Analysis of All Protein Phosphatase Genes in Aspergillus nidulans Identifies a New Mitotic Regulator, Fcp1

Reversible protein phosphorylation is an important regulatorymechanism of cell cycle control in which protein phosphatasescounteract the activities of protein kinases. In Aspergillusnidulans, 28 protein phosphatase catalytic subunit genes wereidentified. Systematic deletion analysis identified four essentialphosphatases and four required for normal growth. Conditionalalleles of these were generated using the alcA promoter. Thedeleted phosphatase strain collection and regulatable versionsof the essential and near-essential phosphatases provide animportant resource for further analysis of the role of reversibleprotein phosphorylation to the biology of A. nidulans. We furtherdemonstrate that nimT and bimG have essential functions requiredfor mitotic progression since their deletions led to classicalG₂- and M-phase arrest. Although not as obvious, cells withAnpphA and Annem1 deleted also have mitotic abnormalities. Oneof the essential phosphatases, the RNA polymerase II C-terminaldomain phosphatase Anfcp1, was further examined for potentialfunctions in mitosis because a temperature-sensitive Anfcp1allele was isolated in a genetic screen showing synthetic interactionwith the cdk1F mutation, a hyperactive mitotic kinase. The Anfcp1^tscdk1F double mutant had severe mitotic defects, including inabilityof nuclei to complete mitosis in a normal fashion. The severityof the Anfcp1^ts cdk1F mitotic phenotypes were far greater thaneither single mutant, confirming the synthetic nature of theirgenetic interaction. The mitotic defects of the Anfcp1^ts cdk1Fdouble mutant suggests a previously unrealized function forAnFCP1 in regulating mitotic progression, perhaps counteractingCdk1-mediated phosphorylation.

INTRODUCTION

Top

INTRODUCTION

In many cellular processes reversible phosphorylation/dephosphorylationreactions play important roles by regulating protein activityand subcellular localization. As enzymes counteracting the functionof protein kinases, protein phosphatases have been firmly establishedas key coordinators of diverse biological events. Three maincriteria are used to classify protein phosphatases: sequencehomology, structure, and catalytic mechanism concerning substratespecificity. According to these features, protein phosphatasesare divided into the three main groups: classical serine/threoninephosphatases, protein tyrosine phosphatases, and the aspartatebased catalysis protein phosphatase (reviewed in reference 33).

The classical Ser/Thr phosphatases can be further subdividedinto the phosphoprotein phosphatase (PPP) family and the proteinphosphatase Mg²⁺/Mn²⁺-dependent (PPM) family. All members ofthe PPP family share high sequence similarities and have incommon a conserved phosphoesterase catalytic motif (PP2Ac),although their biological functions range widely from mitoticregulation (PP1) (8), immune response (PP2B) (4), DNA damageresponse (PP4) (15), and blue-light signaling in plants (PP7)(32). PP2C type protein phosphatases make up the PPM familyand are characterized by structural similarity of their catalyticdomains to PPPs despite the lack of any sequence similarity(33).

The protein Tyr phosphatase (PTP) superfamily is distinguishedby its CX₅R catalytic signature motif shared by all of its members.It consists of the classical PTPs, the dual-specificity phosphatases(DSPs), the Cdc25 type phosphatases, and the low-molecular-weightphosphatases. The classical PTPs consist both of receptor andnonreceptor PTPs, with functions related to cell adhesion andcell-cell signaling. While the DSPs belong to the PTP superfamily,they can not only dephosphorylate tyrosine residues but alsoshow phosphatase activities toward Ser/Thr residues. Of theDSPs, the function of Cdc14 (mitotic exit) (56) and PTEN (PIP₃signaling) (17) are relatively well understood, while littleis known about many other members. The Cdc25 type phosphatasesare well known for their essential function in regulating mitoticentry via the activation of cyclin-dependent kinase 1 (Cdk1)(13). Little is known about the function of the low-molecular-weightphosphatases.

The aspartate-based catalysis phosphatases are defined by theshared signature catalytic motif of DXDXT/V (CPDs). Its foundingmember is the FCP1 phosphatase with an essential function incoordinating the phosphorylation status of the RNA polymeraseII largest subunit C-terminal domain (RNAP II CTD) and thusregulating the activity of the transcription machinery (24).

In addition to these main protein phosphatase families, SSU72and the tyrosine phosphatase families are considered separatetypes of protein phosphatases, although both share significantsequence similarities with the PTPs (12, 31).

Like many other biological events, numerous regulatory mechanismsconcerning the eukaryotic cell cycle have been shown to involvereversible protein phosphorylation/dephosphorylation. Duringmitosis, the function of protein kinases such as Cdk1, Aurora,NIMA, and Polo-like kinases are of critical importance for propermitotic progression (16, 30, 40). As enzymes counteracting theeffects of kinases, protein phosphatases have naturally beenconsidered as logical candidates to have important cell cyclefunctions as well. As of now, Cdc25 and Cdc14 of the PTP superfamilyand PP1 and PP2A of the classical Ser/Thr phosphatase familyare the protein phosphatases whose mitotic functions have beenmost studied.

Identified for its essential function in mitotic entry (9, 46),Cdc25 functions to activate Cdk1 by removal of the inhibitoryTyr15 phosphorylation of Cdk1. The activity and localizationof Cdc25 itself is regulated by phosphorylation as well. Ithas been shown that Cdc25 is activated by Cdk1 mediated phosphorylation,forming a positive-feedback loop to facilitate rapid entry intomitosis (18). Phosphorylation by Polo-like kinases is importantin determining the subcellular localization of Cdc25 (54).

The DSP family member Cdc14 is known mostly for its role ofregulating later stages of mitosis. In the budding yeast Saccharomycescerevisiae, Cdc14p remains sequestered in nucleoli during interphasebut is released in anaphase via the FEAR (for Cdc fourteen earlyanaphase release) and MEN (for mitotic exit network) signalingcascades. Once released Cdc14p localizes to the spindle andspindle pole body to promote mitotic exit by reversing the phosphorylationof mitotic proteins carried out by Cdks during earlier phasesof mitosis (53, 56). The first evidence for PP1 functioningin mitotic regulation were presented from genetic analysis inAspergillus nidulans and Schizosaccharomyces pombe showing thatPP1 was required for the completion of mitosis (6, 8, 37). Furtherstudies in Drosophila melanogaster confirmed the essential functionof PP1 in mitotic progression (2). Since the M-phase arrestphenotypes of different PP1 mutations in different organismsshow a high degree of heterogeneity, it is generally believedthat PP1 has multiple targets during mitosis, which is alsoconsistent with its diverse localization to chromatin, nuclearlamin, nucleolus, and spindle pole body during different stagesof mitosis (11, 55).

