess the precise number of integrated plasmids for allthe transformants, we generically indicated as multiple integrantsthe strains with an integrated plasmid copy number higher thanthree (ySP3018 and ySP3657). All strains carrying multiple copiesof the GAL1-DMA2 construct (GAL1-DMA2 m) at either the URA3or DMA2 locus are meiotic segregants derived from the parentalstrains ySP3018 or ySP3657, respectively, and therefore carrythe same number of pSP185 integrated copies as the correspondingparental strain. Gene deletions were generated by one-step genereplacement (Wach et al., 1994).

Protein Extracts, Western Blot Analysis, and Kinase Assays
For Western blot analysis, protein extracts were prepared accordingto Surana et al. (1993). For Clb2/Cdk1 kinase assays, proteinextracts were prepared as described previously (Schwob et al.,1994), and 50 µg of extract was used for measuring kinaseactivity on histone H1 (Surana et al., 1993) and for Westernblot analysis. Proteins transferred to Protran membranes (Schleicher& Schuell, Keene, NH) were probed with 12CA5 monoclonalantibodies for hemagglutinin (HA)-tagged Cdc5, and with polyclonalantibodies against Swi6, Clb2, and Sic1 (kind gifts from K.Nasmyth (Institute of Molecular Pathology, Vienna, Austria),W. Zachariae (Max Planck Institute & Molecular Cell Biology,Dresden, Germany), and Mike Tyers (University of Toronto, Toronto,ON, Canada), respectively). Secondary antibodies were from AmershamBiosciences (Piscataway, NJ), and proteins were detected byan enhanced chemiluminescence system according to the manufacturer.

Fluorescence Microscopy, Image Analysis, and Measurements
Nuclear division was scored with a fluorescent microscope oncells stained with propidium iodide. In situ immunofluorescenceof microtubules was performed according to Fraschini et al.(1999) by using the YOL34 monoclonal antibody (Serotec, Oxford,United Kingdom) followed by indirect immunofluorescence withrhodamine-conjugated anti-rat antibody (1:100; Pierce Chemical,Rockford, IL). Detection of Cdc3-green fluorescent protein (GFP),Spc42-GFP, and tetR-GFP dots to score sister chromatid separationwas carried out on ethanol-fixed cells, upon wash with waterand sonication. Digital images were taken with a Leica DC350Fcharge-coupled device camera mounted on a Nikon Eclipse 600and controlled by the Leica FW4000 software. To measure distancebetween spindle and bud neck, sets of three to four fluorescentimages in Z-focal planes 0.3 µm apart were combined intosingle two-dimensional projection. Distances were measured betweenthe proximal end of either metaphase spindles or spindle poles(on Spc42-GFP–expressing cells) and the bud neck on 100–200cells by using the Leica FW4000 software. Comparisons of statisticalsignificance were done by Student's t-test.

Other Techniques
Flow cytometric DNA quantitation was determined according toFraschini et al. (1999) on a BD Biosciences FACScan. Percentageof cells with 2C DNA contents was measured with the CELLQuestsoftware.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Lack of Dma1 and Dma2 Affects Spindle Positioning
Two homologues of human Chfr, which we renamed Dma1 and Dma2,are found to be encoded by the S. cerevisiae uncharacterizedopen reading frames YHR115c and YNL116w, respectively. Theyshow 58% of amino acid identity with each other and >40%with S. pombe Dma1, whereas homology with Chfr is less extensivebut still significant. To functionally characterize Dma1 andDma2, we first deleted each single open reading frame and foundno detectable effects of the single deletions on either cellcycle progression, cell viability, or spindle checkpoint response(our unpublished data). Because these results, together withthe high degree of homology between the two gene products, suggesteda possible functional redundancy, we constructed a double dma1 ${Delta}$ dma2 ${Delta}$ strain, which turned out to be viable and therefore suitablefor further analysis. To investigate the role of Dma1 and Dma2in the yeast cell cycle, we then deleted both genes in a haploidyeast strain carrying the tetO/tetR-GFP constructs to monitorsister chromatid separation at arms of chromosome V (Michaeliset al., 1997). Small unbudded cells were purified by elutriationand released into fresh medium at 25°C to monitor at differenttime points the kinetics of budding, DNA replication, bipolarspindle assembly and elongation, and sister chromatid separation.Despite that we did not find major differences in any of theseparameters between dma1 ${Delta}$ dma2 ${Delta}$ cells and wild type (Figure 1A),we noticed that two GFP-separated dots, indicative of chromosomeV sister separation, could be found within the same cell bodyin a higher fraction of dma1 ${Delta}$ dma2 ${Delta}$ cells than wild type (Figure 1A).This suggests that the lack of Dma1 and Dma2 might affect,among other processes, spindle positioning, because the presenceof mispositioned spindles does not prevent the onset of anaphasein budding yeast (Sullivan and Huffaker, 1992). Accordingly,when we measured directly the average distance between bud necksand the proximal end of metaphase spindles at the time of theirhighest percentage (135' for wild-type and 180' for dma1 ${Delta}$ dma2 ${Delta}$ cells), we found a slight but statistically significant increasein the value found for dma1 ${Delta}$ dma2 ${Delta}$ spindles (1.35 ± 0.39vs. 1.14 ± 0.36 µm, p < 0.0001). To confirmthat lack of Dma1 and Dma2 affects spindle positioning, we alsomeasured the average distance between the bud neck and the proximalspindle pole body (SPB), as well as the average angle betweenthe short bipolar spindle and the mother-bud axis, in eithercycling wild-type or dma1 ${Delta}$ dma2 ${Delta}$ cells expressing the structuralSPB component Spc42 fused to GFP and displaying two GFP dotsfacing each other in the same cell body, indicative of a preanaphasestage. Again, the average distance between the proximal SPBand the bud neck was higher in dma1 ${Delta}$ dma2 ${Delta}$ than in wild-type cells(0.8 ± 0.39 vs. 0.65 ± 0.37 µm, p = 0.004),whereas the mean angle seemed to be not significantly affected(38.6 ± 24.1 vs. 35.6 ± 22.7°, p = 0.3). Whenwe compared spindle orientation in dma1 ${Delta}$ dma2 ${Delta}$ versus wild-typecells expressing ${alpha}$ tubulin fused to GFP (Tub1-GFP), we foundthat indeed the lack of Dma1 and Dma2 caused a slight increase(13%) in the percentage of cells that displayed short bipolarspindles pointing away from the bud neck (Figure 1B).

