A Genetic Screen for Temperature-Sensitive Cell-Division Mutants of Caenorhabditis elegans

A Genetic Screen for Temperature-Sensitive Cell-Division Mutants of Caenorhabditis elegans

Kevin F. O'Connell^a, Charles M. Leys^a, and John G. White^a,b
^a Laboratory of Molecular Biology, University of Wisconsin, Madison, Wisconsin 53706
^b Department of Anatomy, University of Wisconsin, Madison, Wisconsin 53706

Corresponding author: Kevin F. O'Connell, Laboratory of Molecular Biology, University of Wisconsin, 1525 Linden Dr., Madison, WI 53706-1596, kfoconne{at}facstaff.wisc.edu (E-mail).

Communicating editor: R. K. HERMAN

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

A novel screen to isolate conditional cell-division mutantsin Caenorhabditis elegans has been developed. The screen isbased on the phenotypes associated with existing cell-divisionmutations: some disrupt postembryonic divisions and affect formationof the gonad and ventral nerve cord—resulting in sterile,uncoordinated animals—while others affect embryonic divisionsand result in lethality. We obtained 19 conditional mutantsthat displayed these phenotypes when shifted to the restrictivetemperature at the appropriate developmental stage. Eighteenof these mutations have been mapped; 17 proved to be singlealleles of newly identified genes, while 1 proved to be an alleleof a previously identified gene. Genetic tests on the embryoniclethal phenotypes indicated that for 13 genes, embryogenesisrequired maternal expression, while for 6, zygotic expressioncould suffice. In all cases, maternal expression of wild-typeactivity was found to be largely sufficient for embryogenesis.Cytological analysis revealed that 10 mutants possessed embryoniccell-division defects, including failure to properly segregateDNA, failure to assemble a mitotic spindle, late cytokinesisdefects, prolonged cell cycles, and improperly oriented mitoticspindles. We conclude that this approach can be used to identifymutations that affect various aspects of the cell-division cycle.

TO divide, a cell must be able to replicate its DNA, assembleand position a mitotic spindle, and initiate and complete acytokinetic furrow at the appropriate time and place. Each ofthese events and all the associated intermediate steps mustbe coordinated with one another and executed with a high degreeof precision to allow the faithful segregation of genetic materialand cytoplasmic constituents. Despite a long-standing effortto elucidate the mechanisms involved, a complete understandingof many aspects of the process of cell division is lacking.

Using mutation to identify genes required for cell divisionis one particularly fruitful approach to understanding thesemechanisms. Mutant hunts in budding yeast (HARTWELL et al. 1970), fission yeast (NURSE et al. 1976 ; NASMYTH and NURSE 1981; SAMEJIMA et al. 1993 ), flies (GATTI and BAKER 1989 ), andother species have led to the identification of many componentsof the cell-division machinery. But understanding in molecularterms the function of an individual component and how it interactswith other essential proteins requires that genetics be combinedwith biochemistry and cell biology. Thus, the ideal biologicalsystem should be amenable not only to genetic studies but alsoto a broad range of biochemical and cell biological techniques.

The nematode Caenorhabditis elegans seems well suited to exploringthe mechanisms of cell division. In addition to its availabilityfor strong genetic techniques, C. elegans has proven usefulfor both biochemical (AROIAN et al. 1997 ) and cell biological(HYMAN 1989 ; HIRD and WHITE 1993 ) approaches. The early embryo,in particular, possesses several attractive features for suchstudies: it is immotile and contains fairly large cells (10to 50 µm in diameter), facilitating cytological analysis.The centrosomes and spindles are visible by light microscopyand can thus be viewed in live specimens without the need forcomplex imaging techniques. Equally important, cells in theC. elegans embryo undergo cytokinesis—unlike yeast cells,which divide by medial fission or budding, or early Drosophilaembryos, which undergo nuclear division without cytokinesis.Thus, mutations that affect this aspect of cell division canbe studied during the earliest stages of embryogenesis. In addition,the C. elegans embryo possesses both cells that divide proliferatively—toproduce identical daughters—and cells that divide determinatively—toproduce daughters with distinct developmental potentials. Thus,mutations that affect one or both types of division can be identified.

Mutations that affect cell division have been previously identifiedin C. elegans. However, the effects of many of these are limitedto a subset of lineages. Several large-scale screens for embryoniclethal (emb) mutants have identified mutations that affect variousaspects of cell division in the early embryo (HIRSH and VANDERSLICE1976 ; MIWA et al. 1980 ; CASSADA et al. 1981 ; KEMPHUESet al. 1988A , KEMPHUES et al. 1988B ), while another screenhas identified mutations that specifically affect the postembryoniclineages (HORVITZ and SULSTON 1980 ). Both sets include mutationsthat disrupt the temporal and spatial patterns of cell divisionas well as mutations that block division altogether. As notall lineages are affected by these mutations, it is not knownwhether these genes encode key players in the mechanisms ofdivision that are common to all cells.

Among the mutations that affect postembryonic lineages, lin-5(e1348)and lin-6(e1466) are unusual in that they affect nearly alldivisions that occur during this period (ALBERTSON et al. 1978; HORVITZ and SULSTON 1980 ; SULSTON and HORVITZ 1981 ). Thesetwo mutations affect very different aspects of the cell-divisionprocess; lin-5 mutants exhibit defective karyokinesis and cytokinesis(ALBERTSON et al. 1978 ), while lin-6 mutants are defectivein DNA synthesis (SULSTON and HORVITZ 1981 ). Despite the severityof the defects, both lin-5 and lin-6 homozygotes are viable;none of the cell divisions that occur postembryonically areessential for growth and development. However, both mutantsexhibit a similar sterile, uncoordinated (Stu) phenotype becausethe cell divisions required for formation of the gonad and certainventral-cord motor neurons fail.