PP2A is another classical Ser/Thr phosphatase that has confirmedmitotic functions. Although (along with PP1) the mitotic functionof PP2A in S. pombe was identified as early as 1990 (23), studiesin recent years point to a specific role of PP2A in controllingsister chromatid cohesion by interacting with shugosin proteinsat the centromere (52).

In order to analyze the protein phosphatase genes in A. nidulansfor potential mitotic functions, we carried out a systematicgene deletion analysis of all protein phosphatase catalyticsubunit-encoding genes. In addition to this genomic approach,a novel genetic strategy, engaging the function of the mitotickinase Cdk1 (known as NimX^cdc2 in A. nidulans) (42), was setup in the form of a synthetic interaction screen to isolatemutations that, combined with a hyperactive cdk1F mutant (61),cause increased temperature sensitivity. This screen identifieda conditional mutant allele of the RNAP II CTD phosphatase,Anfcp1, and the function of this gene was examined for its potentialrole in mitosis in combination with regulated Cdk1 phosphorylation.

MATERIALS AND METHODS

Top

MATERIALS AND METHODS

General A. nidulans methodologies. Standard growth and classical genetic methodologies for A. nidulanswere in essence as previously described (44). A strain listis provided (see Table S1 in the supplemental material). Endogenousgene deletions and green fluorescent protein (GFP) tagging wascarried out as described previously (35, 59). Identificationand analysis of essential genes via heterokaryon rescue wascompleted according to the method described previously (41).

Genetic screen. For the genetic screen, A. nidulans strain FRY24 was used inwhich a nimX^CDK1F mutant allele had been inserted at the chromosomallocus of nimX^CDK1 to form a tandem repeat of the wild-type nimX^CDK1and mutant nimX^CDK1F alleles, linked together by the auxotrophicmarker pyr4. The screen consisted of two successive selectionprocedures after the initial introduction of new mutations viaUV irradiation (administered at 3.15 x 10⁴ µJ/cm² on 500,000viable spores on 100 plates to yield $~$ 5,000 viable spores/plateat a survival rate of 1.08%). After random UV mutagenesis, survivingcells were tested for initial temperature sensitivity at 42°C.Strains that showed initial temperature sensitive phenotypeswere selected for subsequent eviction of the nimX^CDK1F allele.By utilizing the toxicity that hydroxyurea (HU) and 5-fluooroticacid (5'-FOA) confer upon cells expressing nimX^CDK1F and pyr4,respectively, a double counterselection was carried out on the $~$ 5,000 surviving strains by growth on medium containing 8 mMHU and 0.1% 5'-FOA to recover cells that had evicted both thenimX^CDK1F allele and the pyr4 gene via homologous recombinationbetween the nimX^CDK1F and the wild-type nimX^CDK1 alleles. Afterverifying the eviction of nimX^CDK1F, the mutant strains wereanalyzed for any change to their initial temperature-sensitivephenotypes within the range of 32 to 42°C. Loss of the temperaturesensitivity due to nimX^CDK1F eviction confirmed that the newlyintroduced mutation and nimX^CDK1F were genetically interactingin a synthetic manner. Mutations identified as showing geneticinteractions with nimX^CDK1F in this way were further analyzedgenetically to verify whether they were single mutations, andtheir allelic relationship was examined. Mendelian segregationof the mutant phenotypes was used to confirm the strains containedsingle mutations. Allelic relationships of the different mutationswere verified by crossing the different mutants with each other,whereupon the outsegregation of a wild-type phenotype in theF₁ progeny determined the given two mutations to have occurredon different genes. Dominance of the mutations were determinedby generating diploid strains of wild-type and mutant haploidstrains. Only recessive mutations were selected for molecularcloning purposes. Single, recessive mutations were consequentlycloned by complementation via transformation with an AMA1 plasmid-basedA. nidulans genomic DNA library (38). A single mutant alleleof Anfcp1 was recovered and sequenced.

Conditional growth test conditions. Strain with null allele of the nonessential phosphatase geneswere tested on MAGUU plates for their response to the followingconditions: benomyl (04 and 0.8 µg/ml), sucrose (0.5,1, and 1.5 M), hydroxyurea (8 and 16 mM), NaCl (0.5, 1, 1.5M), methyl methanesulfonate (0.025 and 0.05%), 1,2,7,8-diepoxyoctane(0.01 and 0.02%), camptothecin (25 µg/ml), and temperature(20 and 32 to 42°C).

Affinity purifications using the S-Tag affinity peptide. We have developed the S-Tag affinity purification system forsingle step protein affinity purification of A. nidulans proteinsendogenously tagged with the S-Tag peptide (21). Details havebeen published elsewhere (29a). Notably, however, the standardprotocol was modified by the addition of 320 mM ammonium sulfate(replacing 300 mM NaCl) and 20% glycerol to the extraction buffer.Purified proteins were run on standard Laemmli-sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gels usinga 3% stacking and 6% separating gel made from a 40% (wt/vol)solution of acrylamide and bis-acrylamide (37.5:1).

In vitro phosphatase reactions and analysis. After purificationof protein via S-Tag affinity purification, beads were treatedwith 40 U of ${lambda}$ -phosphatase (New England Biolabs) with or withoutphosphatase inhibitors (1 mM sodium vanadate plus 50 mM sodiumFluoride) after being washed in 2x phosphatase buffer that includedMnCl₂ and protease inhibitors. The beads were mixed and incubatedat 30°C for 30 min (with occasional mixing). Sample bufferwas added, and the supernatant was collected and analyzed bySDS-PAGE. For Coomassie blue staining, gels were fixed in 50%ethanol and 10% acetic acid overnight, rinsed three times for5 min with distilled H₂O, and stained with Bio-Rad Bio-SafeCoomassie blue solution for 1 h. Background staining was removedby using a water wash for 30 min. Standard methodologies wereused for silver staining.

Microscopy and image capture. Fixed samples were examined by using an E800 microscope (Nikon,Inc.) with DAPI (4',6'-diamidino-2-phenylindole), fluoresceinisothiocyanate, or Texas Red filters (Omega Optical, Inc.).Image capture was performed by using an UltraPix digital camera(Life Science Resources, Ltd.). For live cell microscopy, strainswere germinated in 3 ml of minimal media in 35-mm glass bottompetri dishes (MatTek Cultureware). Visualization was performedby using a Nikon Eclipse TE300 (Nikon, Inc.) inverted microscopein conjunction with an Ultraview spinning disk confocal system(Perkin-Elmer) and an Orca ER digital camera (Hamamatsu). Thesystem is fitted with a Bioptechs delta T4 culture dish heaterand objective heating collar for precise temperature control.Image capture on both microscopes was performed by using Ultraviewimage capture software (Perkin-Elmer). Image analysis was completedby using Adobe Photoshop 6.0 (7).