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Figure 1. Dma1 and Dma2 are required for proper spindle positioning. (A) Small unbudded wild-type (ySP1125) and dma1 ${Delta}$ dma2 ${Delta}$ cells (ySP2529) were purified by elutriation and allowed to progress in the cell cycle in fresh YEPD medium at 25°C (time 0). At the indicated time points cell samples were collected for fluorescence-activated cell sorting analysis of DNA contents (top) and to score microscopically kinetics of budding, sister chromatid separation, bipolar spindle assembly, and elongation (bottom). (B) Percentage of correctly positioned and mispositioned short metaphase spindles was scored in logarithmically growing cell cultures of wild-type and dma1 ${Delta}$ dma2 ${Delta}$ strains expressing a TUB1-GFP fusion (n $≥$ 200). The photograph shows examples of short metaphase spindles in dma1 ${Delta}$ dma2 ${Delta}$ cells. (C) Serial dilutions of strains with the indicated genotypes were spotted on YEPD plates and incubated for2dat either 25 or 37°C. (D) Logarithmically growing cultures of strains with the indicated genotypes were shifted from 25 to 37°C for 4 h. The percentage of binucleate cell bodies over total number of cells was scored after sonication and nuclear staining with propidium iodide (n $≥$ 500). (E) The uninucleate budded cells grown at 25°C from D) were scored for nuclear position with respect to the middle (dotted line) of the mother cell (n $≥$ 200).

Wild-type cells treated with hydroxyurea (HU) display penetrationof the nucleus into the bud, whereas the spindle is confinedin the mother cell. This process is defective when spindle positioningis compromised (Yeh et al., 1995). We therefore asked what wasthe behavior of dma1 ${Delta}$ dma2 ${Delta}$ cells in these conditions and foundthat, whereas in HU a significant fraction of wild-type cells(39.5%) displayed stretched nuclei across the neck, only 11.8%of dma1 ${Delta}$ dma2 ${Delta}$ cells did so (Table 2), suggesting that properspindle positioning requires Dma1 and/or Dma2. Conversely, spindlealignment along the mother-bud axis was similar in HU-treatedwild-type and dma1 ${Delta}$ dma2 ${Delta}$ cells (mean angle 39.9 ± 25.4°for wild type and 39.9 ± 25° for dma1 ${Delta}$ dma2 ${Delta}$ ).

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Table 2. Nuclear distribution in HU-arrested cells

We therefore looked for synthetic effects between the doubleDMA1/DMA2 deletion and mutations in genes implicated in nuclearpositioning and/or spindle orientation, such as kip1 ${Delta}$ , kip3 ${Delta}$ ,kar3 ${Delta}$ , bim1 ${Delta}$ , kar9 ${Delta}$ , dyn1 ${Delta}$ , bni1 ${Delta}$ , and cla4 ${Delta}$ . The dma1 ${Delta}$ dma2 ${Delta}$ cla4 ${Delta}$ combinationturned out to be lethal at 25°C (see below), whereas dma1 ${Delta}$ dma2 ${Delta}$ bim1 ${Delta}$ , dma1 ${Delta}$ dma2 ${Delta}$ bni1 ${Delta}$ , and dma1 ${Delta}$ dma2 ${Delta}$ dyn1 ${Delta}$ strains were temperaturesensitive for growth at 37°C (Figure 1C), although to differentextents. No obvious synthetic growth defects were found by combiningdma1 ${Delta}$ dma2 ${Delta}$ with the remaining tested mutations (our unpublisheddata). We then asked whether the observed synthetic growth defectscorrelated with additive effects caused by the above-mentionedmutations on spindle positioning. For this purpose, we measuredthe percentage of binucleate cell bodies, arising from anaphasetaking place in the mother cell, in strains lacking Bim1, Bni1,or Dyn1 either alone or in combination with dma1 ${Delta}$ dma2 ${Delta}$ . As shownin Figure 1D, the absence of Dma1 and Dma2 caused by itselfa modest increase in the percentage of binucleate cell bodies,which was additive with that caused by deletion of BIM1, BNI1,or DYN1. The increment in the fraction of binucleate cell bodiesin the triple mutants compared with the single mutants was alreadyapparent at 25°C and became more evident after incubationfor 4 h at 37°C, due to the stronger effect of BIM1, BNI1,and DYN1 deletions on spindle positioning at this temperature(Figure 1D). Finally, we analyzed nuclear positioning in someof the above-mentioned mutants grown at 25°C, by measuringthe amount of budded cells where the nucleus was away from thebud neck with respect to those where the nucleus was correctlypositioned. We excluded from this analysis bni1 ${Delta}$ mutants becauseof their marked clumpiness, which made very difficult to establishthe position of the bud necks. DMA1/DMA2 deletion increasedby itself the amount of cells with mispositioned nuclei by morethan threefold compared with wild type, and slightly increasednuclear positioning defects of bim1 ${Delta}$ and dyn1 ${Delta}$ mutants (Figure 1E).Together, these data suggest that Dma1 and Dma2 participateto spindle positioning.