It is possible that the lin-5 and lin-6 genes encode proteinsthat play fundamental roles in cell division. One would thereforeexpect that these genes would be required for all divisions.However, neither lin-5(e1348) nor lin-6(e1466) affects the embryonicdivisions; homozygotes complete embryogenesis normally. A likelyexplanation for the lack of early defects could be that thesegene products are maternally provided. Homozygotes would exhibitcell-division failure only when the maternal gene product becomeslimiting—in these cases, during the postembryonic divisions.As the lin-5 and lin-6 mutants are nonconditionally sterile,they provide no insight into embryonic functions. One could,however, identify conditional alleles. This would allow oneto block maternal gene expression and study the cytologicalphenotype during the embryonic divisions.

We have devised a screen to identify temperature-sensitive (ts),nonlineage-specific cell-division mutations in C. elegans. Ourapproach was designed with two goals in mind: to identify genesthat encode key components of the cell-division machinery, andthat are thus required for most cell divisions, and to be ableto study the effects of these mutations during the early embryonicdivisions. To identify the desired genes, we screened for mutantswith ts Emb and Stu phenotypes, indicative of embryonic andpostembryonic cell-division failures. Here we describe the resultsof this new approach, including genetic and cytological analysisfor the 19 mutants isolated.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Culture conditions and strains:
All strains were cultured using standard techniques on nematodegrowth medium (NGM) seeded with Escherichia coli strain OP50(BRENNER 1974 ; LEWIS and FLEMING 1995 ). Temperature-sensitivemutants were grown at either 16° (permissive temperature)or 25° (restrictive temperature) and most other strainsat 20°.

All strains were derived from the wild-type Bristol strain N2.The following mutations, descriptions of which can be foundin HODGKIN et al. 1988 , HODGKIN 1997 , or in cited references,were used: LGI:dpy-5(e61), fer-1(hc13) (WARD and MIWA 1978 ),sem-2(n1343), mex-3(zu155), let-541(h886) (MCKIM et al. 1992), let-536(h882) (MCKIM et al. 1992 ); LGII:mel-11(it26), mel-9(b293),let-240(mn209), let-31(mn31), zyg-1(b1), dpy-10(e128), let-251(mn95),mel-15(it38), mel-22(it30), rol-1(e91), lin-5(e1348), let-266(mn194),spe-8(hc40), let-239(mn93), let-23(sy10), let-252(mn100), let-19(mn19),let-238 (mn229), evl-20(ar103); LGIII: unc-32(e189), plg-1(e2001),ooc-4(e2078), cul-1(e1756) (KIPREOS et al. 1996 ); LGIV: emb-3(hc59),let-54(s44), mes-6(bn66), gon-1(q518), gon-4(e2575), mel-24(ct59),emb-26(g47), emb-31(g55), unc-5(e53), let-296(s1250), let-292(s1146),let-297(s1989), let-71(s692), let-64(s216), let-73(s685), let-655(s1748),evl-7(ar108), fem-1(e1991), spe-27(it132); LGV: dpy-11(e224),myo-3(st386), ego-3(om40); and LGX: lon-2(e678). Rearrangements:hDf10, nDf24, nDf25, nDf30, qDf7, qDf8, maDf4, mnDf16, mnDf68,mnDf89, nDf40, nT1(IV;V), nDf41, eDf19, mDf7, sDf23, stDf7,stDf8, ctDf1, and nDf42.

Isolation of ts Stu mutants:
Two procedures were used to isolate ts Stu mutants. Both werebased on methods described for the isolation of maternal-effectlethal (Mel) mutants (PRIESS et al. 1987 ; KEMPHUES et al.1988B ). The basic approach involves the use of a strain carryinga mutation that prevents egg laying, such as sem-2(n1343). Thesehermaphrodites are still capable of internal self-fertilization,and the embryos that are produced accumulate in the uterus,where they hatch. The trapped larvae feed on maternal tissueand transform the mother into a carcass of writhing larvae boundby an unpalatable cuticle (bag-of-worms phenotype), from whichthe offspring eventually escape. Mutations that block the productionof viable offspring allow sem-2 hermaphrodites to survive. Amongthe survivors, hermaphrodites homozygous for a maternal-effectlethal mutation can be identified by the presence of a distendeduterus full of dead refractile fertilized eggs. In contrast,sterile mutants lack fertilized eggs—but, depending onthe severity and type of mutation, they may possess oocytesand sperm (fertilization-defective), lack oocytes and/or sperm(gametogenesis-defective) or lack a normal somatic gonad (gonadogenesis-defective).

Method 1: A population of sem-2 animals was treated with 40 mM ethyl methanesulfonate(EMS) essentially as described by BRENNER 1974 . Twenty-fiveto 50 mutagenized animals were picked to individual 60-mm platesand allowed to produce an F₁ generation at 20° or 25°.From each culture, 12 F₁ hermaphrodites at the L4 larval stagewere picked to individual wells of 12-well tissue-culture platescontaining NGM media seeded with E. coli OP50. At this point,all animals were incubated at 25°. When a young F₃ generationwas visible, plates were screened under a dissecting microscopefor surviving F₂ adults. Wells containing F₂ Stu animals werescored as positive. Mutations were recovered from heterozygotesin the F₃ population and maintained by picking 8 to 12 animalsto individual plates and scoring each for the production ofone-quarter Stu progeny. At the same time, lines were testedfor temperature sensitivity by individually transferring 6 to8 gravid F₃ animals to 16° and scoring their offspring forthe Stu phenotype. Lines that produced Stu animals at low temperaturewere discarded; those in which Stu animals were not detectedwere tested again. Lines in which the Stu phenotype was reproduciblyabsent at low temperature were retained, and an attempt to derivea homozygous line at 16° was made. In all but one case (thatof abc-1), we were able to establish a homozygous line. At 25°,abc-1 homozygotes possessed a strong Stu phenotype, while atlow temperature they developed into fertile adults that producedonly dead eggs. To propagate abc-1, we placed it over the balancerchromosome nT1(IV;V), which confers dominant uncoordinated andrecessive lethal phenotypes (EDGLEY et al. 1995 ). This balancedstock provided a source of abc-1 homozygotes for most of thework described in this article.

