Dual Function of Cyk2, a cdc15/PSTPIP Family Protein, in Regulating Actomyosin Ring Dynamics and Septin Distribution

doi:10.1083/jcb.143.7.1947

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© The Rockefeller University Press, 0021-9525/1998//1947 $5.00
The Journal of Cell Biology, Volume 143, Number 7, , 1998 1947-1960

Regular Articles

Dual Function of Cyk2, a cdc15/PSTPIP Family Protein, in Regulating Actomyosin Ring Dynamics and Septin Distribution

John Lippincott and Rong Li

Department of Cell Biology, Harvard Medical School, Boston, Massachusetts 02115

We previously showed that the budding yeast Saccharomyces cerevisiaeassembles an actomyosin-based ring that undergoes a contraction-likesize change during cytokinesis. To learn more about the biochemicalcomposition and activity of this ring, we have characterizedthe in vivo distribution and function of Cyk2p, a budding yeastprotein that exhibits significant sequence similarity to thecdc15/PSTPIP family of cleavage furrow proteins. Video microscopyof cells expressing green fluorescent protein (GFP)-tagged Cyk2p revealed that Cyk2p forms a double ring that coincideswith the septins through most of the cell cycle. During cytokinesis,however, the Cyk2 double ring merges with the actomyosin ringand exhibits a contraction-like size change that is dependenton Myo1p. The septin double ring, in contrast, does not undergothe contraction-like size change but the separation between the two rings increases during cytokinesis. These observationssuggest that the septin-containing ring is dynamically distinctfrom the actomyosin ring and that Cyk2p transits between thetwo types of structures. Gene disruption of CYK2 does not affectthe assembly of the actomyosin ring but results in rapid disassembly of the ring during the contraction phase, leading to incompletecytokinesis, suggesting that Cyk2p has an important functionin modulating the stability of the actomyosin ring during contraction.Overexpression of Cyk2p also blocks cytokinesis, most likelydue to a loss of the septins from the bud neck, indicatingthat Cyk2p may also play a role in regulating the localizationof the septins.

Key Words: cytokinesis • actin • myosin • septins • yeast

Abbreviations used in this paper: Cyk2, cytokinesis 2; GFP, green fluorescent protein; HA, hemagglutinin; ORF, open reading frame; YPD, yeast extract, peptone, dextrose; YPG, yeast extract, peptone, galactose, raffinose.

Address correspondence to R. Li, Department of Cell Biology,Harvard Medical School, 240 Longwood Ave., Boston, MA 02115.Tel.: (617) 432-0640. Fax: (617) 431-1144. E-mail: rli{at}hms.harvard.edu

THE mechanisms that mediate and control cytokinesis are fundamentalto the successful completion of the cell cycle. Despite activeresearch throughout the years, these mechanisms remain elusive.Animal cells divide by cleavage furrow formation and the actionof an actomyosin-based contractile ring (for review see Schroeder, 1990;Satterwhite and Pollard, 1992; Fishkind and Wang, 1995). Thetiming and positioning of the cleavage furrow and contractilering are crucial for the proper distribution of organelles andgenetic information. The mechanochemical activity of the contractilering is unclear, but it is believed to function in a manneranalogous to actin and myosin in muscle. However, the contractilering exhibits several differences from the sliding actin-myosinfilaments in sarcomeres: (a) the actin and myosin filaments in the cleavage furrow are not always organized in parallel arrays (Verkhovsky and Borisy, 1993; Maupin et al., 1994); (b) there is an intimate association of the contractile ring with the cell membrane (Schroeder, 1990); (c) the ring gets smaller without increasing in width, indicating that contractilering components leave the ring as contraction occurs (Schroeder, 1972);and (d) the contractile ring contains components that have notbeen found in myofibrils (for review see Fishkind and Wang, 1995).Some of these components must contribute to the stability ofthe contractile ring to ensure its integrity during force generation.It is this complexity which has hampered the study of thiscritical structure and process.

Cytokinesis studies in the fission yeast Schizosaccharomycespombe have revealed a number of important proteins involvedin different aspects of cytokinesis (for review see Chang and Nurse, 1996;Gould and Simanis, 1997). One of these proteins, cdc15p, hasbeen shown to be a component of the actomyosin ring and essentialfor cytokinesis. cdc15p is a phosphoprotein containing a potential coiled coil domain, PEST sequences, and a carboxy-terminalSH3 domain (Fankhauser et al., 1995). Temperature-sensitivecdc15 mutant cells exhibit defects in localizing at least twomedial ring components, actin and cdc12p, a formin family protein,suggesting that cdc15p is involved in the assembly of the actomyosinring (Fankhauser et al., 1995; Chang et al., 1997). A recentstudy showed that cdc15 mutant cells are also unable to accumulateactin patches at the septum (Balasubramanian et al., 1998).Homologues of cdc15p have been found in multicellular organisms,including tapeworm, mouse, and human. The murine homologue,PSTPIP, has recently been shown to be involved in aspects ofcytoskeletal activities, including cytokinesis. It localizesto the cleavage furrow, and like cdc15p, blocks cytokinesiswhen overexpressed in S. pombe (Spencer et al., 1997).

In budding yeast, many proteins localize to the bud neck, thesite of cell division. Cortical actin patches localize at thebud neck around the time of cell division, although their functionis unknown. Another set of neck components involved in cytokinesisare the septins. The septins contain the products of the CDC3,CDC10, CDC11, and CDC12 genes and are thought to be the majorcomponent of the 10-nm neck filaments (for review see Longtine et al., 1996).Mutations in the septin genes lead to defects in cell morphogenesisand cytokinesis. The septins have also been found in the cleavagefurrow of animal cells, suggesting that their role in cytokinesisis conserved (Kinoshita et al., 1997). Recently, it was discoveredthat the budding yeast Saccharomyces cerevisiae also utilizesan actomyosin-based ring that exhibits contraction-like size change during cytokinesis (Bi et al., 1998; Lippincott and Li, 1998).In this organism the septins are required for the localizationof myosin II to the site of cell division, providing evidencethat the septins functionally interact with the actomyosinring.

So far, only three proteins have been directly implicated incontractile ring activity in budding yeast: Act1p (actin), Myo1p (a myosin II), and Cyk1p (an IQGAP-like protein). Geneticanalysis demonstrated that Cyk1p is crucial for the recruitmentof actin filaments to the Myo1 ring (Lippincott and Li, 1998).Further study of cytokinesis in budding yeast relies on theidentification of additional proteins that interact with theactomyosin ring. In this paper, we describe the characterizationof a protein that interacts with both the septin ring and theactomyosin ring. This protein, termed Cyk2p, is a budding yeasthomologue of cdc15p. A combination of genetics and video microscopyanalyses has revealed important information about the roleof Cyk2p in actomyosin ring activity and provided novel insightsinto the function of the cdc15/PSTPIP family proteins.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Media and Genetic Manipulations
Yeast cell culture and genetic techniques were carried out bymethods described in Sherman et al. (1974). Yeast extract, peptone,dextrose (YPD)¹ contained 2% glucose, 1% yeast extract, and2% Bactopeptone (Difco Laboratories, Detroit, MI). YPG contained2% galactose, 2% raffinose, 1% yeast extract, and 2% Bactopeptone.Synthetic complete media was prepared by the method describedin Kaiser et al. (1994).