Dma1 and Dma2 Are Required for Correct Septin Ring Assembly
The synthetic lethality caused by the simultaneous lack of Cla4,Dma1, and Dma2 suggested that these proteins might be involvedin the same process and prompted us to test whether Dma1 andDma2 could be involved in septin ring deposition. In fact, theCla4 PAK kinase has been implicated in the correct assemblyof the septin ring at the bud neck at the onset of budding (Cvrckovaet al., 1995) and the septin ring is in turn required for correctnuclear positioning (Kusch et al., 2002). By using the temperature-sensitivecla4-75 allele (Cvrckova et al., 1995), we first constructeda cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ triple mutant, which was viable at 25°Cbut could not grow at 37°C, whereas cla4-75 cells grew normallyat 37°C (Figure 2A) due to the functional redundancy betweenCla4 and the PAK kinase Ste20 (Cvrckova et al., 1995). Culturesof wild-type, dma1 ${Delta}$ dma2 ${Delta}$ , cla4-75, and cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ cells,all expressing the septin ring component Cdc3 fused to GFP (Cdc3-GFP),were grown at 25°C and then shifted to 37°C for 3 h.As shown in Figure 2B, upon temperature shift the lack of eitherCla4 or Dma1 and Dma2 reduced the percentage of cells with acorrectly assembled septin ring from 60 to 23 and 32% respectively,whereas it markedly increased the fraction of cells with eithermislocalized rings or diffuse unlocalized GFP signal, despitethat Cdc3-GFP protein levels remained unchanged (Figure 2C).Strikingly, the simultaneous lack of all the above-mentionedproteins dramatically compromised septin ring deposition, allowingthis process to take place correctly in only 8% of the cells.In addition, cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ cells were often misshapen orwith wide bud necks (Figure 2B) and mostly arrested with 2CDNA contents and undivided nuclei (our unpublished data), suggestingthat the morphogenesis checkpoint might be active in these conditions(Lew and Reed, 1995). Thus, Dma1 and Dma2 participate, likeCla4, to proper septin ring deposition.

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Figure 2. Synthetic effects between dma1 ${Delta}$ dma2 ${Delta}$ and cla4-75 on cell growth and septin ring deposition. (A) Serial dilutions of logarithmically growing cultures of strains with the indicated genotypes were spotted on YEPD plates and incubated for2dat25and37°C. Two independent cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ meiotic segregants from the same heterozygous diploid are shown. (B) Cultures of the indicated strains, all carrying a CDC3-GFP–bearing low copy number plasmid, were grown in selective medium to maintain the plasmid at 25°C and then shifted to 37°C for 3 h. The percentage of cells with either correctly deposited or mispositioned septin ring, as well as diffuse unlocalized signal, was scored by monitoring the septin ring marker Cdc3-GFP (graph, n $≥$ 300). The photographs show examples of Cdc3-GFP localization at 37°C in wild-type (wt), dma1 ${Delta}$ dma2 ${Delta}$ , cla4-75, and cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ cells. (C) Same amounts of protein extracts from the cell cultures used for B were analyzed by Western blot with anti-GFP antibodies to monitor protein levels of Cdc3-GFP. 1, wt 25°C; 2, wt 37°C; 3, dma1 ${Delta}$ dma2 ${Delta}$ 25°C; 4, dma1 ${Delta}$ dma2 ${Delta}$ 37°C; 5, cla4-75 25°C; 6, cla4-75 37°C; 7, cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ 25°C; and 8, cla4-75 dma1 ${Delta}$ dma2 ${Delta}$ 37°C. C, loading control.

Dma1 and Dma2 Participate to the Spindle Position Checkpoint
Both S. pombe Dma1 and human Chfr have been shown to be involvedin mitotic checkpoint responses (Murone and Simanis, 1996; (Scolnickand Halazonetis, 2000). To verify whether Dma1 and Dma2 couldthemselves function in the spindle assembly checkpoint, we arrestedin G1 by ${alpha}$ factor and released in the presence of nocodazoledma1 ${Delta}$ dma2 ${Delta}$ cells, as well as wild-type and mad2 ${Delta}$ bub2 ${Delta}$ double mutantcells, all carrying the tetO/tetR-GFP constructs to monitorsister chromatid separation at arm regions of chromosome V (Michaeliset al., 1997). Whereas mad2 ${Delta}$ bub2 ${Delta}$ cells separated sister chromatidsand rereplicated their genome very efficiently, being completelycheckpoint deficient (Alexandru et al., 1999; Fesquet et al.,1999; Fraschini et al., 1999), wild-type and dma1 ${Delta}$ dma2 ${Delta}$ mutantcells arrested mostly in metaphase with 2C DNA contents (Figure 3A),suggesting that Dma1 and Dma2 are not required for thecheckpoint activated by spindle disassembly.

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Figure 3. Dma1 and Dma2 are involved in the spindle position checkpoint. (A) Isogenic strains with the indicated genotypes, all carrying the tetO/tetR-GFP constructs, were arrested in G1 by ${alpha}$ factor and released in the presence of nocodazole to measure at different time points DNA contents by fluorescence-activated cell sorting analysis (left) and sister chromatid separation at arms of chromosome V (right). (B) Cultures of strains with the indicated genotypes were grown at 25°C and shifted at time 0–37°C for 7 h. Percentages of the different cell types, drawn on the right side of the figure, were determined after sonication and nuclear staining with propidium iodide.

We then asked whether Dma1 and Dma2 could instead be involved,like Bub2 and Bfa1, in the spindle orientation checkpoint, thatdelays MEN activation in response to spindle mispositioning.To address this question, we deleted DMA1 and DMA2 in a strainlacking the dynein-encoding gene DYN1. In the absence of dyneinspindles are mispositioned, and as a consequence, a small fractionof cells undergo anaphase and nuclear division in the mothercell (Yeh et al., 1995). In spite of that, cells fail to exitmitosis and divide, due to a Bub2/Bfa1-dependent checkpoint(Figure 3B; Bardin et al., 2000). Because dyn1 ${Delta}$ mutants accumulatedbinucleate cell bodies at 37°C (Figure 1D) and the dma1 ${Delta}$ dma2 ${Delta}$ dyn1 ${Delta}$ triple mutant was temperature sensitive (Figure 1C),we scored failures in the spindle position checkpoint after7 h at 37°C, by monitoring the percentage of cells withmore than one bud, which had either one undivided nucleus ortwo separated nuclei within the same cell body and thereforehad not undergone a proper anaphase. In fact, the emergenceof a second bud in such cells is a marker of unscheduled mitoticexit, no longer coupled to nuclear division. Under these conditions,14% of dyn1 cells underwent anaphase in the mother cell dueto spindle misorientation, but neither rebudded (Figure 3B)nor rereplicated DNA (our unpublished data). Similarly to BUB2deletion, the lack of Dma1 and Dma2 caused 16% of dyn1 cellsto bud again before proper nuclear division (Figure 3B) andto enter a new round of DNA replication, accumulating with DNAcontents higher than 2C (our unpublished data), suggesting thatthese proteins are required to delay mitotic exit in the presenceof mispositioned spindles.