Using Method 1, we screened 3678 F₁ animals, or 7356 haploidgenomes, for a ts Stu phenotype and obtained the mutations stu-8(oj1),abc-1(oj2), spd-1(oj5), and zyg-1(oj7).

Method 2: A modification of Method 1 allowed us to screen for ts Stu mutantsmore efficiently. A key feature of Method 2 was that F₂ animalscarrying dead eggs were first identified at high temperature,then screened for temperature sensitivity by being transferredindividually to low temperature. Some of the animals that carriedan emb mutation were able to produce a few viable offspringafter the temperature decrease. These offspring were able tofound lines of homozygous animals that were screened for theStu phenotype.

The basic approach was as follows: Large quantities of sem-2worms were cultivated in liquid media at room temperature, essentiallyas described (SULSTON and HODGKIN 1988 ). The larger quantitieswere required partly because of the larger number of animalsthat could be screened and partly because this method employsa synchronization step in which most of the population is killedoff. Part of a culture containing many L4 larvae was spun downat 2500 rpm for 5 min, washed several times with M9 buffer (85.6mM NaCl, 42.3 mM Na₂HPO₄, 22 mM KH₂PO₄, 1 mM MgSO₄), and suspendedin fresh M9 buffer. The worm suspension was adjusted to 40 mMEMS, agitated for 3 hr at room temperature, then allowed torest undisturbed for an additional hour. Worms that had settledto the bottom of the tube were recovered, transferred to freshliquid-culture media, and grown with constant agitation at roomtemperature until many F₁ gravid adults were visible. The wormswere collected by centrifugation as before, washed several times,and suspended in 7.5 ml M9 buffer. To obtain a semisynchronizedpopulation of F₂ animals, the volume of the worm suspensionwas adjusted to 35 ml with a solution of 0.25 M KOH and 1.3%sodium hypochlorite. F₁ adults and larvae were dissolved inthe basic hypochlorite solution, but unhatched F₂ embryos survived.The isolated F₂ eggs were distributed at a density between 250and 750 eggs per 100-mm NGM plate, and the plates were placedat 16° until the majority of animals had reached the L4stage. At this time, plates were moved to 25°, where theyremained until most of the F₂ adults had been consumed. SurvivingF₂ hermaphrodites carrying dead eggs—and presumably homozygousfor an emb mutation—were picked individually to 12-welltissue-culture plates. The plates were stored at 16° for2 to 3 weeks, and each well was scored for the presence of viableF₃ animals. Lines were retested for the Emb phenotype by shiftingfour L4 animals to 25°. Secondary testing revealed manyof the lines to be false positives, probably the result of syntheticeffects (many independent mutations contributing to the Melphenotype), single mutations with a variable phenotype, or pickingerrors. Lines with a reproducible Emb phenotype were testedfor the presence of the Stu phenotype. This was accomplishedby examining any surviving adult progeny from the secondaryEmb test or by shifting carcasses full of young larvae to hightemperature. Lines that displayed both the Emb and Stu phenotypeswere retained.

The number of haploid genomes screened was estimated as follows:First, the frequency of F₁ animals carrying an emb mutationwas determined by picking gravid F₁ adults to single-culturewells just before the synchronization step. These animals wereexposed to the same temperature regime as the isolated F₂ eggs.F₁ mothers heterozygous for an emb mutation were identifiedby examining their offspring for individuals carrying dead eggs.We found that under these conditions, approximately one in threeF₁ hermaphrodites carried an emb mutation. Thus, for each survivingF₂ adult picked to low temperature, the equivalent of threeF₁ animals, or six haploid genomes, were screened. As we testedapproximately 7900 F₂ animals for temperature sensitivity, weestimate that 47,400 haploid genomes were screened using Method2. The ts mutations stu-9(oj13), stu-10(oj14), stu-11(oj18),stu-12(oj21), slo-1(oj23), stu-13(oj24), stu-14(oj26), stu-15(oj28),spd-2(oj29), stu-16(oj30), stu-17(oj31), stu-18(oj32), stu-19(oj33),cyk-2(oj34), and spd-3(oj35) were identified with this approach.

It should be stressed that the frequency with which ts Stu mutationswere identified using Method 2 probably underestimates the frequencyat which they were induced by EMS mutagenesis. Animals homozygousfor a ts emb mutation would not have been identified had theyfailed to produced progeny after the shift to low temperature.This could have occurred if the effect of a ts mutation wereirreversible or if the F₂ mother had run out of sperm priorto the temperature decrease.