Plasmid Construction
To construct CYK2-expressing plasmids, a DNA fragment containinga 265-bp 5' sequence and the entire open reading frame (ORF)of CYK2 was amplified by PCR against yeast genomic DNA. Thisfragment was digested with PstI (site included in the 5' primer)and BamHI (site included in the 3' primer immediately followingthe coding sequence for the last amino acid), and then clonedbetween the corresponding sites in pRL72 (a COOH-terminal myc-taggingvector) and pRL73 (a COOH-terminal green fluorescent protein[GFP]-tagging vector) (Lippincott and Li, 1998) to yield pLP1and pLP2, respectively. pLP2 was digested with SalI and NotIand the fragment containing CYK2–GFP was cloned into theSalI and NotI sites of pRS313 to generate pLP3. The PstI/BamHIfragment used to generate pLP1 was also cloned into bluescriptSK at the same sites to yield pLP5. A CYK2 disruption plasmid,pLP6, was constructed by digesting pLP5 with BglII and StyI,removing 86% of the CYK2 ORF, blunting both ends, and ligatingthe vector fragment with the blunted HIS3 marker gene (Berben et al., 1991).To generate the plasmid that expresses CYK2 under the controlof the GAL1 promoter, CYK2 was amplified by PCR against genomicDNA with primers that included the 3' stop codon, but startedimmediately downstream of the ATG which follows an in-frameSalI site. This PCR fragment was cloned into pcDNA3.1/v5/His-TOPO(Invitrogen, Carlsbad, CA) to generate pLP21. pLP21 was subsequentlydigested with SalI, and the CYK2 fragment was ligated into the SalI site of pRL62, a pRS306 based vector for NH₂-terminalhemagglutinin (HA) tagging of genes under the GAL1 promoter.Orientation was determined so that the second amino acid ofCyk2 is directly downstream and in-frame with the HA tag.

To construct the septin GFP-expressing plasmid, a DNA fragmentcontaining a 242-bp 5' sequence and the entire ORF of CDC12was amplified by PCR against yeast genomic DNA. This fragmentwas digested with PstI (site included in the 5' primer) andBamHI (site included in the 3' primer immediately followingthe coding sequence for the last amino acid), and cloned betweenthe corresponding sites in pRL73 to yield pLP17.

To construct the MYO1 disruption plasmid, bluescript SK wasdouble digested with HindIII and EcoRI, blunted, and then religatedto generate pLP10-5. A DNA fragment containing a 226-bp 5'sequence and the entire ORF of MYO1 was amplified by PCR againstyeast genomic DNA. This fragment was digested with PstI (siteincluded in the 5' primer) and BamHI (site included in the3' primer immediately following the coding sequence for thelast amino acid), and then cloned between the correspondingsites in pLP10-5 to yield pLP11. pLP11 was subsequently digestedwith EcoRV to remove 5,111 bp (88%) of the MYO1 ORF which wasreplaced by ligating in the HIS3 marker gene to generate pRL185.

Strain Construction
All strains used in this study are listed in Table I. To disruptCYK2, pLP6 was digested with EcoRI and XbaI, and then transformedinto RLY138 and RLY323 to yield RLY392 and RLY416, respectively.RLY292, the haploid S288c background ${Delta}$ cyk2 strain, was generatedfrom tetrad dissection of RLY392. CYK2 gene disruption was confirmedby PCR analysis of the genomic DNA prepared from the His⁺ coloniesusing a 5' primer corresponding to a sequence within the CYK2coding region that is replaced by the HIS3 marker gene in thedisruption allele and a 3' primer corresponding to a sequence3' to the CYK2 coding region that is not present in pLP6 (datanot shown). To generate a strain expressing CYK2 under the control of the GAL1 promoter (RLY292), pLP23 was linearizedwith XcmI and integrated into the URA3 locus of RLY261. Expressionand galactose-specific induction of HA-Cyk2p was confirmed byimmunoblot analysis (data not shown). RLY332 (the ${Delta}$ myo1 strain)was generated by digesting pRL185 with BamHI and XhoI, andthen transforming into the haploid strain RLY8. MYO1 gene disruptionwas confirmed by PCR analysis of the genomic DNA prepared fromthe His⁺ colonies using a 5' primer corresponding to a sequencewithin the MYO1 coding region that is replaced by the HIS3marker gene in the disruption allele and a 3' primer correspondingto a sequence 3' to the MYO1 coding region that is not presentin pRL185 (data not shown). The parental strain of RLY519 contains ${Delta}$ arp2::TRP1 and ARP2–GFP. ARP2–GFP is a functionalprotein as it complements the ${Delta}$ arp2::TRP1 deficiency (Winter,D., and R. Li, unpublished result). A strain containing tubulin-GFPand Cyk2–GFP was generated by transforming pLP2 intoRLY392. The resulting strain was then sporulated and dissectedto generate a strain in which the only copy of Cyk2 was Cyk2–GFP.This strain was then transformed with Stu1-linearized pAFS125(Straight et al., 1997) to generate RLY620.

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Table I Yeast Strains

Zymolyase Treatment
For the experiments shown in Fig. 5, C and D and Fig. 7 E, 5ml of cells were fixed by the addition of 37% formaldehydeto 5% final concentration and incubation at room temperaturefor 1 h with gentle agitation, washed twice with PBS and oncewith 1 M sorbitol in 50 mM KPO₄, pH 7.5. Cells were incubatedwith 0.2 mg/ml zymolyase 20T (Seikagaku Corp., Tokyo, Japan)in the above sorbitol buffer containing 2 mM DTT for 10 minat 37°C. Typically >90% of the treated cells lost therefractile appearance when observed under a Nikon Labophot-2microscope with a Plan 40 0.5 ELWD objective (Melville, NY),indicating that cell wall removal was efficient.

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Figure 5 Cyk2p is important for cytokinesis. (A) Tetrad analysis of diploid strains heterozygous for the ${Delta}$ cyk2 mutation (left panels: RLY392, W303 background; right panels: RLY416, S288c background). Tetrads were dissected and incubated at either 23°, 30°, or 37°C as indicated. (B) Two examples of ${Delta}$ cyk2 microcolonies which were unable to grow into visible colonies. (C and D) RLY292 ( ${Delta}$ cyk2) or RLY8 (wild-type) cells were grown overnight at 23°C and then shifted to 37°C for 8 h. Samples were taken and fixed every 2 h. The cells were either treated with zymolyase and counted on a hemacytometer as described in Materials and Methods (C) or subjected to OD₆₀₀ measurements (D). The resultant cell concentration or OD₆₀₀at each time point was divided by that at time 0 to give relative cell number or relative OD₆₀₀, respectively, and plotted over time. (E and F) RLY292 (top panels in E and F) or RLY8 (bottom panels in E) cells were grown overnight at 23°C, shifted to 37°C for 4 h, and then stained with DiI (E) or calcofluor (F) as described in Materials and Methods. Optical sections were taken using wide-field deconvolution three-dimensional microscopy (Agard et al., 1989). The top panels (E) are a series of 400-nm sections, the bottom panels in E and those in F are a series of 200-nm sections. (G) RLY292 cells were grown overnight in YPD at 23°C and then shifted to 37°C. Samples were fixed before the shift and at 4 h after the shift and stained with rhodamine-phalloidin as described in Materials and Methods. Bar, 10 µm.