DMA2 Overexpression Prevents Mitotic Exit in Nocodazole-treated bub2 ${Delta}$ and mad2 ${Delta}$ Cells
Because S. pombe dma1⁺ was isolated as multicopy suppressorof the temperature sensitivity of cdc16 mutant cells (Muroneand Simanis, 1996), we asked whether overexpression of one ofits budding yeast homologues could rescue the checkpoint defectsof cells lacking Bub2, the budding yeast counterpart of Cdc16.To address this question, the DMA2 coding sequence was clonedunder the control of the galactose-inducible GAL1 promoter (GAL1-DMA2)and integrated in single copy into the yeast genome. We firstcompared the kinetics of mitotic exit in GAL1-DMA2 versus wild-typecells in synchronized cultures grown in raffinose-containingmedium (GAL1 promoter off), arrested in G1 with ${alpha}$ factor andthen released in the presence of galactose (GAL1 promoter on).No major differences could be seen between the two strains inthe kinetics of Clb2 degradation, Sic1 accumulation, Clb2/Cdk1kinase inactivation, and spindle disassembly (Figure 4A), suggestingthat overproduction of Dma2 from the GAL1 promoter does notinterfere with mitotic exit during an unperturbed cell cycle.To ask whether overexpression of DMA2 could rescue spindle checkpointdefects, wild-type and bub2 ${Delta}$ cells, either lacking or carryingthe GAL1-DMA2 fusion, were treated as described above and thenreleased from the G1 arrest in the presence of galactose andnocodazole, to depolymerize microtubules. As expected, in theseconditions wild-type cells arrested in metaphase with 2C DNAcontents, irrespective of the presence of GAL1-DMA2, and bub2 ${Delta}$ cells exited mitosis and entered into a new round of buddingand DNA replication, accumulating 4C DNA contents. Conversely,DMA2 overexpression in bub2 ${Delta}$ cells mostly prevented them fromrereplicating their DNA (Figure 4B).

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Figure 4. Overexpression of DMA2 prevents mitotic exit in nocodazole treated spindle checkpoint mutants. (A) Cultures of wild-type cells either lacking (wt) or carrying (GAL1-DMA2) one single copy of the GAL1-DMA2 fusion integrated at the URA3 locus were grown in YEPR, arrested in G1 by ${alpha}$ factor, and released in YEPRG. When the percentage of budded cells was >90% (t = 105') ${alpha}$ factor was readded at the concentration of 10 µg/ml. Cells were harvested at the indicated times for fluorescence-activated cell sorting analysis (FACS) of DNA contents, kinetics of budding, nuclear division, and spindle elongation after immunostaining of ${alpha}$ tubulin. At the same time points, cell samples were collected also for Western blot analysis with anti-Clb2 and anti-Sic1 (Swi6, loading control) and for Clb2/Cdk1 immunoprecipitations followed by kinase assays by using histone H1 as substrate. (B) Cultures of isogenic strains with the indicated genotypes, either lacking or carrying one copy of the GAL1-DMA2 fusion integrated at the URA3 locus and logarithmically growing in YEPR were arrested in G1 by ${alpha}$ factor and released in YEPRG containing nocodazole (time 0). At the indicated times, DNA contents were analyzed by FACS. (C) Wild-type, GAL1-DMA2 (our unpublished data), mad2 ${Delta}$ , and mad2 ${Delta}$ GAL1-DMA2 strains, all carrying the tetO/tetR-GFP constructs to measure sister chromatid separation at subtelomeric regions, were treated as in A. At the indicated times, cell samples were collected for FACS analysis of DNA contents (left) and kinetics of sister chromatid separation (right).

Whereas Bub2 and Cdc16 inhibit mitotic exit and cytokinesisthrough similar pathways (Simanis, 2003), Mad2 belongs to adifferent branch of the mitotic checkpoint, which prevents sisterchromatid separation and MEN activation via a different route(Gardner and Burke, 2000). It was therefore interesting to verifywhether DMA2 overexpression also could suppress the checkpointdefects of cells lacking Mad2. To this end, wild-type, GAL1-DMA2,mad2 ${Delta}$ , and mad2 ${Delta}$ GAL1-DMA2 strains carrying the tetO/tetR-GFPconstructs to monitor separation of sister chromatids at subtelomericregions (Alexandru et al., 2001) were treated as described above.Upon spindle disassembly by nocodazole, wild-type and GAL1-DMA2cells arrested with unseparated sister chromatids (Figure 4C)and 2C DNA contents (our unpublished data), whereas mad2 ${Delta}$ cells,as expected, lost sister chromatid cohesion and underwent asecond round of DNA replication (Figure 4C). Overexpressionof DMA2 in the latter cells could not prevent the onset of anaphase,but mostly inhibited rereplication (Figure 4C), suggesting thatDma2 does not influence the ability of Mad2 to inactivate Cdc20/APC,which in turn promotes sister chromatid separation (Musacchioand Hardwick, 2002), but rather intervenes more downstream inthe pathway. Thus, high levels of Dma2 can prevent both mad2 ${Delta}$ and bub2 ${Delta}$ cells from exiting mitosis and entering into a newcell cycle, indicating that they might affect MEN activationunder certain conditions.