Backcrossing, mapping, and complementation analysis:
All mutations were backcrossed at least twice to N2 stocks toremove the sem-2 marker and any extraneous mutations producedduring mutagenesis. Selection of backcrossed lines was basedon expression of either the Stu or Emb phenotype; in all cases,the unselected phenotype cosegregated, indicating that the twophenotypes were linked. Assignment of mutations to specificchromosomes was performed as described by BRENNER 1974 , usingthe following markers: dpy-5 I, rol-1 II, unc-32 III, unc-5IV, dpy-11 V, and lon-2 X. Despite repeated attempts, we werenot able to detect linkages between any of these markers andthe stu-11 mutation. We have decided to include stu-11 in thework presented here to provide the most complete descriptionof the screening results. Once a mutation was assigned to aspecific chromosome, we determined its position within the linkagegroup using two- and three-factor mapping techniques (BRENNER1974 ). In these crosses, Stu mutations were followed by scoringeither the sterile phenotype or the Emb phenotype. The map positionof each Stu mutation shown in Figure 1 was established by scoringa minimum of 35 recombinant chromosomes. All raw mapping datahave been submitted to the C. elegans genomic database AceDB(EECKMAN and DURBIN 1995 ).

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Figure 1. Positions of Stu mutations in a simplified genetic map of C. elegans. Each holocentric chromosome is depicted as a horizontal line, with the designated center indicated by a solid oval. The positions of selected genes are indicated by vertical lines; those identified in this screen are shown in a larger font. The mutation oj7 was only partially mapped before it was determined to be an allele of the zyg-1 gene. Thus, the previously established map position of zyg-1 is shown. The positions and extents of chromosomal deficiencies are indicated by the shaded bars beneath the corresponding chromosomes. In some cases, a deficiency appeared to overlap the position of a Stu mutation that it complemented; the unshaded area indicates the extent of overlap. In other cases, a deficiency appeared not to overlap the position of a Stu mutation that it failed to complement; the distance between the deficiency breakpoint and the Stu mutation is indicated by a solid bar.

To confirm the positions obtained with three-factor mapping,Stu mutations were tested for complementation with genetic deficienciesthat mapped within the regions of interest. Stu mutations werealso tested for allelism with closely linked (0.25–1.0map units) mutations known to confer a sterile, Stu, lethal,Mel, or Emb phenotype (see Table 1). Noncomplementation wasindicated by the presence of sterile or Stu progeny. In caseswhere the test marker appeared to complement the Stu mutation,we verified the results by confirming the presence of fertileanimals carrying both the marker and the Stu mutation.

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Table 1. Complementation analysis

Penetrance tests:
To determine the types and frequencies of postembryonic defectscaused by Stu mutations, we exposed mutant animals to the restrictivetemperature at the completion of embryogenesis. Plates containingworms grown at 16° were scanned under the high-power lens(x160 total magnification) of a Wild Kombistereo dissectingmicroscope for unhatched eggs containing threefold embryos,a postmorphogenic state marked by an adultlike body plan, alength three times that of the eggshell, and extensive writhingactivity. Each embryo was placed in one well of a 12-well plate,and the plates were transferred to high temperature for severaldays. Each well was examined for the ultimate fate of the animal.Some animals arrested during larval development. These wereoften misshapen and necrotic, making it difficult to assignthem to one of the four (L1–L4) larval stages. Thus, weestimated stages on the basis of size alone and assigned animalsto one of the following classes: early larval lethal (L1/L2),midlarval lethal (L2/L3), or late larval lethal (L3/L4). Hermaphroditesthat developed to adulthood were scored for fertility. The absenceof fertilized eggs was scored as sterility regardless of theappearance of the adult: We did not distinguish between thepresence or absence of gametes or a normal somatic gonad. Someof the adults were also scored for vulval defects. This wasusually accomplished using the high-power lens of the dissectingmicroscope.

To measure penetrance of the Emb phenotype, homozygous L4 larvaeor young adults from each strain were picked individually to35-mm NGM plates at 25°. Twenty-four hours later, each animalwas removed and transferred to a second plate for an additional24 hr. Dead (unhatched) eggs were counted on both sets of plates1 day after adults were removed. As embryogenesis is completedin about 14 hr at this temperature (WOOD et al. 1980 ), eggsthat remained unhatched after 24 hr were scored as dead. Afterthe dead eggs had been counted, the plates were returned to25°, and the next day all viable progeny were counted, keepingtrack of the number of animals that had arrested at the L1 larvalstage. While in most instances animals that escaped embryoniclethality developed into sterile adults, for two mutations asignificant number of escapers arrested at the L1 stage. Thesecases are noted in Table 4. For this penetrance (P) test, aswell as the rescue and selfing tests described below, a minimumof four hermaphrodites from each line were brooded or crossed.

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Table 2. Postembryonic phenotypes caused by Stu mutations

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Table 3. Summary of mutant phenotypes

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Table 4. Embryonic lethal phenotypes: Penetrance and parental tests

Parental tests:
To determine whether embryonic lethality was caused by failedmaternal or zygotic expression of wild-type activity, mutantlines were subject to two additional tests. In the male rescue(R) test (WOOD et al. 1980 ), homozygous mutant hermaphroditeswere mated to wild-type males, and the viability of offspringwas compared to that of unmated control hermaphrodites (fromthe P test). A higher survival rate among the progeny of a matedhermaphrodite was interpreted as rescue.

The R test was performed in a manner similar to that of theP test. Each homozygous mutant L4 larva or young adult was placedat 25° in the presence of four N2 males. After 24 hr theadult males were removed, and the hermaphrodite was transferredto a second plate. After an additional 24 hr at 25°, thehermaphrodite was moved to a third plate. The first and thirdplates were placed at 16° immediately after the animalswere transferred. These were used to assess successful mating.The second plate was left at 25° for 24 hr. The viabilityrate was calculated from the number of dead eggs and live progenypresent on the second plate. To confirm that mating had takenplace, all three plates were examined for the presence of progenymales. For several strains, mating could not be confirmed inthis manner, as mutant hermaphrodites did not produce live progeny.In these cases, the test was performed using plg-1 males, whichdeposit a gelatinous plug over the vulva during copulation.Mating was confirmed by scoring for the presence of a plug atthe time males were removed.