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Figure 7 Overexpression of Cyk2p results in an aberrant distribution of the septins and a cytokinesis defect. (A, panel a) RLY536 (GAL1-HA-CYK2) or RLY569 (vector control) cells were struck out on either YPD or YPG and grown for 3 d at 23°C. (A, panel b) RLY536 was grown overnight at 23°C in YP-raffinose media. Galactose was added to 2% at time 0 and cells were allowed to grow another 15 h at 23°C. Samples were taken every 2 h up to 8 h and then again at 15 h and fixed. Shown is a phase image of cells from the 8-h timepoint. (B) Cells from the 4- and 15-h time points were stained with rhodamine-phalloidin as described in Materials and Methods. (C) The fixed RLY536 cells from the 8-h time point were double stained with either mouse anti-HA (top) or rabbit anti-Cdc3 (bottom) antibodies. (D) The RLY536 (left) and RLY569 (right) cells from each time point of the experiment in A, panel b were counted by the following method: fields of cells were first counted in the phase channel; the number of cells within the same field that had a septin ring around the bud neck or aberrant septin filaments were then counted in the fluorescent channel. The resultant numbers from the fluorescent channel were divided by the total cell number from the phase channel to give percent cells with septin rings or with aberrant septin filaments. These numbers were plotted as a function of time as shown (200–500 cells were counted for each sample). (E) A sample of the RLY536 and RLY569 cells from each time point of the experiment in A, panel b were treated with zymolyase as described in Materials and Methods and counted on a hemacytometer. The resultant cell concentration at each time point was divided by that at time 0 to give relative cell number and then plotted over time. (F) Representative images of GFP fluorescence in RLY476 (Cdc12-GFP–expressing, ${Delta}$ cyk2) cells were captured using the setup for time-lapse imaging as described in Materials and Methods. Bars, 10 µm.

Fluorescence Staining of Yeast Cells
Cells grown in YPD were fixed directly in growth media by additionof 37% formaldehyde to 5% final concentration and incubationat room temperature for 1 h with gentle agitation. Cells grownin synthetic media were shifted to growth in YPD for 1 h beforefixation because the low pH of the synthetic media resultedin poor fixation. Phalloidin staining was performed as described(Guthrie and Fink, 1991) except that the cells were treatedwith zymolyase to remove the cell wall after fixation in allof the experiments in this study with the exception of thecells from the 4-h time point in Fig. 7 B (in order to showcell morphology). Immunofluorescent staining using either mouseanti-myc (Evan et al., 1985), rabbit anti-Cdc3 (Frazier et al., 1998),or mouse anti-HA primary antibodies and FITC-conjugated orrhodamine-conjugated secondary antibodies (Jackson ImmunoResearch,West Grove, PA) was carried out as described (Drubin et al., 1988).To double stain cells with rhodamine-phalloidin and an antibody,the methanol/acetone treatment was omitted from the immunofluorescencestaining procedure. After incubation with the secondary antibody,the cells were incubated with 0.05 µM rhodamine-phalloidin (Molecular Probes, Eugene, OR) for 20–30 min in the dark.The cells were visualized on a Zeiss Axiophot microscope witha HB100 W/Z high-pressure mercury lamp and a Zeiss 100x PlanNeofluar oil immersion objective (Carl Zeiss, Thornwood, NY).Image acquisition was carried out using Northern Exposure (Phase3 Imaging Systems, Milford, MA).

DiI and Calcofluor Staining
DiI was purchased from Molecular Probes and a 1-mg/ml stocksolution was made in 95% EtOH. 1 ml of cells at a density ofOD₆₀₀ $~$ 0.3 were pelleted by centrifugation and resuspended gentlyin 100 µl of DiI stock solution. Cells were incubatedfor 20 min at 37°C, washed three times with H₂O, and thenviewed using a rhodamine filter set. Calcofluor staining wasdone essentially as previously described (Pringle, 1991). Afluorescent brightener 28 (Sigma, St. Louis, MO) stock solutionwas prepared in H₂O at 1 mg/ml. Cell pellets prepared as abovewere resuspended in 100 µl stock solution, incubated5 min at room temperature, washed three times with H₂O andviewed using a 4',6-diamidino-2-phenylindole (DAPI) filter set. Serial sections were obtained using wide-field deconvolutionthree-dimensional microscopy (Agard et al., 1989).

Measurements of Fluorescence Intensity
The average maximum fluorescence intensities presented in Fig.6 were measured in the following manner: the two dots of fluorescenceat the bud neck represent a perpendicular section through theMyo1–GFP ring. WinView 32 software (Princeton Instruments,Trenton, NJ) was used to measure the brightest pixels in bothdots (left and right sides of the ring). The brightest pixelswere averaged together and the background was subtracted. Thebackground was measured by averaging over 20 separate pixelvalues located away from the bud neck at each time point. Inthe case of asymmetrical Myo1–GFP ring contractions,the brightest pixels were not averaged and each dot was consideredseparately. Intensity profiles (see Fig. 6 C) were measuredusing custom software developed for WinView 1.6.2 (courtesyof A. Mallavarapu, Harvard Medical School, Boston, MA) in thefollowing manner: a line was drawn through the Myo1–GFPring of a cell image obtained as described below. The intensity values through the thickness of the line (two pixels) wereaveraged and plotted against the distance of the line. Theline drawn through the wild-type cell neck was 15 pixels (1.23µm) long and the line drawn through the ${Delta}$ cyk2 cell neckwas 30 pixels (2.46 µm) long.

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Figure 6 Abnormal contraction of the Myo1 ring in ${Delta}$ CTK2 cells. (A) RLY534 (panel a, Myo1-GFP–expressing, wild-type) or RLY533 (panel b, Myo1-GFP–expressing, ${Delta}$ cyk2) cells were observed by video microscopy as described in Materials and Methods. (panel a) Time-lapse sequence in a typical wild-type cell; (panel b) time-lapse sequence in a typical ${Delta}$ cyk2 cell whose Myo1 ring appeared symmetrical. (B) The diameter and average maximum intensity of Myo1 rings in RLY534 and RLY533 cells were measured using WinView 32 software (Princeton Instruments) as described in Materials and Methods. The measurements were then plotted as a function of time. (panels a and b) show the results for two typical RLY534 cells and (panels c and d) for two typical RLY533 cells. (C) A line was drawn through the Myo1 ring of a typical RLY534 (left) or RLY533 (right) cell at each of the indicated time points and pixel intensity values along the line were obtained as described in Materials and Methods. The measurements were then plotted against distance along the line. (D) A typical RLY533 cell whose Myo1 ring appeared asymmetrical. Bars, 10 µm.