RESULTS

Top

RESULTS

Identification of 28 protein phosphatase catalytic subunit genes in A. nidulans. The protein sequence of all protein phosphatase catalytic subunitgenes of the budding yeast S. cerevisiae were used for BLASTsearches to determine sequence homologues in the AspergillusComparative Database of the Broad Institute (http://www.broad.mit.edu/annotation/genome/aspergillus_group/MultiHome.html).In addition, the catalytic domains of different classes of proteinphosphatases were used for BLAST searches. A total of 28 differentgenes predicted to encode protein phosphatase catalytic subunitswere thus identified (Table 1) . Of the 28 predicted genes,4 had been identified in previous studies. Originally isolatedthrough genetic screens (34), nimT and bimG were shown to berequired for proper mitotic entry and progression, respectively(8, 36). In addition, pphA is thought to regulate hyphal morphogenesis(26), while cnaA function had been implicated in the regulationof the G₁/S transition of the cell cycle (45), although recentstudies indicate it to be nonessential (50).

View this table:
[in this window]
[in a new window]

TABLE 1. Protein phosphatase catalytic subunit genes in A. nidulans^a

Generation of protein phosphatase gene deletion strains. To examine the function of the protein phosphatase catalyticsubunits, 27 of the 28 identified genes were deleted in a systematicmanner (we were unable to generate the cnaA-null allele). Thenull alleles were generated by replacing coding sequences withgene deletion constructs obtained by fusion PCR (59). The efficacyof homologous recombination of these constructs into the genomewas enhanced by utilizing an A. nidulans recipient strain ofa ${Delta}$ Ku70 genetic background ( ${Delta}$ nkuA) (35). A. nidulans is capableof forming heterokaryons that maintain two types of geneticallyunlike nuclei within a common cytoplasm. When an essential geneis deleted, the primary transformant colonies maintains a heterokaryoticstate in which the essential gene function is provided by theundeleted nuclei, while the function of the nutritional markeris provided by the deleted nuclei. Since conidiospores (conidia)of A. nidulans are uninucleate the heterokaryotic state cannotbe propagated through these spores. Therefore, conidia of theprimary transformants of essential gene deletions are unableto propagate when streaked on nutritionally selective growthmedium. Of the 27 A. nidulans protein phosphatase genes investigated,deletion of 4 protein phosphatase genes resulted in the consistentgeneration of heterokaryons, confirming their cellular functionsto be essential (41). A representative heterokaryon rescue analysisdata set of bimG gene deletion is shown in Fig. 2A. The diagnosticPCR results, using primers targeting sequences outside the genedeletion construct, confirm the formation of heterokaryons containingboth parental and deleted alleles. The deletion strains of theother 23 phosphatase genes were confirmed to be viable homokaryons,demonstrating the function of these protein phosphatases tobe nonessential. No conditional phenotypes associated with thesegene deletions were identified under various experimental growthconditions regarding genotoxic stress, high osmolarity, andhigh and low growth temperatures. Nevertheless, null allelesof four nonessential protein phosphatases showed significantgrowth defects. The deletion strains of Anppg1 (AN0164), Annem1(AN1343), Anssu72 (AN3810), and Anyvh1 (AN4419) exhibited defectivegrowth phenotypes readily distinguishable by the small sizesof their colonies (Fig. 1A). When the diameter of their colonieswere measured daily over 5 days, all four showed reduced colonygrowth rates compared to the control wild-type strains and otherdeleted phosphatase mutants (data not shown).

View larger version (69K):
[in this window]
[in a new window]

FIG. 2. Essential function of protein phosphatase genes analyzed utilizing heterokaryon rescue and alcA-driven alleles. (A) Conidia from six primary transformants obtained after transformation with a bimG deletion construct were replica plated on selective (YAG) and nonselective (YAGUU) plates and incubated to allow colony formation. The inability of ${Delta}$ bimG conidia and untransformed conidia to grow on selective YAG medium and the ability of untransformed conidia to grow on nonselective YAGUU media confirms that each primary transformant colony is heterokaryotic, indicating that bimG is essential (41). Heterokaryon formation was verified using diagnostic PCR analysis, showing that the wild type (lane 1) contains just the wild-type allele and that the heterokaryon contains both wild-type and deletion alleles (lane 2). (B) Deletion phenotypes of essential phosphatase genes, as indicated, can be reconstituted by suppressing their expression using the alcA promoter such that growth can occur when alcA is induced (ethanol media) but not when alcA is suppressed using glucose media. Strains SS120 (alcA-fcp1), SS124 (alcA-nimT), SS121 (alcA-bimG), and SS123 (alcA-pphA) are represented. This both confirms that these genes are essential and provides strains for further functional analysis.

View larger version (116K):
[in this window]
[in a new window]

FIG. 1. Colony growth of all nonessential phosphatase gene deletion strains. (A) While the colony sizes of all other gene deletion strains are comparable to the wild-type control strains SO451 and TNO2A7, including strains SS140 ( ${Delta}$ AN5057), SS150 ( ${Delta}$ AN4544), SS159 ( ${Delta}$ AN0129), SS154 ( ${Delta}$ AN10077), SS157 ( ${Delta}$ AN10138), SS148 ( ${Delta}$ AN5722), SS133 ( ${Delta}$ AN2472), SS141 ( ${Delta}$ AN1467), SS164 ( ${Delta}$ AN0914), SS167 ( ${Delta}$ AN4896), SS143 ( ${Delta}$ AN6982), SS147 ( ${Delta}$ AN1358), SS143 ( ${Delta}$ AN6892), SS135 ( ${Delta}$ AN3793), SS170 ( ${Delta}$ AN0504), SS125 ( ${Delta}$ AN0103), SS137 ( ${Delta}$ AN4426), SS130 ( ${Delta}$ AN10570), and SS129 ( ${Delta}$ AN10281), colonies of the ${Delta}$ Anyvh1 (SS162), ${Delta}$ Annem1 (SS132), ${Delta}$ Anppg1 (SS153), and ${Delta}$ Anssu72 (SS160) strains are smaller. The numbers refer to the AN numbers designated by the Broad Institute (http://www.broad.mit.edu/annotation/genome/aspergillus_group/MultiHome.html). (B) The deletion phenotype of the indicated genes can be mimicked utilizing alcA promoter driven conditional alleles. When their gene expression is suppressed on glucose medium, colony growth is impaired similar to the gene deletion strain colonies: alcA-ppg1 (SS087), ${Delta}$ ppg1 (SS153), alcA-nem1 (SS099), ${Delta}$ nem1 (SS132), alcA-ssu72 (SS122), ${Delta}$ ssu72 (SS160), alcA-yvh1 (SS078), and ${Delta}$ yvh1 (SS162). Three controls are the nonessential phosphatase AN0129 gene under alcA control, a wild-type (growth control strain SO451), and alcA-regulated nimT, which is an essential gene (positive control strain SS124).