To determine whether maternal expression of wild-type gene activitycould suffice for embryogenesis, we employed the selfing (S)test (WOOD et al. 1980 ). A hermaphrodite heterozygous for aStu mutation was allowed to self-fertilize at the restrictivetemperature, and the viability of offspring was determined asdescribed for the P test. Heterozygotes were obtained by matingN2 males with morphologically marked homozygous Stu mutant stocksand picking nonmarked offspring. The rate of survival amongthe homozygous mutant offspring indicated the degree of maternalrescue.

DNA staining:
Animals grown at 25° were washed off seeded plates withM9 buffer and transferred to a microfuge tube. The animals werewashed several times with M9 buffer and fixed in 100% methanolfor 10 min at room temperature. Worms were removed from thefixative by centrifugation and stained in a solution of 0.5µg/ml 4',6-diamidino-2-phenylindole (DAPI) for 10 minat room temperature. The specimens were mounted on a microscopeslide, and images were obtained under epifluorescence illuminationusing a Photometrics (Tucson, AZ) SenSys KAF 1400 CCD camera.

Multiple focal plane time-lapse imaging:
Early development of mutant embryos was analyzed with a systemcapable of making time-lapse differential interference contrast(DIC) images of multiple focal planes (THOMAS et al. 1996 ).The system utilized for these studies contained a Nikon (Melville,NY) Optiphot-2 microscope mounted with a Hamamatsu (Bridgewater,NJ) C2400 video camera. The video signal from the camera wasfed to an AG-5 frame-grabber card (Scion Corporation, Frederick,MD) installed in a Macintosh PowerPC 7600 computer. The AG-5card supported both frame averaging and contrast enhancement.Automated focus control was obtained using a stage motor drivenby a Ludl MAC 2000 controller. The controller was connectedto the computer via the serial port. The four-dimensional (4D)image acquisition, data translation, and viewing and analysisapplications used in these studies were written by CHARLES THOMASof the Integrated Microscopy Resource (IMR), University of Wisconsin.All software is available free of charge at the IMR Website,http://www.bocklabs.wisc.edu/imr/home.htm.

To prepare embryos for 4D analysis, mutant animals at the L4larval stage or older were shifted to 25° for approximately24 to 36 hr. Young embryos were quickly dissected from gravidmothers in egg salts (118 mM NaCl, 48 mM KCl, 2 mM CaCl₂, 2mM MgCl₂, and 5 mM HEPES, pH 7.4) and transferred by mouth pipetonto a cushion of solidified 3% agarose in egg salts that hadbeen cast on a glass slide. A coverslip was placed gently overthe drop, the edges were sealed with molten vaseline, and theslide was transferred to the microscope. All recordings wereperformed at 25°. Temperature was controlled via the roomthermostat or locally, using a hair dryer equipped with a feedbackthermocouple to heat the microscope stage.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Identification of a novel set of conditional cell-division mutations:
We have employed a new approach to identifying conditional cell-divisionmutations in C. elegans that is based on expression of two phenotypesknown to be associated with cell-division failure. NineteenEMS-generated ts mutations that conferred both Emb and Stu phenotypeswere identified. Eighteen of these mutations were positionedon the genetic map using two- and three-factor mapping techniques(MATERIALS AND METHODS). Where possible, the positions wereconfirmed using genetic deficiencies that mapped within theappropriate regions. The mutations mapped to all five autosomesand the X chromosome (Figure 1). Closely linked Stu mutationswere tested for allelism, and in all cases the mutations werefound to complement one another. Thus, these 18 mutations define18 distinct genes.

To determine whether any of these 18 Stu mutations representednew alleles of previously identified genes, complementationtests were performed between Stu mutations and any closely linkedmutation known to possess a sterile, Stu, lethal, or Emb phenotype.The results of these complementation tests are summarized in Table 1. Despite exhaustive testing, in only one case did wefind that a Stu mutation failed to complement a known mutation.The mutation oj7 failed to complement zyg-1(b1) (Table 1). Weconclude that the new approach is capable of identifying manynew genes.

Stu mutations affect many aspects of postembryonic development:
The lin-5 and lin-6 mutations block postembryonic cell division,leading to a Stu phenotype (ALBERTSON et al. 1978 ; HORVITZand SULSTON 1980 ; SULSTON and HORVITZ 1981 ). To estimateto what extent these new mutations might affect the postembryoniccell divisions, we exposed mutant animals to the restrictivetemperature for the entirety of postembryonic development andscored for viability, fertility, and vulval morphology.

Nearly all mutations conferred some degree of larval lethality(Table 2 and Table 3). In particular, abc-1, spd-2, and stu-18animals exhibited high levels of larval lethality, suggestingthat these genes might be required postembryonically for viability.However, for spd-2 and stu-18, we found that similar percentagesof animals arrested as larvae at 16° and 25°—indicatingthat, in these cases, larval lethality occurred independentof the temperature shift. It is possible that at 16°, manyspd-2 and stu-18 animals experience a low level of random cell-divisionfailure; some might be healthy enough to hatch but too sickto develop beyond the larval stages.

For 10 mutant lines, the penetrance of the sterile phenotypewas nearly complete: all or almost all of the animals that developedto adulthood were sterile. Among this group of mutants werethose with the most severe defects. stu-8, abc-1, zyg-1, stu-15,and spd-2 animals were extremely uncoordinated, lacked a normalgonad, and possessed highly penetrant vulval defects (Table2 and Table 3). Adult stu-9, stu-10, stu-19, and cyk-2 hermaphroditeswere also uniformly sterile, but the gonad appeared to be welldeveloped, and the Unc phenotype tended to be weak and variable.For spd-3, the sterile phenotype was nearly absolute: only oneof 38 adults scored was fertile.