Time-Lapse Imaging of Cells Expressing GFP-tagged Proteins
Strains expressing GFP-tagged proteins were grown overnightin selective media and placed on agarose pads essentially asdescribed (Waddle et al., 1996). Living cells were imaged atroom temperature on an Eclipse E600 microscope with a 100/1.40oil differential-interference contrast objective (Nikon). Imagesof Myo1–GFP were collected through a neutral density filter of value 8 every 30 s with 0.8 s of exposure to fluorescentlight filtered through a EXHQ450/50 DM480 LP/BA465LP GFP filterset (Chroma, Brattleboro, VT) using a cooled RTE/CCD 782Y Interlinecamera (Princeton Instruments). The shutter was controlled automaticallyusing a D122 shutter driver (UniBlitz, Rochester, NY) and WinView1.6.2 software (Princeton Instruments) with custom software(courtesy of A. Mallavarapu). Images of Cyk2–GFP werecollected using the same system, every 30 s without a neutraldensity filter and 0.05-s exposures. Images of Cdc12–GFPwere collected using the same setup every 30 s with a neutraldensity filter of value 4 and a 0.1-s exposure. Cells imagedby the above method usually remain healthy for more than onecell cycle as judged by the rate of bud appearance or growth.Images of Arp2–GFP and Cyk2–GFP in the same cellwere also collected every 30 s using the same setup with aneutral density filter of value 8 and a 0.5-s exposure.

Images of tubulin–GFP and Cyk2–GFP in the same cellwere collected at room temperature using a Zeiss Axiovert 100TV microscope through a neutral density filter of value 3 every30 s with 0.5-s exposure to fluorescent light filtered througha EXHQ450/50 DM480 LP/BA465LP GFP filter set (Chroma) usinga cooled RTE/CCD 782Y Interline camera (Princeton Instruments).Seven z-sections were acquired at each timepoint through a 3-µm range using a Ludl z-motor controlled by PHAT-Lapsesoftware (courtesy of A. Mallavarapu) for WinView 32 (PrincetonInstruments) and then flattened into a single image using PHAT-Lapsesoftware.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

We had previously shown that Saccharomyces cerevisiae containsan actomyosin-based ring at the bud neck which is importantfor cytokinesis (Lippincott and Li, 1998). This ring undergoesa contraction-like size change during cytokinesis. For convenience,we will refer to this event as contraction throughout the papereven though rigorous tests of the actual mechanism are stilllacking. To further understand the regulation and mechanismof function of this ring, it is important to identify additionalring components. To this effect we cloned an ORF found in theyeast genomic database whose predicted amino acid sequence shows significant similarity to the S. pombe cdc15 protein (Fankhauser et al., 1995). cdc15 is a component of the medialring in fission yeast and is required for the completion ofcytokinesis and accumulation of actin patches to the septum(Fankhauser et al., 1995; Balasubramanian et al., 1998). Wehave named the cdc15 homologue of budding yeast Cyk2 (for cytokinesis2) because of its involvement in cytokinesis (see below). Asequence alignment between this ORF and cdc15 was previouslypublished (Fankhauser et al., 1995) and showed that the S.cerevisiae cdc15-like protein also possesses a potential coiled-coilregion and a COOH-terminal SH3 domain.

Cyk2p Shuttles between the Septin and the Actomyosin Rings
To test whether Cyk2p is indeed a component of the actomyosinring in budding yeast cells, we tagged the protein at the COOHterminus with either six myc epitopes or GFP. Both of theseconstructs complemented the null phenotypes (see below and datanot shown). Cyk2p was found to localize to the mother–budjunction, usually appearing as a double ring around the neck.In most cells, the Cyk2 double ring colocalized with the septindouble ring (Fig. 1 A, panel a), but in a small fraction ofanaphase cells, Cyk2p localizes to a single ring "sandwiched"between the septin rings (Fig. 1 A, panel b). Because the actomyosin ring usually appears as a single ring in between the septin rings (Lippincott and Li, 1998), we examined whether Cyk2psometimes colocalizes with the actin ring. Double stainingof Cyk2p and actin showed that in anaphase cells where actinfilaments had been recruited to the Myo1 ring, the Cyk2 ringoften appeared as a single ring colocalizing with the actinring (Fig. 1 A, panel c).

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Figure 1 Intracellular localization of Cyk2p. (A) RLY294 (Cyk2-myc–expressing) cells were fixed and double stained with mouse anti-myc and either rabbit anti-Cdc3p (panels a and b) or rhodamine-phalloidin (panel c, two examples shown). (B) RLY286 (Cyk2-GFP–expressing) cells were observed by video microscopy as described in Materials and Methods. Arrow in the 83' panel, a new bud. Bars, 10 µm.

The above immunolocalization results suggest that Cyk2p shiftsfrom the septin rings to the actomyosin ring sometime duringanaphase. To further investigate this possibility, we examinedthe in vivo changes in Cyk2p localization by time-lapse videomicroscopy on living cells expressing Cyk2–GFP. The Cyk2–GFPring was found in cells with buds of all sizes (data not shown).Fig. 1 B shows a time-lapse sequence of Cyk2–GFP localizationduring one cell cycle. At time 0, Cyk2–GFP was foundto localize to a double ring at the neck of two large buddedcells. At 24' (top) and 50' (bottom) the Cyk2 double ringsappeared to have merged into a single ring. Within the nexttwo minutes, the single ring started to decrease in diameter(Fig. 1 B, 24–28', top; 50–54', bottom), similarto the contraction-like morphological change of the Myo1 ringobserved at cytokinesis (Lippincott and Li, 1998). In contrastto the Myo1 ring which shrinks to a single dot and then disappears,the Cyk2 fluorescence did not disappear, but spread out aroundthe neck area (Fig. 1 B, 30–36', top). This spreadingresulted in the reformation of a Cyk2 double ring, half ofwhich resided in the mother, and the other in the daughter(Fig. 1 B, 41', top). One of the Cyk2 rings extended on oneside toward the future bud site while it was disappearing fromthe old bud site (Fig. 1 B, 41–58', top), and eventuallyformed a new ring as the new bud grew out (83', arrow indicatesnew bud).

To further characterize the timing of Cyk2p localization tothe actomyosin ring with respect to spindle and actin dynamics,strains were constructed which coexpressed either Cyk2–GFPand tubulin–GFP or Cyk2–GFP and Arp2–GFP,a component of cortical actin patches. Fig. 2 A shows a time-lapsesequence which demonstrates that the Cyk2p double ring mergedto a single ring after the completion of spindle elongation(compare 14–22'). The contraction of the Cyk2 single ringfollows (Fig. 2 A, 26–32'), during which the spindlebreaks down. Fig. 2 B shows a time-lapse sequence which demonstratesthat actin patches accumulate at the bud neck at the end ofCyk2–GFP ring contraction (compare actin patch distributionin frames 11–15' with that in frames 15.5' and 17').

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Figure 2 The dynamics of the Cyk2 ring in relation to those of the spindle and cortical actin patches. RLY620 (tubulin-GFP and Cyk2-GFP–expressing) cells (A) or RLY519 (Arp2–GFP and Cyk2-GFP–expressing) cells (B) were observed by video microscopy as described in Materials and Methods. Bars, 10 µm.