Generation of conditional alleles of protein phosphatase genes utilizing the alcA promoter system. As a tool to more easily study the protein phosphatase geneswhose deletions proved to be lethal, or result in severe growthdefect phenotypes, strains containing conditional alleles ofthese genes were generated. In A. nidulans, the targeted regulationof gene expression can be achieved by placing the gene of interestunder the control of the promoter of the alcohol dehydrogenaseI gene alcA (57). As part of the alcohol utilization pathway,alcA gene expression is highly induced in response to ethanoland threonine and suppressed in the presence of glucose (3,28, 29), while fructose, lactose, or glycerol allows a moderatelevel of alcA expression (10, 43). In the present study, thealcA promoter constructs were endogenously inserted immediatelyupstream of the phosphatase gene loci, generating strains inwhich the only copy of the given phosphatase is under the controlof the alcA promoter. When the growth characteristics of thesestrains were compared to the corresponding gene deletion strains,the suppression of the genes on glucose-containing medium provedto be effective enough for the growth patterns exhibited bythe alcA inducible strains to mimic that of the gene deletionstrains. When grown on suppressing medium alc::Annem1 strainsshowed growth defects closely resembling those of the correspondinggene deletion strain (Fig. 1B). Although the growth defectsexhibited by the alc::Anppg1, alc::Anyvh1, and alc::Anssu72strains were not as severe as in the deletion strains, theystill produced colonies of smaller size than wild-type strains(Fig. 1B). Suppression of the essential protein phosphataseswas highly effective since it yielded complete growth arrestsof the alc::Anfcp1 and alc::bimG strains, and only minicolonieswere formed for the alc::nimT and alc::pphA strains (Fig. 2B).

Germination and growth defects resulting from essential protein phosphatase gene deletions. To examine the growth characteristics of cells with essentialprotein phosphatase gene deletions, conidia from the primarygene deletion transformants were streaked on YAG medium platesand grown at room temperature for 3 days. Since the nutritionalmarker used for the transformation was pyrG^AF, YAG plates arenutritionally selective for undeleted conidia that carried thenonfunctional pyrG89 mutant allele. Not meeting the nutritionalrequirement, it is known that these conidia fail to projecta germ tube and do not grow beyond swelling of the conidiospores.In contrast, the conidia which are pyrG⁺ but deleted of theessential phosphatase genes would grow up to the limit imposedby the lack of the essential phosphatase gene function, enablingthe assessment of the terminal growth phenotypes caused by thedeletions. Deletion of bimG showed the most severe growth defectas the ${Delta}$ bimG spores on YAG medium failed to project germ tubesand nuclei failed to divide (Fig. 3A). Deletion of Anfcp1 wasslightly less severe as ${Delta}$ Anfcp1 spores were able to germinateand project very short germ tubes (Fig. 3A). The nimT gene deletionhad a less detrimental effect on initial germination and polarizedgerm tube projection (Fig. 3A). Similarly, ${Delta}$ pphA spores werealso able to grow into germlings comparable to ${Delta}$ nimT spores (Fig.3A).

View larger version (73K):
[in this window]
[in a new window]

FIG. 3. Growth arrest and nuclear defects of essential phosphatase gene deletions. (A) The terminal growth patterns of essential phosphatase gene deletions were recorded after 3 days growth of conidia from heterokaryons of the indicated gene deletions on selective plates and then photographed at low power. ${Delta}$ bimG conidiospores show virtually no polarized growth even after 3 days. While ${Delta}$ Anfcp1, ${Delta}$ pphA, and ${Delta}$ nimT conidia are able to germinate, the projected germ tubes fail to grow to form colonies. To the right, representative germlings of the indicated deletions are shown after DAPI staining to reveal nuclear number and morphology. ${Delta}$ bimG and ${Delta}$ nimT cells showed late G₂- and M-phase arrest phenotypes, respectively, consistent with previously known loss-of-function mutant phenotypes. The nuclei of ${Delta}$ Anfcp1 cells appear severely fragmented, and ${Delta}$ pphA cells exhibit irregular distributions of nuclei along the germ tube with indications of defects in proper nuclear segregation. (B) Representative germlings, after DAPI staining, of gene deletions that cause growth defects but not lethality, as indicated, after 6.5 h (top panels) and 9 h (bottom panels) of growth. Strains are SS162 ( ${Delta}$ yvh1), SS153 ( ${Delta}$ ppg1), SS132 ( ${Delta}$ nem1), and SS160 ( ${Delta}$ ssu72) are represented. The R153 wild-type strain is shown for comparison. Bar, $~$ 5 µm.

Nuclear defects in cells with the essential phosphatase genes deleted. To determine potential nuclear and mitotic defects associatedwith the deletion of essential phosphatase genes, spores ofthese deletion transformants were suspended into YG liquid mediumand inoculated on coverslips, grown for 18 h at room temperature,DAPI stained, and imaged by fluorescence microscopy (as an exception,spores taken from the bimG deletion transformant were grownin nonselective YGUU medium since ${Delta}$ bimG pyrG⁺ spores and bimGpyrG89 spores were more difficult to distinguish in selectiveYG medium). Previous studies conducted with the bimG11 conditionalmutant allele had revealed that loss of BIMG activity led tomitotic arrest of the cell with condensed DNA (8). When visualizedby DAPI staining the nuclei of ${Delta}$ bimG spores were arrested withDNA remaining condensed, a phenotype consistent with the observationsmade in bimG11 mutants (Fig. 3A). DAPI staining of ${Delta}$ nimT cellsrevealed their nuclei showing a G₂-phase arrest with nucleiunable to enter mitosis with uncondensed DNA, also confirmingthe previous conclusions about nimT function drawn from studiesof the nimT23 temperature-sensitive mutant (36). Although germlingsof ${Delta}$ pphA cells were capable of at least three rounds of mitoses,their nuclei had irregular morphologies and distribution alongthe germ tube, indicative of potential mitotic defects (Fig.3A). ${Delta}$ Anfcp1 cells showed DAPI staining patterns that made itdifficult to distinguish individual nuclei, possibly due tomitotic defects.