Overexpression of DMA2 Causes Cytokinetic Defects Partially Suppressed by BUB2 Deletion
To gain insights into the molecular mechanisms leading to suppressionof mitotic checkpoint defects by DMA2 overexpression, we analyzedthe effects of Dma2 high dosage during an unperturbed cell cycle.For this purpose, we monitored cell cycle progression undergalactose-induced conditions of otherwise wild-type cells carryingeither none, one single (s) or multiple tandem copies (m) ofGAL1-DMA2 integrated in the genome. G1 synchronized cell cultureswere released in the presence of galactose, and kinetics ofDNA replication, budding, spindle assembly/breakdown, and nucleardivision were monitored on fixed cells at different times afterrelease. As shown in Figure 5A, wild-type cells could completeone division cycle within 120 min, as indicated by the reappearanceof cells with 1C DNA contents after nuclear division and disassemblyof anaphase spindles. Expression of GAL1-DMA2(s), as observedpreviously (Figure 4A), had only modest effects on cell cycleprogression, causing at most a 15-min delay in spindle disassemblyand cell division. However, compared with wild type, a higherpercentage of GAL1-DMA2(s) cells with 2C DNA contents persistedthroughout the course of the experiment and a small fractionof undivided cells occurred at later time points, accumulatingas chains of cells with DNA contents higher than 2C (Figure 5A).These effects were magnified by expression of GAL1-DMA2(m),which allowed very few cells with 1C DNA contents to reaccumulate,whereas $~$ 30% of the cells occurred as rebudded, multinucleatedcells with DNA contents higher than 2C at 240 min after induction(Figure 5A). Most of these cells could not be separated aftercell wall digestion with zymolase (our unpublished data), suggestingthat they arose from a cytokinetic failure. These cytokineticdefects did not correlate with inability to exit mitosis. Infact, GAL1-DMA2(m) cells could not only rebud and enter intoa new round of DNA replication but also could disassemble theirspindles, albeit more slowly than wild-type cells (Figure 5A),suggesting that high levels of Dma2 can, at most, delay mitoticexit, while more severely affecting cytokinesis.

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Figure 5. Overexpression of DMA2 interferes with cytokinesis and septin ring disassembly. (A) Cultures of wild-type cells, either untransformed (wt) or carrying one (s) or multiple (m) copies of the GAL1-DMA2 fusion integrated at the DMA2 locus, were grown in YEPR, synchronized in G1 with ${alpha}$ factor, and released into YEPRG at time 0. Samples were withdrawn at the indicated time points for fluorescence-activated cell sorting analysis (FACS) analysis of DNA contents (top) and to score kinetics of budding, nuclear division and spindle elongation (bottom). Cell cycle progression of a bub2 ${Delta}$ GAL1-DMA2(m) cell culture under the same conditions was followed in parallel by FACS analysis. (B) Serial dilutions of the indicated cell cultures, either lacking or carrying a single (s) or multiple (m) copies of the GAL1-DMA2 fusion integrated at the DMA2 locus were spotted on YEPD (Glu) and YEPRG (Gal) plates and incubated for 3 d at 23°C. (C) Wild-type (W303) and GAL1-DMA2(m) (ySP3018) cells expressing a Cdc3-GFP fusion were grown in YEPR, synchronized with ${alpha}$ factor, and released into YEPRG. At the time cells entered S phase of the second cell cycle (150', as determined by FACS analysis), cells with two Cdc3-GFP rings or mispositioned GFP signals were scored (see text for details). Photographs show examples of GAL1-DMA2 cells that either deposit a new septin ring before disassembly of the previous one (left) or show mislocalized Cdc3-GFP signal (right).

By analogy to SIN inhibition by S. pombe Dma1 (Guertin et al.,2002), it was possible that the phenotypic effects caused byDMA2 overexpression were due to partial MEN inactivation. Wetherefore asked whether deletion of BUB2, encoding a well-characterizedMEN inhibitor (Simanis, 2003), could restore normal cell cycleprogression in cells expressing high Dma2 levels. Strikingly,the cytokinetic defects of GAL1-DMA2(m) cells could be almosttotally rescued by inactivation of Bub2. In fact, GAL1-DMA2(m)bub2 ${Delta}$ cells were almost completely able to divide and reaccumulatewith 1C DNA contents (Figure 5A). Furthermore, deletion of BUB2partially rescued the lethality caused by GAL1-DMA2(m) overexpression(Figure 5B). We also analyzed whether the cytokinetic defectsof GAL1-DMA2(m) cells could be rescued by inactivation of othermitotic inhibitors, such as the mitotic CDK inhibitory kinaseSwe1 (Booher et al., 1993) and the Tem1 inhibitor Amn1 (Wanget al., 2003). In contrast to BUB2 deletion, neither AMN1 norSWE1 deletion could alleviate the cytokinetic defects causedby DMA2 overexpression (Figure S1A, supplementary data).

To investigate in further detail the reasons for the cytokineticfailure observed upon overexpression of DMA2, we analyzed whetherthe septin ring was correctly positioned in GAL1-DMA2(m) cellscompared with wild-type. In fact, a septin ring, which is anessential prerequisite for cytokinesis, is assembled at theG1/S transition at the site of bud emergence (Longtine et al.,1996) and is normally disassembled during mitotic exit in aTem1-dependent manner (Lippincott et al., 2001). We found thatindeed overproduction of Dma2 caused remarkable differencesin the kinetics of septin ring disassembly compared with wildtype. In fact, after release in the presence of galactose ofG1 synchronized cultures of wild-type and GAL1-DMA2(m) cellscarrying the Cdc3-GFP fusion, no cells with two septin ringswere seen among >300 wild-type cells, whereas 17% of GAL1-DMA2(m)cells showed a new septin ring at the site of bud emergencebefore disassembly of the old one (Figure 5C, left) at 150 minafter release from G1, when cells entered into a new round ofbudding and DNA replication. Interestingly, these cells rebuddedonly from the previous bud and never from the mother cell, consistentlywith a role of the septin ring in creating a physical barrierto the diffusion of cell polarity determinants through the budneck (Barral et al., 2000). A fraction of GAL1-DMA2(m) cells(14 vs. 1.2% of wild-type cells) showed also aberrant septinring deposition (Figure 5C, right). Together, these data suggestthat overexpression of DMA2 affects normal septin ring depositionand disassembly, thus causing cytokinetic defects.