The Septins Are Not Components of the Contractile Ring
To differentiate the localization of Cyk2p from that of the septins, we also examined the in vivo changes in septin localizationin cells expressing the COOH-terminal GFP-tagged Cdc12p. TheCdc12–GFP construct complements the null (data not shown)and shows a Cdc12 localization similar to that described previouslyfor the septins (Haarer and Pringle, 1987). Time-lapse videomicroscopy of Cdc12- GFP–expressing cells revealed thatthe septin double rings did not merge into a single ring, butrather they moved further apart late in the cell cycle (Fig.3, 3–4'). The septin rings never shrank like the Cyk2or Myo1 ring, suggesting that they are not part of the contractileapparatus. Like Cyk2p, subsequent to cell separation individualseptin rings were seen to elongate at one end, mark the newbud site and completely delocalize from the old site as thenew bud emerged (Fig. 3, 17–29', bottom ring). Theseobservations suggest that the septin rings are structurallydistinct from the actomyosin ring and that the merging of theCyk2 double ring to a single ring is not a non-specific consequenceof tightening of the neck cortex during cytokinesis.

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Figure 3 The in vivo dynamics of the septin rings. RLY370 (Cdc12-GFP–expressing) cells were observed by video microscopy as described in Materials and Methods. Bar, 10 µm.

The Cyk2 Ring Is Disrupted by a Septin Mutation
Because Cyk2p colocalizes with the septins in the early partof the cell cycle, the possibility exists that septins may be required for the assembly and maintenance of the Cyk2 ring.To test this possibility, the Cyk2-myc–expressing constructwas introduced into a cdc12-6 (Kim et al., 1991) mutant strain.The cells were cultured at 23°C, and then shifted to growthat 37°C, the nonpermissive temperature. As expected, theseptin ring was lost in >99% of the mutant cells 30 min afterthe temperature shift (Table II). The Cyk2 ring was also absentin >99% of these cells. There was only a small drop in thefraction of the septin ring-containing or Cyk2 ring-containingcells in the wild-type culture shifted to 37°C (Table II),suggesting that the disappearance of the septin and Cyk2p ringsin the mutant culture was not simply due to the temperatureshift. This result suggests that the septins play an importantrole in the assembly and maintenance of the Cyk2 ring. Cyk2p, however, is not required for septin ring localization (see below).

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Table II The Cyk2 Ring Is Abolished by a Septin Mutation

The Effect of MYO1 Gene Disruption on the Dynamics of the Cyk2-containing Ring
Because the Cyk2 ring merges with the actomyosin ring and exhibitsa contraction-like size change late in the cell cycle, we testedwhether the dynamics of the Cyk2-containing ring are dependenton Myo1p. The Cyk2–GFP construct was introduced intoa ${Delta}$ myo1 strain. The ${Delta}$ myo1 cells are viable but exhibit severedefects in cytokinesis and colony growth (Watts et al., 1987)(Lippincott, J., and R. Li, unpublished result). Cyk2p is ableto localize properly in ${Delta}$ myo1 cells through most of the cellcycle, indicating that the normal localization of Cyk2p is notdependent on Myo1p (Fig. 4, 20' and data not shown). However,in large-budded cells, after the Cyk2 double rings merged into a single ring, the ring broke into small pieces without undergoing the contraction-like size change (Fig. 4, 32–43'). This result suggests that Myo1p is required for maintainingthe integrity and/or contraction of the Cyk2 ring during cytokinesis.

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Figure 4 The in vivo dynamics of Cyk2p-containing structure in ${Delta}$ myo1 cells. RLY414 (Cyk2-GFP–expressing, ${Delta}$ myo1) cells were observed by video microscopy as described in Materials and Methods. Bar, 10 µm.

CYK2 Gene Disruption Results in a Cytokinesis Defect
The results described above indicate that Cyk2p is a componentof the bud neck and is intimately associated with the actomyosinring during cytokinesis. To further investigate the involvementof Cyk2p in cytokinesis, we constructed a null allele of CYK2by deleting 86% of the CYK2 ORF. Because the phenotypes ofmany cytoskeletal mutants vary significantly between differentgenetic backgrounds, we disrupted the CYK2 gene in two commonly studied strain backgrounds: W303 and S288c. Tetrad analysisof a heterozygous diploid ${Delta}$ cyk2 strain in the W303 genetic backgroundwas performed. When the tetrads were grown at room temperature( $~$ 23°C), 45% of the ${Delta}$ cyk2 spores were able to grow into colonies,but the growth of these colonies was much slower than thatof the wild-type spores (Fig. 5 A, top left, two large coloniesin each tetrad were His^– and wild type). When the tetradswere dissected and incubated at 30°C, 79 out of 80 ${Delta}$ cyk2spores were incapable of small colony formation (Fig. 5 A, bottomleft). Microscopic analysis of the noncolony-forming sporesrevealed that these ${Delta}$ cyk2 spores were able to germinate and proceed through a number of cell cycles before lysing as a small chain (Fig. 5 B). Many of the cells in the viable colonieswere also in chains or clumps.

It is worth noting that these viable ${Delta}$ cyk2 colonies greatlyimproved their growth rate and cell morphology after severalrounds of streaking on YPD plates, suggesting that these cellssomehow adapted or accumulated suppressor mutations. To distinguishbetween these possibilities, a growth-improved ${Delta}$ cyk2 strain wasbackcrossed to the parental wild-type strain. From 12 tetrads,11 of the 24 (46%) ${Delta}$ cyk2 spores grew into colonies that werephenotypically indistinguishable from the growth-improved ${Delta}$ cyk2colonies. Of the remaining 13 ${Delta}$ cyk2 spores, six did not growinto visible colonies and seven grew into colonies that weremuch smaller than wild-type and contained cells with the chainmorphology. These results are consistent with a single, unlinked,suppressor mutation which greatly improves the growth of ${Delta}$ cyk2cells. No phenotype was observed for Cyk2⁺ cells that containedthis suppressor mutation. In the more robust S288c strain background, ${Delta}$ cyk2 spores were able to form colonies at 30°C but notat 37°C (Fig. 5 A, right), although chains or clumps ofcells exist in colonies grown at 30°C. The neck of ${Delta}$ cyk2cells are often two to three times as wide as the wild-typecells in both strain backgrounds (see Fig. 6). To avoid suppressormutations, we mostly worked with S288c colonies that freshly came from a tetrad plate cultured at room temperature.

The chains or clumps of cells that were seen in ${Delta}$ cyk2 coloniescould arise from either a cytokinesis defect or a cell separationdefect. To distinguish between these possibilities, both wild-typeand ${Delta}$ cyk2 cells in the S288c background were grown for 8 h at37°C and samples were taken and fixed every 2 h. Each samplewas treated with zymolyase to remove the cell wall and cellnumber per milliliter was determined using a hemacytometer.From the 4-h time point on, the ${Delta}$ cyk2 cell number did not significantly increase and the cells remained as clumps and chains after the zymolyase treatment, while the wild-type cell number increasedexponentially during this time frame (Fig. 5 C). The opticaldensity of the ${Delta}$ cyk2 culture increased at a wild-type rate indicatingthat the two cultures grew at approximately the same rate (Fig.5 D). Thus, ${Delta}$ cyk2 cells exhibit a cytokinesis defect definedby the criteria previously described (Hartwell, 1971).