Cytological abnormalities in nonessential protein phosphatase deletions with growth defects. For the analysis of the nonessential phosphatase gene deletionsthat cause a decline in colony size, clonal conidium stockswere generated for each of the deletion strains, as well asthe alcA-regulated strains. After 6.5 and 9 h of growth in YGUU-richliquid medium at 32°C, the cells were fixed and stainedwith DAPI to visualize DNA. Control wild-type cells (strainR153) grown under the same conditions reached, on average, the4- and 16-nucleus stages, respectively, after 6.5 and 9 h ofgrowth (Fig. 3B), and the growth and cytological defects exhibitedby the phosphatase null mutants were compared to them. Deletionof Anppg1 and Anssu72 appeared to slightly affect the overallearly growth rate without causing any pronounced nuclear defects.At time points of 6.5 and 9 h of growth, both ${Delta}$ Anppg1 and ${Delta}$ Anssu72cells had fewer nuclei, as well as shorter germ tubes comparedto the wild-type cells, indicating an overall slowdown of growthas a consequence of the gene deletions (Fig. 3B). Although lesssevere, these phenotype were also observed in the alc::Anppg1and alc::Anssu72 cells grown under suppressing conditions (thesame YGUU rich liquid medium used is glucose-based and thussuppresses alcA-promoter-driven expression) (data not shown).In the Annem1-null mutants, although the overall growth rateof the cells was also affected, signs of DNA fragmentation werethe most significant deletion phenotype. The nuclei were smallin size and of irregular shape, with some appearing to havecondensed DNA. A feature more pronounced in the cells that hadgrown longer (9 h) was the presence of fiber-like structurespositively stained by DAPI that appeared to be interlinkingthe nuclei (Fig. 3B). These phenotypes persist in the alc::Annem1strain grown under suppressing conditions, although their growthrate resembles that of the wild-type strain (data not shown).Taken together, these phenotypes suggested defects in mitosis,leading to fragmented DNA masses and nuclei that failed to fullyseparate from each other. The most severe growth defect phenotypeamong the nonessential phosphatase gene deletion strains wasshown by the ${Delta}$ Anyvh1 strain. After 6.5 h of growth, most of thespores had failed to germinate, and many of those cells hadnot undergone their first mitosis either (Fig. 3B). Even thecells that had managed to initiate germination were small insize, not only in terms of the length of the germ tube but alsoin the extent of how much the spore had swollen prior to germination.When ${Delta}$ Anyvh1 cells were grown for 9 h, the germ tubes were stillvery short in length (Fig. 3B).

Genetic interaction of an Anfcp1 mutation with cdk1F. The systematic gene deletion analysis of the protein phosphatasecatalytic subunits revealed the function of bimG, nimT, pphA,and Anfcp1 to be essential in A. nidulans. The severity of nucleardefects, suggestive of mitotic defects, observed in ${Delta}$ Anfcp1 cellswas interesting, and the results of a novel forward geneticscreen provided insight into the potential role of Anfcp1 inregulating the cell cycle and mitosis. Cdk1 is one of the mainregulators determining entry into mitosis. Activation of Cdk1,which triggers the G₂/M transition, hinges on the removal ofinhibitory phosphorylation from a tyrosine residue in the ATP-bindingdomain, a mechanism conserved in organisms ranging from fissionyeast to humans. However, unlike fission yeast, in A. nidulansthis mechanism is not the only means through which entry intomitosis is regulated, since mutants that lack the inhibitoryphosphorylation (Tyr15) (cdk1F, tyrosine 15-to-phenylalaninemutation) still progress through the cell cycle in the absenceof genotoxic stresses. However, this allele does cause sensitivityto DNA-damaging agents and slowed S phase caused by low levelsof HU (60, 61). With the aim of identifying additional mitoticregulatory genes that do not function through Tyr15 phosphorylationof Cdk1, a genetic screen was carried out looking for mutationsthat show genetic interactions with the cdk1F mutant allele.As a result, a loss-of-function conditional mutation of Anfcp1was isolated, which showed a synthetic temperature sensitivityphenotype in combination with cdk1F.

The genetic screen utilized an A. nidulans strain that has botha wild-type cdk1 and a cdk1F mutant allele linked in tandemwith the nutritional marker pyr4. As a hyperactive kinase mutant,the cdk1F mutant allele is dominant over the wild-type counterpartwhile not causing temperature sensitivity. After UV mutagenesis,mutant strains showing temperature sensitivity were processedto define mutations that depend on the cdk1F mutation for theirtemperature-sensitive phenotype. This was done by using 5'-FOAto select against pyr4 and HU to select against cdk1F allowingselection for loop-out of the cdk1F allele via homologous recombinationbetween the wild-type cdk1 and mutant cdk1F alleles. In thisway alleles without cdk1F were selected. Strains obtained inthis way were tested for loss of their temperature-sensitivephenotype. Loss of temperature sensitivity as a consequenceof cdk1F eviction confirmed that the newly introduce mutationsand the cdk1F mutation genetically interact in a negative manner,in combination causing increased temperature sensitivity (Fig.4A).

View larger version (59K):
[in this window]
[in a new window]

FIG. 4. Genetic interaction between the Anfcp1 phosphatase and the activated cdk1F allele of the Cdk1 mitotic kinase. (A) Colony growth at 32°C (left plate) and 38.5°C (right) of strains containing the following mutations: 1, fcp1^ts cdk1F (SS101); 2, cdk1F (SS105); 3, fcp1^ts (SS002); 4, wild type (TNO2A7); 5, fcp1^ts cdk1F cdk1; and 6, cdk1F cdk1 (FRY24). (B) Domains of AnFcp1 and the mutation causing the fcp1^ts allele, which changes the indicated conserved leucine to a serine. An, A. nidulans; Sce, S. cerevisiae; Spo, S. pombe; Hu, human. (C) S-Tagged RNAP II was purified from a strain with the fcp1^TS mutation (SS031) or a wild-type strain (SS025) grown at 32 or 42°C. Purified proteins were separated via SDS-PAGE, and the gel was stained with Coomassie blue. The region of the gel corresponding to RNAP II is shown.

One of the mutant alleles isolated in this screen was Anfcp1^ts.When the mutant allele was cloned and sequenced, a mutationthat converted a conserved leucine residue, immediately upstreamof the "DXDXT" metal-assisted phosphotransferase signature motif,to a serine residue was identified (Fig. 4B). Designated Anfcp1^ts,this mutant allele causes a certain level of temperature sensitivityby itself, but in combination with the cdk1F mutant causes astronger temperature-sensitive phenotype, underscoring the geneticinteraction of Anfcp1 and cdk1 (Fig. 4A).