Because we found that spindle disassembly was somewhat delayedin DMA2-overexpressing cells (Figure 5A), we also analyzed moreaccurately to what extent mitotic exit could be compromisedin such cells by checking directly MEN activation in late mitosis.As a readout, we analyzed by Western blot degradation of twoAPC substrates, the Polo kinase Cdc5 and the main mitotic cyclinClb2, as well as reappearance of the CDK inhibitor Sic1, bothevents depending on MEN-dependent activation of the Cdc14 phosphataseat the end of mitosis (Shirayama et al., 1998; Visintin et al.,1998). Wild-type and GAL1-DMA2(m) cells were arrested in metaphaseby nocodazole treatment and then released in the presence ofgalactose and ${alpha}$ factor, to arrest them in the next G1 phase.Consistently with a cytokinetic defect, cell division kineticswas very slow in GAL1-DMA2(m) cells, and DMA2 overexpressioncaused accumulation of cells with long anaphase spindles comparedwith wild type, suggesting that spindle disassembly was transientlydelayed (Figure 6). However, spindles eventually disassembledbetween 90 and 120 min. Similarly, Clb2 was degraded and Sic1reappeared with $~$ 15-min delay with respect to wild type (Figure 6).Proteolysis of a HA-tagged version of Cdc5 was more dramaticallyaffected and was not completed by the end of the experiment(150 min) in GAL1-DMA2(m) cells, whereas it was already apparentat 105 min in wild-type cells under the same conditions. Therefore,Dma2 high levels seem to interfere with some aspects of mitoticexit.

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Figure 6. Mitotic exit upon DMA2 overexpression. Wild-type (wt, ySP939) and GAL1-DMA2m (ySP3318) cells expressing HA-tagged Cdc5 (Cdc5-HA3) were grown in YEPR, synchronized in metaphase by nocodazole treatment (5 µg/ml), and released at time 0 into YEPRG containing ${alpha}$ factor to arrest cells in the next G1. Cell samples were withdrawn at the indicated times for fluorescence-activated cell sorting analysis of DNA contents (top); kinetics of budding, nuclear division, and spindle elongation (middle); and Western blot analysis of Cdc5-HA3, Clb2, and Sic1 (bottom).

Overexpression of DMA2 Interferes with Tem1 Activation
Because the data so far suggested that Dma1 and Dma2 could impingeon the same pathway as Bub2, we asked whether their target mightbe the MEN, and looked for genetic interactions between MENcomponents and Dma2. To this end, we analyzed the effects ofGAL1-DMA2(s) expression, which has only minor effects on cellproliferation of otherwise wild-type cells, in some mutantsdefective at the top of the MEN cascade, such as cdc5-1, cdc5-2,lte1 ${Delta}$ , cla4 ${Delta}$ , and tem1-3. In all mutants, except for lte1 ${Delta}$ , wecould see a toxic effect on cell proliferation caused by ectopicDMA2 expression even at 25°C, permissive temperature forthe above-mentioned mutants. Therefore, high levels of Dma2are deleterious when the MEN is partially compromised (Figure 7).In two mutants, cdc5-1 and cla4 ${Delta}$ , synthetic growth effectscaused by GAL1-DMA2 could be partially rescued by BUB2 deletion.The tem1-3 mutant was the most sensitive to DMA2 overexpression,and upon galactose induction accumulated cells rebudding fromthe previous bud and eventually containing multiple nuclei andmitotic spindles (Figure 7, B and C). This phenotype can alsobe seen in a low percentage of tem1-3 cells at the permissivetemperature (Figure 7B), allowing to speculate that Dma2 mightact close to Tem1 in the MEN. If this were the case, we wouldexpect overexpression of TEM1 to counteract the cytokineticdefects caused by high levels of Dma2, like BUB2 deletion does(Figure 5A). Indeed, TEM1 overexpression from the GAL1 promoterallowed cells expressing GAL1-DMA2(m) to undergo cytokinesiswith wild-type kinetics (Figure 8A), suggesting that Tem1 mightbecome limiting for promoting mitotic exit and cytokinesis inDMA2-overexpressing cells. In addition, GAL1-TEM1 expressionalso could restore cell viability in Dma2 overproducing cellsmore efficiently than BUB2 deletion (Figure 8B). Because S.pombe Dma1 was proposed to antagonize the polo kinase (Guertinet al., 2002), we wondered whether overproduction of the polokinase Cdc5 could restore proper cell division in cells containinghigh Dma2 levels. However, overexpression of CDC5, unlike thatof TEM1, did not suppress either cytokinetic defects or celllethality of GAL1-DMA2(m) cells (Figure S1, A and B, supplementarydata).

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Figure 7. DMA2 overexpression is toxic for MEN mutants. (A) Serial dilutions of the indicated cell cultures, lacking or carrying one copy of the GAL1-DMA2 fusion integrated at the URA3 locus, were spotted on either YEPD (Glu) or YEPRG (Gal) plates and incubated for two days at 25°C. (B) Cultures of the indicated strains were grown in YEPR at 25°C and induced with 1% galactose at time 0. Cell samples were withdrawn every 2 h for fluorescence-activated cell sorting analysis of DNA contents (our unpublished data), kinetics of accumulation of multinucleate cells (graph) and in situ immunostaining of ${alpha}$ tubulin (our unpublished data). (C) Examples of nuclei and microtubules of tem1-3 GAL1-DMA2 multinucleated cells from the experiment in B) after 4 h of galactose induction are shown.