A second experiment was performed to confirm that ${Delta}$ cyk2 cellsdisplay a cytokinesis defect at the nonpermissive temperature. ${Delta}$ cyk2 cells in the S288c background grown at room temperaturewere shifted to 37°C for 4 h and stained with either calcofluor(a chitin-specific fluorescent dye) or DiI (cytoplasmic membrane-specificfluorescent dye). The stained cells were observed by serial optical sectioning using wide-field deconvolution three-dimensionalmicroscopy (Agard et al., 1989). Fig. 5 E (top) shows a seriesof 400-nm sections through a typical clump of ${Delta}$ cyk2 cells afterDiI staining. By looking through the series it was clear thatthe cytoplasm is connected between all four cell bodies, whereasin a wild-type control cell that has completed cytokinesis,no cytoplasm connection was observed at any focal plane (Fig.5 E, bottom). Calcofluor staining of ${Delta}$ cyk2 cells confirmed thata septum had failed to form between two cell bodies beforethe next round of budding (Fig. 5 F).

Because the cdc15 mutation affects both the proper formationof the actin ring and the accumulation of actin patches atthe septum in S. pombe (Balasubramanian et al., 1998), we examinedactin structures in ${Delta}$ cyk2 cells (Fig. 5 G). S288c ${Delta}$ cyk2 cellswere grown at 23° and at 37°C for 4 h, fixed, and thenstained for F-actin with rhodamine-phalloidin. At both the permissiveand nonpermissive temperatures actin patches polarized properlyin small-budded cells and accumulated at the septum in dividingcells (Fig. 5 G, 23°C and 37°C, left panels). The cellin the latter panel has two buds, both of which have patchesaccumulated at the septum). Actin rings were also able to formin the ${Delta}$ cyk2 cells and are indistinguishable from those seenin wild-type cells (Fig. 5 G, 23°C and 37°C, rightpanels). Therefore, unlike cdc15p, Cyk2p does not appear tobe required for the normal distribution of actin filaments inthe cell. The Myo1 ring also forms properly in ${Delta}$ cyk2 cells at both the permissive (Fig. 6) and nonpermissive temperature(data not shown), suggesting that Cyk2p is not required forthe formation of the contractile ring.

Cyk2p Is Important for the Stabilization of Myo1 Ring during Contraction
Because Cyk2p appears to associate with the actomyosin ringduring cytokinesis, it is possible that Cyk2p is important forthe contraction of the ring. To test this hypothesis, we introducedMyo1–GFP into the S288c or W303 diploid strains heterozygousfor the ${Delta}$ cyk2 mutation and dissected tetrads. Movies were madeof Myo1–GFP in Cyk2-null cells as soon as possible aftertetrad dissection (2 d) to avoid suppressor accumulation. Fig.6 A, panel a shows Myo1 ring contraction in a typical wild-typecell. The ring appeared to shrink evenly down to a dot in themiddle of the bud neck without losing fluorescent intensity(Fig. 6 A, panel a, 0–3'). The Myo1 ring was also ableto contract in the absence of Cyk2p, but the contraction wasclearly aberrant. In contrast to the Myo1 rings observed inwild-type cells, the Myo1 ring in ${Delta}$ cyk2 cells (all cells observedin both backgrounds) appeared to lose width and intensity during contraction (Fig. 6 A, panel b and Fig. 6 D).

Measurements of the maximum fluorescence intensity of the Myo1ring, which approximates the intensity of the pixel in focus,were taken during Myo1 ring contraction in both wild-type and ${Delta}$ cyk2 cells. In the wild-type cells the intensity of the Myo1ring increased as the ring contracted and then decreased drasticallyafter contraction was complete (Fig. 6 B, panels a and b aretwo typical wild-type cells). In contrast, the intensity ofthe Myo1 ring in ${Delta}$ cyk2 cells decreased steadily and rapidlyas soon as contraction started (Fig. 6 B, panels c and d aretwo typical examples). Another way to quantify the differencebetween the Myo1 ring in wild-type and in ${Delta}$ cyk2 cells was toobtain intensity profiles along a line cutting across the ringand bud neck. The intensity profile of a typical wild-typecell demonstrates that the Myo1 ring maintained intensity asthe two fluorescence peaks at the two sides of the neck moved closer to each other (Fig. 6 C, WT, 0–4'). In ${Delta}$ cyk2 cells, however, the Myo1 ring decreases in intensity as the fluorescencepeaks move together (Fig. 6 C, ${Delta}$ cyk2, 0–6'). The abilityto observe two fluorescence peaks moving together in ${Delta}$ cyk2 cellsalso suggests that the narrowing of the ring results from contractionrather than ring subunits diffusing away.

The duration of contraction in the ${Delta}$ cyk2 cells was roughly thesame as that in the wild-type cells. Because the necks of ${Delta}$ cyk2cells are up to three times as large in diameter as the wild-typecells, the rate of contraction in the former must be fasterthan in the latter. Indeed, the rate of contraction was estimatedto be 0.26 µm/min (eight cells averaged, ${sigma}$ _n-1 = 0.119)in ${Delta}$ cyk2 cells and 0.10 µm/min (eight cells averaged, ${sigma}$ _n-1 = 0.039) in the wild-type cells. Some ${Delta}$ cyk2 cells had neckssimilar in size to those in wild-type cells, yet ring contractionwas still faster in the mutant cells (data not shown), indicatingthat the faster contraction seen in ${Delta}$ cyk2 cells was not due tothe larger necks observed. Unlike in the wild-type cells, in ${Delta}$ cyk2 cells after contraction, it was often possible to seevesicle movement through the bud neck by Nomarski imaging indicatingthat cytokinesis failed to occur. These results suggest that Cyk2p is important for maintaining the stability of the Myo1ring during contraction, and this defect is likely to be thecause of the cytokinesis failure in ${Delta}$ cyk2 cells.

In some ${Delta}$ cyk2 cells (seven out of 10 cells observed in the S288cbackground, but none in the W303 background), only one of thedots moved and the intensity of the moving dot faded much quickerthan the opposite side of the ring (Fig. 6 D), suggesting thatdisassembly occurred asymmetrically. Because the fluorescencepeak was abruptly lost on one side, it was difficult to distinguishwhether the shortening of the Myo1–GFP "band" from oneside was due to asymmetrical contraction or asymmetrical disassembly.

Cyk2p Plays a Role in Regulating Septin Localization
In S. pombe, overexpression of cdc15p results in the formationof actin rings in G2 arrested cells and prolonged overexpressionof cdc15p inhibits actin ring formation and blocks septation(Fankhauser et al., 1995). To examine the effect of Cyk2p overexpression,we constructed a strain carrying a single integrated copy ofCYK2 tagged with hemagglutinin (HA) epitope under the controlof the galactose inducible GAL1 promoter. Overexpression ofCyk2p is lethal as cells containing this construct grow on glucosebut not galactose-containing media (Fig. 7 A, panel a). This detrimental effect was not due to the HA tag because the vectoralone did not affect growth on galactose media and the HA-Cyk2pcomplements the null mutation when expressed under the CYK2promoter (data not shown). Cells overexpressing Cyk2p adoptedchain-like morphology and contained long hyperpolarized buds(Fig. 7 A, panel b) similar to those seen in septin mutants(Longtine et al., 1996).