AnFCP1 is a protein phosphatase which dephosphorylates RNA polymerase II. Both in S. cerevisiae and in humans, the protein phosphataseFcp1 had been shown to dephosphorylate the C-terminal domainof the largest subunit of RNA polymerase II (1, 24). To verifywhether this function of AnFCP1 is conserved, its putative targetRNAP II was endogenously tagged C terminally with the affinityS-Tag. This was done since antibodies targeting specific serineresidues within the Y-S-P-T-S-P-S heptapeptide repeats of theRNAP II CTD were ineffective, presumably because these repeatsare only loosely conserved in A. nidulans (51; data not shown).The S-Tag version of RNAP II is functional since RNAP II isessential (data not shown) and strains carrying the S-Taggedversion were viable and displayed no growth defects. Using theS-Tag protein purification system (21), RNAP II was affinitypurified from both wild-type and Anfcp1^ts strains incubatedat the permissive (32°C) and restrictive (42°C) temperaturesof the Anfcp1^ts conditional mutation. RNAP II purified fromthe wild-type strain separated into subspecies with a size rangeof $~$ 200 to 250 kDa at both 32 and 42°C. Unlike in the wild-typestrain, RNAP II purified at 42°C from the Anfcp1^ts strainshowed the loss of subspecies with molecular masses lower than $~$ 250 kDa, suggesting the loss of hypo- and unphosphorylated isoformsof RNAP II CTD (Fig. 4C). An in vitro phosphatase treatmentconfirmed that the differences in electrophoretic mobility shownby different RNAP II isoforms were indeed due to differentialphosphorylation (data not shown).

Synthetic interaction of Anfcp1^ts and cdk1F. As a hyperactive protein kinase and an inactivated protein phosphatasepaired together led to a synthetic mutant phenotype (enhancedtemperature sensitivity), we hypothesized that this interactionmay be mediated by an abnormally elevated phosphorylation stateof a common protein substrate shared by cdk1 and AnFCP1. Inaddition to being the substrate of the phosphatase Fcp1, RNAPII CTD had been shown in previous studies to be phosphorylatedby Cdk1 in vitro (14) and undergo mitotic specific hyperphosphorylation(58). This suggests RNAP II CTD as a candidate common substrateof Fcp1 and Cdk1. To examine this possibility, endogenouslyS-tagged RNAP II was affinity purified from cdk1F, Anfcp1^ts,and Anfcp1^ts cdk1F mutants at various temperatures. In the cdk1Fmutant strain, RNAP II CTD phosphorylation remained constantcomparable to wild-type strains at both 32 and 42°C, a findingconsistent with the fact that the cdk1F mutant strain does notexhibit a temperature sensitive phenotype. To compare the phosphorylationstatus of Anfcp1^ts mutant and Anfcp1^ts cdk1F double-mutant strains,cultures were grown at the permissive temperature of 32°Cand subsequently shifted to temperatures of 37 to 40°C.Although this was the range of temperature where the syntheticeffect of the two mutations was most pronounced (i.e., the Anfcp1^tscdk1F double-mutant strain exhibits a more severe level of temperaturesensitivity compared to the single mutant strains), the differenceof the phosphorylation statuses differed only marginally. Asimilar result was obtained when the cultures of the two strainswere grown entirely at 37°C (data not shown). These dataindicate that the synthetic interaction of Anfcp1 and cdk1 areat best only partially mediated through the phosphorylationstatus of RNAP II.

Localization of RNAP II through the cell cycle. RNAP II was endogenously tagged with GFP and its localizationexamined throughout the cell cycle by time-lapse confocal microscopy.In wild-type cells, RNAP II located to nuclei, with a partialexclusion from the nucleolus indicated by a darker area withineach nucleus (Fig. 5, –1.5'). At certain time points,the fluorescence intensity within nuclei dissipated evenly intothe entire cell, remained dispersed for 4 to 5 min, and reconcentratedback into the nuclei that in the mean time had doubled in numbers.The doubling of the number of nuclei and the time frame of theRNAP II staying dispersed indicated that while RNAP II localizedto the nuclei during interphase, it dispersed throughout thecell when mitosis started and relocalized to daughter nucleionce mitosis was completed (Fig. 5). Since A. nidulans is knownto undergo a partially open mitosis, the mitotic specific dispersalof RNAP II indicates that it does not remain associated withnuclear components during mitosis.

View larger version (83K):
[in this window]
[in a new window]

FIG. 5. RNA polymerase II changes location during mitosis. Endogenously GFP-tagged RNAP II (strain SS185) was imaged by using time-lapse confocal microscopy as cells passed through mitosis. RNAP II-GFP is predominantly nuclear during interphase, while it disperses into the cytoplasm during mitosis and is reimported to daughter nuclei during exit from mitosis and entry into G₁. Bar, $~$ 5 µm.

To determine whether the genetic interaction of the cdk1F andAnfcp1^ts mutations affected mitosis, endogenously GFP taggedRNAP II was followed in the wild type and in cdk1F, Anfcp1^ts,and Anfcp1^ts cdk1F mutants growing at 38°C. Concerning thelength of germlings, the number and distribution of the nucleiand the duration of mitoses (i.e., dispersal of RNAP II::GFPfrom nuclei, due to NPC partial disassembly) (7), the wild-typeand cdk1F strains did not appear to have a notable difference,a finding consistent with the fact that at 37°C neitherof the strains showed visible growth defects. The Anfcp1^ts strainshowed a slightly longer duration of RNAP II-GFP dispersed thoughno major cytological defects were observed. The most strikingphenotypes were displayed by Anfcp1^ts cdk1F double mutants.Many of these cells displayed nuclei that were near to eachother with nuclei appearing to be joined (Fig. 6D). Time lapseimaging revealed (Fig. 7A) that such cells had nuclei that weredifficult to define from each other and which changed in shapeand conformation through time. In fact, nuclei often appearedto merge into one continuous nucleus containing multiple nucleoli(see Fig. 7A at 48', for example). These surprising changescan be seen clearly in a full-time course video file (see Video1S in the supplemental material). When RNAP II::GFP was seento disperse from such apparently joined nuclei, indicating entryinto mitosis, the number of nuclei was not always increasedwhen RNAP II::GFP returned to nuclei after completion of mitosis(Fig. 7B). Additionally, we observed some nuclei in the doublemutant that appeared to complete mitosis, generating two daughternuclei capable of importing RNAP II-GFP but which then remergedin an apparent reversal of mitosis (Fig. 7C). At time zero'(Fig. 7C), the cell contains two nuclei and a micronucleus.At 8' the cell enters mitosis and RNAP II-GFP starts to dispersefrom nuclei to throughout the cell. At 22' the cell exits mitosisand daughter nuclei reimport RNAP II-GFP, and at 24' four nucleiare apparent. However, as the cell progresses further into thecell cycle these four nuclei merge into two nuclei, each witha single nucleolus. The micronucleus can also be seen. Thus,although this cell undergoes a mitotic event the net resultis regeneration of the same nuclear configuration (compare the0' to 40' images in Fig. 7C). Finally, cells were observed inwhich the RNAP II::GFP signal remained dispersed after enteringmitosis for an extended period of time, presumably due to theirinability to exit mitoses.