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Figure 8. TEM1 overexpression rescues cytokinetic and growth defects caused by Dma2 high levels. (A) Cultures of isogenic strains with the indicated genotypes (ySP3616, ySP3657, and ySP3721), logarithmically growing in YEPR, were arrested in G1 by ${alpha}$ factor and released in YEPRG at time 0. Cell samples were withdrawn at the indicated times for fluorescence-activated cell sorting analysis of the DNA contents. (B) Serial dilutions of the indicated cell cultures were spotted on YEPD (Glu) or YEPRG (Gal) plates and incubated for 3 d at 23°C.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

A Role for Dma1 and Dma2 in Septin Ring Assembly
The first step in nuclear positioning occurs through migrationof the spindle toward the bud neck and requires a Kar9-dependentpathway that involves, besides the cortical determinant Kar9(Miller and Rose, 1998), the plus-end microtubule binding proteinBim1, that interacts with Kar9 (Korinek et al., 2000; Lee etal., 2000); the Bni1 protein, required for Kar9 proper localization(Miller et al., 1999); and the microtubule motor Kip3 (Cottinghamand Hoyt, 1997; DeZwaan et al., 1997). A second pathway, leadingto insertion of the spindle through the bud neck, depends oncytoplasmic dynein (Cottingham and Hoyt, 1997; DeZwaan et al.,1997) and on the cortical protein Num1 (Heil-Chapdelaine etal., 2000). The two pathways are presumably functionally redundant,because inactivation of any gene of one pathway in the absenceof any component of the second pathway is often lethal or severelydeleterious. Recently, septins also have been implicated inspindle positioning by providing a cortical cue for microtubulecapture, and based on genetic interactions have been proposedto act in the nuclear positioning Kar9 pathway (Kusch et al.,2002). We now show that Dma1 and Dma2 might have a direct rolein septin ring deposition and might therefore control spindlepositioning. In fact, lack of both Dma1 and Dma2 compromiseseptin ring assembly and have additive effects with cla4 mutations.In addition, overexpression of Dma2 delays septin ring disassemblyat the end of mitosis. We find that the lack of Dma1 and Dma2does not cause synthetic growth defects when combined with deletionof either KAR9 or KIP3 (our unpublished data), whereas it confersa temperature-sensitive growth phenotype to dyn1 ${Delta}$ cells, whichwould suggest that Dma1 and Dma2 might act in the Kar9-dependentpathway. However, the finding that DMA1/DMA2 deletion causesadditive defects on spindle positioning when combined with thelack of either Bim1 or Bni1 argues against this simple view,suggesting that Dma1 and Dma2 might act in a novel spindle positioningpathway. This is still an open question, since genetic interactionsdo not always reflect the complex functional interactions takingplace between components of the spindle positioning/orientationpathways, because other exceptions to the above-mentioned simplegenetic rule have been previously observed. For example, deletionof BIM1 is lethal in kip3 ${Delta}$ cells, despite Bim1 and Kip3 supposedlybelong to the same spindle positioning pathway (Tong et al.,2001). In addition, despite that Cla4 also should participateto the Kar9-dependent pathway by virtue of its involvement inseptin ring organization (Cvrckova et al., 1995), it is essentialin a bni1 ${Delta}$ background (Goehring et al., 2003).

How Dma1 and Dma2 regulate septin ring organization is unknownat the moment. Septins undergo different posttranslational modifications,including covalent attachment of the ubiquitin-related peptideSUMO between the onset of anaphase and cytokinesis (Johnsonand Blobel, 1999). Multiple mutations in septin sumoylationsites prevents the disappearance of septin rings from old budsites, leading to the proposal that sumoylation of septins promotesdisassembly of the septin ring, either directly or indirectly,by preventing/inducing other posttranslational modifications,such as ubiquitination (Johnson and Blobel, 1999). Based onthe failure of DMA2-overexpressing cells to timely disassembleseptin rings, and on the notion that Dma1 and Dma2 are RINGfinger-containing proteins, and therefore possibly part of anE3 ubiquitin-ligase (Joazeiro and Weissman, 2000), an attractivehypothesis that is worth further investigation is that Dma1and Dma2 might directly mediate septins' ubiquitination or sumoylation.

The MEN as a Target of Dma1/Dma2
Fission yeast Dma1 has been found to prevent activation of theSIN, thereby inhibiting cytokinesis, and to interfere with thecorrect localization of the Polo kinase Plo1 and other SIN regulators(Guertin et al., 2002). In addition, its human homologue Chfris a ubiquitin ligase that ubiquitinates the Polo-like kinasePlk1 in Xenopus cell extracts (Kang et al., 2002). The followinglines of evidence suggest that the mitotic exit network couldbe a target of Dma1 and Dma2 regulation in budding yeast: 1)moderate DMA2 overexpression can suppress the ability of spindlecheckpoint mutants to exit mitosis in the presence of nocodazole;2) increased levels of Dma2 that are perfectly tolerated bywild-type cells are extremely toxic specifically for some MENmutants; and 3) strong DMA2 overexpression causes mitotic exitand cytokinesis defects that can be rescued by either deletionof BUB2 or simultaneous overexpression of TEM1. Indeed, allthese data could be consistent with a model where Dma1 and Dma2antagonize the activity of the Polo kinase Cdc5, because oneimportant function of Cdc5 in the MEN is to down-regulate theGTPase-activating protein Bub2/Bfa1, thus allowing Tem1 activation(Hu et al., 2001). However, so far we have been unable to findany correlation between Dma1/Dma2 activation and Cdc5 regulation.In fact, Cdc5 protein levels are unaltered in dma1 ${Delta}$ dma2 ${Delta}$ cells(Figure S2A, supplementary material) and more stable, ratherthan more labile, in DMA2-overexpressing cells (Figure 6). Moreover,high levels of Dma2 do not interfere with separation of sistertelomeres (Figure S2B, supplementary material), which dependsupon Cdc5 activity (Alexandru et al., 2001). Finally, cytokineticdefects caused by DMA2 overexpression are not rescued by highCdc5 levels (Figure S1A, supplementary material).

Another possibility is that the MEN inhibitory function of Dma1/Dma2is to inhibit Tem1 through the GAP Bub2/Bfa1. However, we thinkthis is not the case, because BUB2 deletion only partially counteractsthe deleterious effects on cytokinesis of Dma2 high levels andmostly does not suppress their lethal effects in MEN mutants.Moreover, DMA1/DMA2 deletion dramatically increases the benomylsensitivity of bub2 ${Delta}$ cells (our unpublished observations), suggestingthat Dma1/Dma2 and Bub2 might operate in different pathways.Accordingly, DMA2 overexpression can suppress the spindle checkpointdefects of bub2 ${Delta}$ cells. Therefore, we rather suspect that Dma1and Dma2 might impinge more directly on Tem1 activation. Infact, TEM1 overexpression can partially counteract the inhibitoryeffects on cytokinesis and the toxicity on growth caused byhigh levels of Dma2. In addition, depletion of Tem1 in conditionsthat allow mitotic exit causes defects in septin ring disassembly(Lippincott et al., 2001) that are remarkably similar to thoseobserved in DMA2-overexpressing cells.