To examine the effect of Cyk2p overexpression on actin structures,cells were grown in the presence of galactose for up to 15h and stained for actin with rhodamine-phalloidin. At time 0,cells contained normal actin structures (data not shown). By4 h, many cells became hyperpolarized with elongated buds andactin patches were concentrated at the tips of hyperpolarizedbuds (Fig. 7 B, 4 hr, arrowhead indicates elongated bud). Actinrings were not observed in preanaphase cells, suggesting thatunlike cdc15 in S. pombe, overexpression of Cyk2p does notinduce premature actin ring formation (data not shown). After15 h, however, F-actin aggregates were seen at the bud neckin a small population of cells ( $~$ 5%) (Fig 7 B, 15 h) and well-organizedactin rings were not observed. Thus, prolonged overexpressionof Cyk2p may have a similar effect on actin ring formation asseen with prolonged overexpression of cdc15p in S. pombe.

Because the cells containing overexpressed Cyk2p exhibit a morphologytypical of septin mutants, we determined whether septin organizationwas affected by Cyk2p overexpression. Cells were grown in galactose-containing media for various amounts of time were fixed and stained forseptins (Cdc3) and HA-Cyk2p. Cells overexpressing Cyk2p for8 h did not contain normal septin rings localized at the budneck. Long aberrant septin filaments were seen in most of theCyk2p overexpressing cells (Fig 7 C, bottom), but rarely incells containing vector alone (data not shown). Some of theseaberrant septin filaments clearly contained HA-Cyk2 (Fig. 7C, top, arrowheads in left panel indicate faint Cyk2p filaments).Fig. 7 D shows that the percentage of cells containing aberrantfilaments increased proportionally to the number of cells thathad lost septin rings from the bud neck. To quantify the apparentcytokinesis defect, the fixed cells from each time point wereremoved of the cell wall by zymolyase treatment and the resultingspheroplast concentration was determined by cell counting.Although the cell number of the wild type increased exponentially,the cell number of the Cyk2p overexpressing cells plateauedat 4 h, the same time point when most of the cells had lostthe septin ring from the bud neck (Fig. 7 E). This result suggeststhat overexpression of Cyk2p results in a loss of septin localizationfrom the bud neck which correlates with an inability to carryout cytokinesis. The appearance of the aberrant septin filamentsmay be a consequence of the loss of the normal septin structures(see Discussion).

Consistent with an ability of Cyk2 to delocalize the septins,in $~$ 50% of the ${Delta}$ cyk2 cells that expressed Cdc12– GFP, theseptin rings were formed at the new bud neck without delocalizingfrom the old bud neck, resulting in chains of cells that containedmultiple septin rings (Fig. 7 F).

Discussion

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Cyk2p Shuttles between the Septin Ring and the Actomyosin Ring
In this paper, we first described time-lapse analysis of the in vivo dynamics of Cyk2p localization in comparison with those of the septins and Myo1p using strains expressing GFP-taggedproteins. Fig. 8 A depicts the localization pattern of thesethree proteins before (top), during (middle), and after (bottom)cytokinesis. The Cyk2p-containing rings appear indistinguishablefrom the septin rings through most of the cell cycle, but justbefore cytokinesis, the Cyk2 double rings merge into a singlering that coincides with the Myo1p-containing ring. The Cyk2single ring then shrinks into a bright dot, suggesting thatit is part of the actomyosin contractile ring during cytokinesis.The septins, on the other hand, maintain the appearance ofa pair of rings with the same diameter, but they grew furtherapart around the time of cytokinesis. Although Myo1p disappearsrapidly from the neck region after contraction, Cyk2p redistributesback to two faint rings, whose appearance and location are againindistinguishable from those of the septin rings. At the beginningof the next cell cycle, both the Cyk2 and the septin ringsmigrate laterally (for axially budding cells) to the incipientbud site by an unknown mechanism.

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Figure 8 (A) A schematic comparison of changes in the morphology of the rings that contain septin, Myo1p, or Cyk2p before (top), during (middle), and after (bottom) cytokinesis. (B) A model explaining the role of Cyk2p during the contraction of the actomyosin ring. In wild-type cells (left), the cell cycle signal for cytokinesis triggers the solation of the actomyosin ring as well as the association of Cyk2p with actomyosin ring. Effective contraction and completion of cytokinesis result from a balance between the solation activity and the Cyk2p-dependent stabilization of the ring. In ${Delta}$ cyk2 cells (right), the solation is not balanced by the Cyk2p-dependent stabilization, leading to aberrant and ineffective contraction and hence incomplete cytokinesis.

Further support of the ability of Cyk2p to associate with theseptins came from the observations that Cyk2p colocalizes withthe aberrant septin filaments which are induced by Cyk2p overexpressionand do not contain Myo1p or actin (data not shown), and thatthe localization of Cyk2p is dependent on the septins (TableII). The conclusion that Cyk2p "hops" onto the Myo1 ring atcytokinesis is also supported by the finding that in ${Delta}$ myo1 cells,the Cyk2 ring forms and maintains a normal morphology until the end of the cell cycle when it abruptly breaks, suggestingthat its integrity is dependent on Myo1p only at that point.The septin-containing structure has distinct dynamic behaviorsfrom the actomyosin ring. Some interaction must occur betweenthe two structures because the septins are required for themaintenance of the actomyosin ring (Lippincott and Li, 1998)and because the dynamics of the two ring structures are likelyto be coordinated during cytokinesis. Cyk2p, which seems totransit between the two structures, could mediate the communicationbetween the septins and the actomyosin ring. Alternatively,Cyk2p could have two independent functions when associated with each structure. We have noticed that even small-budded ${Delta}$ cyk2 cells have abnormally wide necks (data not shown). Mutationsin the septins and Myo1p also give rise to cells with widebud necks (Flescher et al., 1993) (Lippincott, J., and R. Li,unpublished result). It is possible that Cyk2p, along withMyo1p and the septins, all localized at the incipient bud site,have an important structural role in determining the neck sizeearly in the cell cycle.

A Role for Cyk2p in Stabilizing the Myo1 Ring during Contraction
Phenotypic analysis of CYK2-disrupted cells showed that Cyk2pplays an important, although not essential, role in cytokinesis,consistent with its localization at the bud neck. We did notobserve any defect in the localization of actin or Myo1p totheir destined structures in ${Delta}$ cyk2 cells, but a severe defectwas consistently observed during contraction of the Myo1 ring:although the brightness of the GFP– Myo1 fluorescenceis maintained in the wild-type cells, it starts to diminishas soon as contraction initiates in ${Delta}$ cyk2 cells. In some ofthe mutant cells observed, the fluorescence appears to diminishevenly in the ring, whereas in others the disassembly occursunevenly. It was also apparent in many of the cells observedthat cytokinesis was not accomplished after contraction.