View larger version (78K):
[in this window]
[in a new window]

FIG. 6. The synthetic effects of cdk1F and Anfcp1^TS are manifested as severe mitotic defects. Representative fields of cells each expressing endogenously tagged RNAP II at the beginning of time lapse confocal microscopy. (A) Wild type (SS185); (B) cdk1F (SS177); (C) Anfcp1^TS (SS174); (D) cdk1F Anfcp1^TS (SS190). Cells were grown and imaged at 38°C. Bar, $~$ 5 µm.

View larger version (111K):
[in this window]
[in a new window]

FIG. 7. Nuclear defects defined by location of RNAP II-GFP during live cell confocal microscopy in a fcp1^ts cdk1F double mutant (strain SS190). (A) Cell containing an ill-defined interphase nuclear cluster that fails to enter mitosis over a 102-min period. At times, individual nuclei seem apparent, but these then merge to form one large nucleus containing multiple nucleoli, revealed as darker nuclear shadows. A video file (see Video S1 in the supplemental material) displays the full time course collected at 1.5-min intervals over 102 min. The playback rate is 2 frames/s (fps). (B) Cell containing a single nucleus that undergoes mitosis, releasing RNAP II-GFP throughout the cell. Upon exit from mitosis and nuclear reimport of RNAP II-GFP, no clear daughter nuclei are generated during this abortive mitosis. A video file (see Video S2 in the supplemental material) displays the time course collected at 1.5-min intervals over 42 min. The playback rate is 2 fps. (C) Cell containing two nuclei and a micronucleus, presumably as a result of a previous defective mitosis. During mitosis, RNAP II-GFP is released from nuclei and then initially reimported to four apparent nuclei upon mitotic exit. However, the paired nuclei from each of the two parental nuclei then reverse mitosis and become two individual nuclei again, each containing a single nucleolus. A video file (see Video S3 in the supplemental material) displays the full time course collected at 2-min intervals over 56 min. The playback rate is 2 fps. Bar, $~$ 5 µm.

In nuclei where the RNAP II::GFP signals dispersed during mitosisand reconcentrated to the nuclei upon its completion, it tooksignificantly longer for this cycle to be completed (comparethe timing of RNAP II-GFP dispersal in Fig. 5 to 7 for example).To rule out the possibility that this may merely be due to anoverall slowed-down cell cycle, the frequency of dispersed RNAPII::GFP signals in all four strains was measured in fixed cellsgrown at 37°C (Table 2) . The increased percentage of cellswith dispersed RNAP II::GFP (Table 2) support the findings oflonger mitoses in the Anfcp1^ts and especially the Anfcp1^ts cdk1Fmutants. The severity of the cytological defects observed inthe Anfcp1^ts cdk1F double-mutant cells might help explain thebasis of the synthetic nature of the genetic interaction betweenthe Anfcp1^ts and the cdk1F mutations. While the Anfcp1^ts andcdk1F single mutants showed moderate or no notable defects comparedto wild-type cells, the Anfcp1^ts cdk1F double mutant exhibitedphenotypes that went far beyond the simple addition of thatof the two single mutant strains.

View this table:
[in this window]
[in a new window]

TABLE 2. Frequency of RNAP II::GFP dispersal in the wild-type, cdk1F, Anfcp1^TS, and Anfcp1^TS cdk1F strains at 37°C^a

DISCUSSION

Top

DISCUSSION

Essential protein phosphatases and cell cycle regulation. This study showed the phosphatase genes bimG, nimT, Anfcp1,and pphA to encode proteins with essential cellular functions.The fact that two of these genes were identified previouslyin genetic screens for cell cycle mutants (34) and that overexpressionof a dominant-negative form of PphA affects growth and mitosis(26) and the identification of AnFCP1 as a potential mitoticregulator in the screen described in this study clearly demonstratethe essential importance of phosphatase-mediated protein dephosphorylationin regulating cell cycle progression. The terminal phenotypesdisplayed by cells with bimG and nimT deleted confirmed theirfunctions to be critical in mitotic regulation, which is consistentwith the findings from studies of the conditional mutant allelesbimG11 and nimT23. While Anfcp1 and pphA deletions did not yieldphenotypes as clearly demonstrative of mitotic defects as bimGand nimT deletions, their defective nuclear DNA morphologiessuggested that there are potentially important functions ofthese genes in mitotic regulation as well. The availabilityof the conditional Anfcp1^ts mutant allele, as well as strainsin which Anfcp1 and pphA are under the inducible promoter alcA,should prove to be useful in further studies of the functionsof these essential genes.

One noticeable essential phosphatase, the Cdc14 phosphatase,that is required for the regulation of S. cerevisiae mitosisis not essential in A. nidulans. In fact, the null Ancdc14 straingrows and develops normally. This suggests that Cdc14 phosphatasesmight not be essential components of mitotic regulation in allorganisms, and recent deletion studies indicate Cdc14B is dispensablefor human mitotic regulation (5).

Gene deletion phenotypes of nonessential protein phosphatases. The gene deletion of four protein phosphatases did not causelethality but had physiological effects detrimental enough tocause strong growth defects. Of these four phosphatase genes,AnSSU72 is functionally linked to the essential phosphataseAnFCP1 since the physiological target of both phosphatases hadbeen shown to be the C-terminal domain of RNAP II (27). Thismay reflect the importance of maintaining a proper phosphorylationstatus of RNAP II CTD for the cell to engage in proper transcriptionalactivity, by itself an activity absolutely vital for cellularsurvival. Unlike AnSSU72, the phosphatase AnNEM1 is linked toAnFCP1 by belonging to the same protein phosphatase family thatshares the CPD type catalytic domain. Defined first by the discoveryof Fcp1, the CDP family is made up of protein phosphatases thatengage in aspartate-based catalysis of target proteins and havein common the signature catalytic motif of DXDXT/V. While onlythree different CPD phosphatases are present in A. nidulans,one of them is essential (Anfcp1) and one causes severe growthdefects upon deletion (Annem1), indicating the importance ofthe biological function conserved in this phosphatase family.Within the context of cell cycle regulation, Annem1 is of addedinterest since its deletion not only caused an overall decreaseof cellular growth but was also marked by noticeable nuclearstructure phenotypes, a strong indication that it may play animportant role in mitotic regulation and/or nuclear structure.This finding is consistent with the functions of Nem1p (S. cerevisiae)and Dullard (humans), which are known to regulate nuclear membranebiogenesis (22, 47, 49).