This group of mutations strongly affected another aspect ofpostembryonic development that requires cell division: vulvaldevelopment (Table 2). In general, the penetrance of vulvaldefects correlated with the severity of the Stu phenotype. Allzyg-1 animals failed to form a normal vulva; most were scoredas vulvaless (Vul), as they lacked a recognizable structurealtogether. A few contained an apparently nonfunctional vulvathat protruded from the body (Pvl), and one possessed multiplevulvae (Muv). Likewise, the other lines with a strong Stu phenotype,stu-8, abc-1, stu-15, and spd-2, contained few animals witha normal vulva. Among these animals the most common defect wasa Pvl phenotype. The mutations stu-9, stu-10, stu-19, and cyk-2conferred milder Stu phenotypes, and accordingly the vulvaldefects were less penetrant. The only exception to the strongpositive correlation between the Stu and vulva phenotypes wasspd-3. These animals possessed a somewhat mild Stu phenotypecapable of nearly normal movement but exhibited a uniform Vulphenotype.

The remaining nine lines, spd-1, stu-11, stu-12, slo-1, stu-13,stu-14, stu-16, stu-17, and stu-18, exhibited a lower penetranceof the sterile phenotype. Among these mutants, spd-1 and stu-16animals exhibited a number of very strong defects. Most spd-1adults were thin, lacked a functional gonad, and exhibited verypoor mobility. Twelve of the 69 spd-1 adults scored were ableto produce a few dead embryos. However, these fertile spd-1animals maintained most of the characteristics of their sterilesiblings: they were thin, incapable of normal movement, andpossessed vulval defects identical to those of sterile siblings.This suggests that the gonadal lineages are less sensitive tothe spd-1 mutation than are the vulval or neuronal lineages.Many stu-16 animals also exhibited striking defects in motilityand development of the vulva and gonad. Like spd-1, the Uncphenotype of stu-16 appeared more penetrant than the sterilephenotype (data not shown).

Despite being isolated on the basis of a nearly complete Stuphenotype, four of the mutant lines exhibited low penetranceof this phenotype under the test conditions. A majority of stu-11,stu-12, stu-13, and stu-18 animals developed into fertile adults.One possible explanation for this discrepancy was the fact thatthe animals were shifted to the restrictive temperature earlierin development during the screen than during these tests. Totest this possibility, we again shifted stu-11, stu-12, stu-13,and stu-18 animals to 25° earlier in development. Underthese conditions, all four lines exhibited a higher penetranceof the sterile phenotype. Nearly all stu-11 and stu-18 animalsand most stu-13 animals developed into sterile adults (see footnoteto Table 2). These results indicate that, in these cases, eitherthe sterility results from defects in early embryogenesis oran earlier shift is required to sufficiently reduce the amountof wild-type gene activity prior to postembryonic development.

Vulval defects were evident among the nine lines with partiallypenetrant sterility. Again, the penetrance of vulval defectsexhibited a positive correlation with the severity of the Stuphenotype. On the basis of appearance, the mutations spd-1 andstu-16 conferred the strongest Stu phenotypes; these mutationsalso had the highest penetrance of vulval defects (Table 2).All spd-1 hermaphrodites and many stu-16 hermaphrodites exhibiteda Pvl phenotype. In contrast, the mutations stu-11, stu-12,slo-1, stu-13, stu-14, and stu-18 conferred mild Stu phenotypesand few vulval defects. Once again, a single exception to thecorrelation between these two phenotypes was noted: stu-17 hermaphroditespossessed a mild Stu phenotype and a high incidence of the Vulphenotype. These results suggest that, in general, the vulvallineages are affected to the same degree by these mutationsas are the gonadal/germ-line lineages.

We also noted that two of the mutations conferred an additionalphenotype. A higher than expected number of males were presentamong stu-10 and slo-1 adults. In a wild-type population, males(genetically XO) are produced spontaneously at an approximatefrequency of one in 500 through nondisjunction of the X chromosome(HODGKIN et al. 1979 ). Among 56 stu-10 adults scored, 10 weremale, and among 64 slo-1 adults, four were male. Unlike theother phenotypes scored in this test, this Him (high incidenceof males) phenotype was almost certainly not because of a postembryonicdefect but was instead because of defects in meiosis that occurredat the nonrestrictive temperature. Like the Him phenotype, theStu phenotype may be because of chromosome missegregation; thus,stu-10 and slo-1 mutants may be defective in both meiotic andmitotic chromosome segregation.

To determine whether the Stu phenotype is a reliable indicatorof postembryonic cell-division defects, we stained zyg-1 andabc-1 adults with the DNA-specific dye DAPI. Both zyg-1 andabc-1 animals contained many abnormal nuclei. In particular,we noted the presence of abnormal nuclei in the ventral nervecord and intestine, two tissues in which postembryonic nucleardivisions occur (SULSTON and HORVITZ 1977 ). In wild-type animals,the adult complement of ventral cord nuclei is arranged in alongitudinal row that runs along the ventral midline. In DAPI-stainedwild-type animals, these nuclei appeared of uniform size andintensity (Figure 2A). In contrast, in zyg-1 adults, many ventralcord nuclei were abnormally large and appeared to be polyploid,perhaps as a result of a nuclear-division defect. In abc-1 adults,intestinal cell nuclei exhibited an unusual morphology: nucleiwere elongated and contained thin, wispy extensions (Figure2C). These threads of DNA suggest a defect in chromosome segregation—and,as shown in Figure 4H, abc-1 embryos appeared to possess arelated defect. In addition, zyg-1 and abc-1 animals possesseddefects in gonadal and vulval nuclei, indicating that thesemutations may lead to a general block in postembryonic celldivision.