The disassembly event was quantified by measuring the maximumfluorescence intensity of the GFP–Myo1 ring in cellswhere the disassembly occurred evenly in the ring. The maximumfluorescence intensity approximates the intensity of the pixelsin focus and reflects the concentration of Myo1p in the ring.In the wild-type cells, it seems that there are two phasesof fluorescence changes after the start of contraction: (a)a slight increase in fluorescence during contraction; and (b)a rapid loss of fluorescence after the ring becomes a dot (Fig.6 A, panel a). However, rapid disassembly must also be occurringduring the first phase, otherwise the intensity would haveincreased many fold since ring diameter decreased by approximatelysixfold during contraction. Careful measurements of contractilering volume have been made in Arbacia (sea urchin) eggs, whichled to the same conclusion that contraction must be accompaniedby disassembly (Schroeder, 1972).

The results discussed above may be in support of the solation–contractioncoupling model, first proposed based on studies in dictyosteliumextracts (Condeelis and Taylor, 1977; Taylor and Fechheimer, 1982).In this model, actin/ myosin structures are prevented from contractionby extensive cross-linking in these structures (gelation). Solationby either a decrease in actin filament lengths or a decreasein the extent of the cross-linking would reduce the resistanceagainst the sliding of actin and myosin II filaments and therebystimulate contraction. In support of this model, it was observedthat when fibroblast cells were treated with cytochalasin D,the stress fibers shorten rapidly, presumably by actomyosin-basedcontraction, with a concomitant loss of actin and myosin IIfrom the fibers (Taylor and Fechheimer, 1982). Quantitativeanalysis was also carried out using an in vitro system consistingof a gel of actin and myosin II. The rate of contraction ofthis gel was inversely related to the amount of filamin, anF-actin cross-linking protein, present in the gel (Janson et al., 1991;Kolega et al., 1991).

If the solation–contraction model is correct, it is notdifficult to predict that effective contraction, i.e., contraction that can pull a load such as the plasma membrane, must dependon a balance between solation and stabilization of the actomyosin-basedstructure (Fig. 8 B). Cyk2p may have a specialized role inthe stabilization of the actomyosin ring during contraction.Thus, in the absence of Cyk2p, solation could occur to a greaterextent, explaining the three times faster rate of contractionobserved in the mutant than in the wild type. However, the rapiddeterioration of the contractile ring could result in a lossof force and dissociation from the plasma membrane, explaining the frequent failure in cytokinesis. The cytokinesis defect of ${Delta}$ cyk2 cells is more severe at elevated temperatures. Thismay be because the inward pulling force generated by actinand myosin is opposed by the turgor pressure that drives cellsurface growth behind the actomyosin ring (Cosgrove, 1986;Bluemink and de Laat, 1973), and membrane trafficking occursat a faster rate at 37°C (Novick et al., 1980).

Cyk2 May Have a Separate Function in Regulating Septin Localization
The observation that Cyk2p intimately associates with the septinsby colocalization suggests that Cyk2p has an important interactionwith the septins. In ${Delta}$ cyk2 cells, the septins show normal distributionat the bud neck but exhibit a delay in delocalization from theold bud neck after the next round of budding. Therefore, Cyk2pmay play a role in delocalizing the septin ring. It is notclear, however, to what extent the delay in septin delocalizationcontributes to the cytokinesis defect. Consistent with an abilityto delocalize the septins from the bud neck, cells overexpressingCyk2p lose the septin rings from the bud neck but form longseptin filaments elsewhere in the cytoplasm. These aberrantseptin filaments could be formed as a default due to the inabilityto localize to the bud neck, or alternatively, they might bepromoted directly by the overexpressed Cyk2p. The former possibilitywould be more consistent with the defect in septin delocalizationin ${Delta}$ cyk2 cells and the result that Cyk2 rings are dependenton the septins. An ability of Cyk2p to remove septins fromthe bud neck must be tightly regulated, because Cyk2p colocalizeswith the septins at the bud neck through most of the cell cycle.The overexpressed Cyk2p might override this regulation anddisplace the septins from the bud neck at any point in thecell cycle.

Functional Comparison of Cyk2 Homologues
Fission yeast cells deficient in cdc15p, the S. pombe homologueof Cyk2p, exhibit impaired assembly of the medial ring (Fankhauser et al., 1995;Balasubramanian et al., 1998). It is possible that this defectshares the same mechanistic cause with the defect in Myo1 ringstability in ${Delta}$ cyk2 cells. In S. pombe, cdc15p colocalizes withthe actomyosin ring starting from early M phase, and thereforeit may be required for ring stabilization even before contraction. Cyk2p, on the other hand, colocalizes with the actomyosin ring late in the cell cycle and therefore may play a specializedrole in ring stabilization during contraction. At this point,it is not clear whether the effect of cdc15p or Cyk2p on thestability of the actomyosin ring is mediated through actinor myosin II. Consistent with an interaction with actin, extendedoverexpression of Cyk2p results in the formation of aberrantF-actin aggregates at the bud neck (Fig. 7 B, 15 hr), similarto those observed in S. pombe cells overexpressing cdc15p.A recent experiment showed that a cdc15 temperature sensitivemutant fails to accumulate actin patches at the septum afterincubation at the nonpermissive temperature (Balasubramanian et al., 1998).We did not, however, observe any defect in actin patch distributionin ${Delta}$ cyk2 cells. Thus, it is likely that Cyk2p and cdc15p havesome differences in function.

Recently, imp2p, a cdc15p homologue was cloned in fission yeast(Demeter and Sazer, 1998). Imp2 is associated with the contractilering in S. pombe. Interestingly, imp2p seems to be involvedin the destabilization of the medial ring during septation,whereas Cyk2p appears to be important for the stabilizationof the contractile ring (Demeter and Sazer, 1998).

PSTPIP, the mammalian homologue of Cyk2p, also localizes tothe cleavage furrow, but its role in cytokinesis has not beeninvestigated. PSTPIP has also been shown to localize to thecell cortex and stress fibers (Spencer et al., 1997). Becauseactin and myosin II are also present at the above locations,it is possible that PSTPIP has a general function in actomyosin-basedcontractility which is not restricted to cytokinesis in animalcells.

Acknowledgments

This work was supported by a Funds for Discovery Award and the award from the Giovanni Armenise-Harvard Foundation to R. Li.

Submitted: 14 August 1998

Revised: 28 October 1998

The authors are extremely grateful to A. Mallavarapu for providingcustom software and help with video microscopy. We thank C.Field (Harvard Medical School) and J. Frazier (University ofCalifornia, San Francisco, CA) for their gift of anti-Cdc3 antibodies,A. Straight (Harvard Medical School) for providing tubulin-GFP,D. Winter (Harvard Medical School) for providing Arp2–GFP,and J. Pringle (University of North Carolina, Chapel Hill,NC) for septin mutant strains. We are indebted to J. Swedlow(University of Dundee, Dundee, Scotland, UK), W. Prinz, and J. Yarrow (both from Harvard Medical School) for their helpwith three-dimensional deconvolution imaging and to S. Storms(Harvard Medical School) for computer assistance. We thankS. Shepard for preparation of media and solutions, and K. Shannon,D. Winter, T. Lechler, N. Tolliday, C. Field, A. Straight (allfrom Harvard Medical School), and F. Lippincott (Boston, MA)for support, thoughtful discussion, and critical reading of the manuscript.

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