Genetic interaction of Anfcp1 and cdk1 and RNAP II CTD phosphorylation. The identification of Anfcp1^ts to cause increased temperaturesensitivity in combination with cdk1F revealed a genetic interactionbetween Anfcp1 and cdk1. The fact that a hyperactive kinase(cdk1F), together with an inactivated phosphatase (Anfcp1^ts),caused a synthetic mutant phenotype suggests the effects ofthose two mutations may converge into a hyperphosphorylatedstate of a common protein substrate. While potential targetsof cdk1 phosphorylation are numerous, the only substrate ofprotein phosphatase Fcp1 convincingly shown thus far is theRNAP II CTD. In contrast to our expectations, the overall levelof RNAP II CTD phosphorylation did not show a significant elevationwhen endogenously S-tagged RNAP II was purified and analyzedby SDS-PAGE under conditions where the synthetic temperaturesensitivity of the Anfcp1^ts cdk1F double mutant is most pronounced.Although this result shows that the bulk amount of RNAP II CTDphosphorylation does not proportionately mediate the synthetictemperature sensitivity of the Anfcp1^ts cdk1F double mutant,it should be noticed that the A. nidulans RNAP II CTD contains44 serine-proline dipeptide sequences, all potential targetsof phosphorylation. It is possible that the synthetic phenotypemay be attributed to the phosphorylation of specific RNAP IIresidues which are not readily detectable by mobility shiftsduring SDS-PAGE. Notably, we were unable to detect an obviouslyhyperphosphorylated form of RNAP II during mitosis, whereassuch a form has been shown to exist during higher eukaryoticmitosis (58).

Localization of RNAP II during A. nidulans mitosis. Since mitosis in A. nidulans is partially open (7, 39), nuclearproteins that are not attached to the nuclear interior duringmitosis, on chromosomes, for example, can disperse into thecytoplasm via passive diffusion once nuclear pores open at thebeginning of each mitotic phase. In contrast, proteins suchas histones, which remain associated with chromatin during mitosis,are not released from nuclei during mitosis. The predominantnuclear localization of endogenously GFP-tagged RNAP II in growingcells confirmed that it remains in the nucleus during interphasesince it is engaged in transcriptional activities. The completedispersal of RNAP II during mitosis suggests that its associationwith DNA may be actively disrupted during mitosis, effectivelydisabling it from continuing transcription. During the transcriptioncycle, it had been shown that the CTD of RNAP II has to be completelydephosphorylated for the RNAP II to form a preinitiation complexand reengage in transcriptional activity (25, 48). In mammaliancells the RNAP II CTD is hyperphosphorylated during mitosis,and this is thought to be regulated by Cdk1-mediated phosphorylation(58). Although in A. nidulans this mitosis-specific CTD hyperphosphorylationevent could not be observed, the fact that RNAP II completelydisperses during mitosis suggests that there still may be amitotic specific phosphorylation pattern of RNAP II CTD in A.nidulans capable of actively dissociating RNAP II from chromatinand thus contributing to its mitosis-specific dispersal. Thework described here has demonstrated that cdk1F shows a stronggenetic interaction with the RNAP II CTD phosphatase gene Anfcp1.Taken together with the fact that Cdk1 is a major mitotic proteinkinase which in other systems is capable of phosphorylatingRNAP II CTD in vitro, the Cdk1 kinase could be considered acompelling candidate to promote such a mitosis-specific phosphorylationevent of RNAP II CTD. Intriguingly, the mitotic hyperphosphorylationof RNAP II CTD in higher eukaryotes is dependent on the Pin1peptidyl-prolyl isomerase (58). Pin1 has been shown to bothinhibit Fcp1 and activate Cdk1, thus promoting mitotic hyperphosphorylationof RNAP II CTD. It will thus be interesting to investigate thepotential role of Pin1 (PinA in A. nidulans [20]) in mediatingthe genetic interactions and mitotic phenotypes (see below)we have uncovered while studying Fcp1 and Cdk1. One predictionis that increased expression of PinA might phenocopy the fcp1^tscdk1F double mutant (by inhibiting Fcp1 and activating Cdk1).

Mitotic defects in the Anfcp1^ts cdk1F double mutant. When the localization pattern of RNAP II was examined in theAnfcp1^ts, cdk1F, and Anfcp1^ts cdk1F strains at 38°C andcompared to wild-type cells, the Anfcp1^ts cdk1F double mutantsrevealed by far the most severe defects. The various pleiotropicdefects observed in the Anfcp1^ts cdk1F double mutants stronglyindicates that the synthetic interaction between the Anfcp1^tsand cdk1F mutation may impact cells in ways that might go beyondthe immediate disruption of the RNAP II-driven transcriptioncycle. Although the RNAP II CTD is thus far the only known substrateof FCP1, it cannot be ruled out that FCP1 and Cdk1 may shareother common substrates. Since the effects of mutations of Anfcp1and cdk1 would become amplified in a pleiotropic manner if theywere to share many substrates, this could explain why the differenceof RNAP II CTD phosphorylation between cdk1F, Anfcp1^ts, andAnfcp1^ts cdk1F mutants is only moderate compared to the severityof the cytological defects observed in the double mutant. Alternatively,the effects of the double mutant on the fidelity of transcriptioncould potentially preferentially affect gene expression specificto cell cycle transitions, thus causing the mitotic defectsobserved. It is also possible Cdk1 and FCP1 do not directlyshare a common substrate but function in different cellularpathways. The interaction between Anfcp1^ts and cdk1F is geneticin nature, and Anfcp1^ts and cdk1F could still show their syntheticallyinteracting effects if the separate biological pathways in whichthey function merge onto common cellular targets that provideimportant activities concerning mitotic regulation. In fact,reports suggesting the involvement of Fcp1 in DNA damage responses(19) indicate that Fcp1 may functionally relate to Cdk1 in amanner more directly linked to mitotic regulation. However,we could not detect obvious DNA damage response defects in thefcp1^ts allele.

Overall, the severe mutant phenotypes observed in the doublemutant compared to that exhibited by the Anfcp1^ts and cdk1Fsingle mutants confirms the relevance of the genetic interactionbetween Anfcp1^ts and cdk1F and provides important evidence thatthe conserved Fcp1 phosphatase might play a role in mitoticregulation by counteracting Cdk1-mediated phosphorylation.

ACKNOWLEDGMENTS

We thank Berl Oakley and members of his lab, especially TanyaNayak, for generously providing constructs used in generatingthe riboB::alcA insertion cassette, the TNO2A7 strain, and helpfuldiscussions. We also thank all members of the Osmani lab forhelp and support, especially Hui-Lin Liu for having made availablethe S-Tag affinity purification system extensively used in thisstudy and Aysha Osmani for her expertise and steady moral supportthroughout the entire process of this work.

This study was supported by a grant from the National Institutesof Health (GM042564) to S.A.O.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Genetics, The Ohio State University, 804 Riffe Bldg., 496 W. 12th Ave., Columbus, OH 43210. Phone: (614) 247-6791. Fax: (614) 247-6845. E-mail: osmani.2{at}osu.edu

Published ahead of print on 30 January 2009.

Supplemental material for this article may be found at http://ec.asm.org/.

REFERENCES

Top