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Figure 2. DAPI-stained wild-type and Stu mutant animals. Anterior is at right in all panels. (A) Wild type. Arrowheads indicate the single row of ventral cord nuclei that runs along the bottom edge of the animal. Inset, magnified view of nuclei. (B) zyg1(oj7). Arrowheads indicate polyploid nuclei within the ventral cord. Inset, magnified view of nuclei. (C) abc-1(oj2). Arrowheads indicate elongated intestinal cell nuclei. Inset, magnified view of an intestinal cell nucleus. Bar in B corresponds to 50 µm for A and 100 µm for B and C.

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Figure 3. Early embryonic development of C. elegans. (A) Pronuclear migration. The oocyte pronucleus (o) is traveling toward the sperm pronucleus (s) at the posterior of the embryo. A pseudocleavage furrow (visible at mid-egg length) forms but does not complete and regresses shortly after the oocyte pronucleus passes through it. (B and C) Rotation of the centrosome-pronucleus complex. The two pronuclei meet at the posterior then move to the center, where they undergo a 90° rotation to position the centrosomes (arrowheads) on the anterior-posterior axis. (D and E) First cleavage. The spindle initially forms at the center of the cell but becomes eccentrically placed toward the posterior during anaphase. The ensuing furrow divides the cell into a larger anterior cell (AB) and a smaller posterior cell (P₁). Note that the AB centrosome is spherical, while the P₁ centrosome is disc shaped (arrowheads in E). (F) Second division. The AB spindle forms first and is perpendicular to that of P₁. The different spindle orientations are a consequence of different patterns of centrosome movements (HYMAN and WHITE 1987

). The centrosome pairs of both AB and P₁ are initially aligned along the same transverse axis—where, in AB, they establish the poles (arrowheads) of the mitotic spindle. However, prior to spindle formation in P₁, the centrosomes (arrows), together with the nucleus, rotate by 90° so that the P₁ spindle forms on the anterior-posterior axis. Anterior is to the left in all panels. Bar, 10 µm.

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Figure 4. Representative cytological defects of Stu mutant embryos. (A) An spd-1(oj5) embryo with an abnormal anaphase spindle. In six of six spd-1 embryos observed, the first mitotic spindle broke at the midpoint into two half-spindles. (B and C) In five of eight spd-1 embryos, a late-stage cell-division defect was observed. A representative case is shown in B. Two daughter-cell nuclei (arrowheads) of an spd-1 embryo are separated by a nearly complete cytokinetic furrow. Nine minutes later (C) the furrow has regressed, and the daughter nuclei lie apposed. (D) Aberrant spindle assembly in a zyg-1(oj7) embryo. The nuclei in both cells have broken down, but monopolar rather than bipolar structures appear to have formed. Of eight zyg-1 embryos observed, three exhibited a similar defect during the first cell cycle and five during the second. (E) All spd-2(oj29) zygotes exhibit early developmental defects. The two pronuclei meet near the center of the embryo, and centrosomes are not apparent. (F) Failure to assemble a mitotic spindle in an spd-2 embryo during first mitosis. In all six spd-2 embryos observed, a mitotic spindle was absent. In the embryo shown, the DNA is visible as a clearing at the center of the cell, and multiple cytokinetic furrows can be seen at the periphery. (G) Abnormal first mitosis of a spd-3(oj35) embryo. The spindle is closely associated with the posterior cortex. A furrow is visible at the anterior end and is approximately parallel to the spindle. A second furrow can be seen to bisect the spindle (arrowhead). Similar defects were observed in all 11 spd-3 embryos examined. (H) Nuclear bridge of a two-cell abc-1(oj2) embryo. The re-forming nuclei lie close to the former cleavage plane and appear connected. Of five abc-1 embryos observed, all exhibited a similar defect. (I) Cytokinesis failure in a cyk-2(oj34) embryo. Two apposed daughter nuclei can be seen at the posterior of the embryo. An incomplete furrow (arrowhead) is visible nearby. Incomplete cytokinesis was observed in seven of 14 cyk-2 embryos. (J) Abnormal nuclear positioning as observed in seven of 12 cyk-2 embryos. (K) A stu-10(oj14) embryo in which the P₁ centrosome-nucleus complex has failed to rotate. The AB spindle is not completely visible in this focal plane. The centrosomes are indicated by arrowheads. Abnormal alignment of the P₁ centrosome-nucleus complex was observed in four of five stu-10 embryos and three of six stu-11 embryos. (L) Abnormal centrosome morphology in a two-cell stu-18(oj32) embryo. In 11 of 12 stu-18 embryos examined, the P₁ centrosome did not flatten to the extent observed in wild-type embryos. Bar, 10 µm.

Stu mutations affect embryonic development:
To determine to what extent these genes affect embryogenesis,we quantified the effect that each mutation had on embryonicviability. Homozygous mutant L4 larvae were shifted individuallyto 25°, and the percentage of viable embryos produced duringtwo successive 24-hr periods was determined. For many strains,the percentage of viable embryos was higher during the first24 hr than the second 24 hr, indicating that gene activity slowlydecayed after the temperature shift. To avoid these confoundingperdurance effects, we have chosen to consider the viabilityrate only during the second 24-hr period. These values are shownin Table 4.

Mutations ranged in their effects on embryonic viability. Ninemutations were found to strongly affect viability: hermaphroditeshomozygous for abc-1, zyg-1, stu-15, spd-2, stu-19, or spd-3did not produce any viable progeny, while spd-1, slo-1, andstu-13 mothers produced only a few survivors. Perhaps not surprisingly,this group contained many of the mutations with the strongestStu phenotypes. Given the strong embryonic and postembryonicphenotypes of mutations abc-1, zyg-1, stu-15, and spd-2, itseems likely these mutations affect genes that are essentialfor development of many tissues.