Despite our efforts, how Tem1 inhibition by Dma1/Dma2 couldbe achieved has not yet been elucidated. In fact, Tem1 proteinlevels, localization at SPBs or interaction with Cdc15 (anotherMEN component) seemed to be unaffected by either DMA1/DMA2 deletionor DMA2 overexpression (our unpublished data). Accordingly,deletion of AMN1, which inhibits Tem1/Cdc15 interaction andMEN activation (Wang et al., 2003), did not rescue the deleteriouseffects caused by high levels of Dma2 (Figure S1A/B, supplementarymaterial), suggesting that Dma2 acts independently of Amn1.Because DMA2 overexpression seems to affect cytokinesis morethan mitotic exit, it is also possible that only a special poolof Tem1 is regulated by Dma1/Dma2 or that the latter proteinsand Tem1 antagonistically act in parallel to regulate downstreamMEN components. It is now well established that MEN componentshave cytokinetic functions independent of Cdc14 release fromthe nucleolus and inactivation of mitotic CDKs (Shou et al.,1999; Lippincott et al., 2001; Park et al., 2003). Further experimentswill be required to clarify these points. Being Dma1 and Dma2possibly part of an E3 ubiquitin ligase, the identificationof their substrates will be critical to understand their possiblerole in MEN regulation. Interestingly, a high-throughput massspectrometric analysis indicates that Dma1 and Dma2, besidesinteracting with each other, physically associate with a F-boxprotein (the gene product of YNL311), which in turn interactswith ubiquitin (Ho et al., 2002), further supporting their possibleinvolvement in a ubiquitination pathway.

Dma1/Dma2 and the Spindle Position Checkpoint
S. pombe Dma1 is required to delay mitotic exit and septum formationwhen spindle function is compromised (Murone and Simanis, 1996).Its human homologue Chfr is instead part of a mitotic stresscheckpoint that delays metaphase entry upon transient treatmentwith drugs interfering with microtubule dynamics (Scolnick andHalazonetis, 2000). Accordingly, Chfr was also found to inhibitthe Cdc2 kinase at the G2/M transition by prolonging its inhibitorytyrosine 15 phosphorylated state (Kang et al., 2002). We showedthat DMA2 overexpression interferes with mitotic exit and cytokinesis,but apparently not with the onset of anaphase. In addition,the deleterious effects caused by high Dma2 levels are not rescued,but rather enhanced, by deletion of SWE1 (Figure S1A, supplementarymaterial) that encodes the Wee1-like inhibitory kinase responsiblefor tyrosine 15 phosphorylation of mitotic CDKs (Booher et al.,1993). Therefore, Dma1 and Dma2 seem to have functions closerto their fission yeast, rather than human, counterpart.

The concomitant lack of Dma1 and Dma2 impairs the spindle positioncheckpoint. A striking correlation can be drawn between theinvolvement of Dma1/Dma2 in this checkpoint and their role inseptin ring assembly. In fact, septins have recently been shownto prevent inappropriate mitotic exit when cytoplasmic microtubulesdo not interact properly with the bud neck (Castillon et al.,2003). Unlike S. pombe Dma1, S. cerevisiae Dma1 and Dma2 arenot required to delay cell cycle progression in the presenceof nocodazole. In addition, whereas lack of Dma1 and Dma2 allowsunscheduled mitotic exit in dynein mutants, it does not haveany effect in the absence of Kar9 (our unpublished observations),suggesting that Dma1 and Dma2 are required to respond only tosome kinds of spindle misposition signals. In this respect,Dma1 and Dma2 share remarkable similarities with Bim1, whichis involved in spindle positioning/orientation (Tirnauer etal., 1999), and also has been implicated in a checkpoint thatdelays cytokinesis in the presence of mispositioned spindlesspecifically caused by dynactin mutation (Muhua et al., 1998).The surprising observation that bim1 ${Delta}$ cells do not necessarilyundergo premature cytokinesis in the presence of spindles mispositionedby other means (Tirnauer et al., 1999; Adames et al., 2001),together with our similar observation on dma1 ${Delta}$ dma2 ${Delta}$ cells, suggeststhat defects in dynein/dynactin might generate different signalsfrom those arising by other kinds of spindle positioning errors.

Interestingly, human Chfr is missing in several tumor cell lines(Scolnick and Halazonetis, 2000), whereas the Bim1 homologueEB1 is associated with the tumor suppressor adenomatous polyposiscoli protein (Su et al., 1995), suggesting that perhaps theseproteins are crucial to maintain genome stability. A detailedcharacterization of the errors they detect might therefore helpto shed light on the processes at the basis of tumor progression.

ACKNOWLEDGMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

We are grateful to Tony Hyman, John Kilmartin, Kyung Lee, KimNasmyth, Mike Tyers, and Wolfgang Zachariae for providing strainsand reagents; to Alessia Beretta for performing some preliminaryexperiments on dma1 ${Delta}$ dma2 ${Delta}$ mutants; and to Maria Pia Longhesefor critical reading of the manuscript. This work was supportedby grants from Associazione Italiana Ricerca sul Cancro to S.P.,and Cofinanziamento 2003 Ministero dell'Istruzione, dell'Universitàe della Ricerca-Università di Milano-Bicocca, Fondo pergli investimenti della Ricerca di Base, and Progetto StrategicoMinistero dell'Istruzione, dell'Università e della Ricerca-Legge449/97 to G.L.

Footnotes

Article published online ahead of print. Mol. Biol. Cell 10.1091/mbc.E04-02-0094.Article and publication date are available at www.molbiolcell.org/cgi/doi/10.1091/mbc.E04-02-0094.

Online version of this article contains supporting material.Online version is available at www.molbiolcell.org.

^* Corresponding author. E-mail address: simonetta.piatti{at}unimib.it.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

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