Moderate effects on viability were observed for stu-8, stu-9,stu-10, stu-11, stu-12, stu-14, stu-16, stu-17, stu-18, andcyk-2; between 10 and 75% of the embryos produced by these strainshatched. In the cases of stu-16 and stu-18, the developmentof most of the survivors was arrested shortly after hatching;only 0.5% of stu-16 animals and 0.7% of stu-18 animals wereviable beyond the first larval stage (Table 4). Many of themutations with an incomplete Emb phenotype also had a mild Stuphenotype. These mutations might be hypomorphs, the weak phenotypesbeing because of residual gene activity. Alternatively, somemutations might be nulls: the corresponding genes might havepartially redundant functions or play nonessential roles. Gene-dosagestudies will be needed to address these possibilities. Nevertheless,as judged by their effects on early and late developmental events,these mutations probably define genes that function in manylineages.

Parental tests:
All 19 Stu mutations conferred an Emb phenotype, suggestingthat these genes might function throughout development. Duringthe first several rounds of division, development of the embryois largely controlled by maternal transcripts and proteins (WOOD1988 ). As a consequence, it is the genetic makeup of the mother,and not that of the embryo, that is relevant to this periodof development. We performed two parental tests to determineto what extent these Emb phenotypes were influenced by maternalgenotypes.

To determine whether the embryonic lethality associated withany of these 19 Stu mutations was a strict consequence of maternalgenotype, we performed a male rescue (R) test (WOOD et al. 1980). In the R test, a homozygous mutant hermaphrodite is matedwith wild-type males at the restrictive temperature. The percentageof viable embryos produced by mated hermaphrodites is determinedand compared to that of unmated controls. A significant increasein viability among the test embryos would indicate that maternalexpression of the gene is not necessary; that is, the wild-typeallele carried by the heterozygous offspring could suffice.

To determine whether maternal expression was sufficient forembryogenesis, we employed the S test (WOOD et al. 1980 ). Inthe S test, viability is measured among the self-progeny ofhermaphrodites heterozygous for the mutation of interest. Allof the progeny will be supplied with wild-type maternal product.However, 1/4 of the progeny of a heterozygous mother will behomozygous, and thus unable to express wild-type gene productzygotically. Hence, the survival rate of this population indicatesthe degree to which maternally supplied gene products play arole in embryogenesis.

The results of the S test were striking in their uniformity:animals heterozygous for any one of the Stu mutations producedsignificantly more than 75% viable embryos (Table 4). Thus,in all cases, maternal gene activity was sufficient to allowmost of the homozygous offspring to survive. While it was clearfrom the results of the S test that many zyg-1 homozygotes survivedto hatching, mothers heterozygous for zyg-1 still produced moderateamounts (10.4%) of inviable offspring. When we examined thesurviving progeny, we found that Stu animals still accountedfor 25% of the offspring. As the homozygous offspring were notdisproportionately affected, the lethality may be interpretedas a semidominant maternal effect.

In contrast to the results of the S test, those of the R testrevealed differences among the Stu mutations. For 13 lines,stu-8, abc-1, spd-1, zyg-1, stu-9, stu-10, stu-11, stu-12, stu-14,spd-2, stu-17, stu-19, and spd-3, mating mutant hermaphroditesto wild-type males did not significantly increase embryonicviability (Table 4). For five of these genes, abc-1, zyg-1,spd-2, stu-19, and spd-3, the results were clear-cut: matedand unmated hermaphrodites did not produce any viable progeny.These genes exhibit a strict requirement for maternal expression,suggesting that they function early in development. In fact,as noted in the following section, four of these five mutantswere found to exhibit defects during the first several roundsof cell division. For the other eight mutants, mated and unmatedhermaphrodites produced similar nonzero levels of viable offspring,indicating that embryonic lethality is not rescued strongly—ifat all.

For six mutations, maternal expression was found not to be necessaryfor embryonic viability. When mated to wild-type males, slo-1,stu-13, stu-15, stu-16, stu-18, and cyk-2 hermaphrodites producedsignificantly more viable progeny than unmated controls (Table4). The lack of strict maternal effects suggests that thesegenes may not be necessary for the earliest period of development,before zygotic transcription is activated. Consistent with thishypothesis, we have not detected any serious defects duringthe first several cell cycles of stu-13, stu-15, stu-16, orstu-18 embryos. slo-1 and cyk-2 did confer early defects (seebelow), but in these cases the defects were somewhat variable,and the increases in viability observed in the rescue testsmay be accounted for by the number of animals that escaped theseearly defects.

Stu mutant embryos possess cell-division defects:
To determine what cytological defects were associated with thesemutations, we analyzed the early divisions of mutant embryos.Mutant L4 larvae or adults were shifted to the restrictive temperatureand allowed to produce embryos for approximately 16 to 24 hr.Young embryos were isolated from gravid mothers, and multiple-focal-planetime-lapse (i.e., 4D) data sets of the first several roundsof division were constructed. As the actual defects observedcould sometimes vary between embryos, we recorded a minimumof three embryos from each mutant line. We report here onlythe defects observed multiple times. For purposes of comparison,early development of a wild-type embryo is shown in Figure3.

Ten of the mutants showed striking defects during the earlycleavages (Figure 4), with the most common defect being cell-divisionfailure. Embryos produced by mothers homozygous for spd-1, zyg-1,spd-2, cyk-2, or spd-3 exhibited reproducible failure of cellcleavage. These mutants could be divided into two groups onthe basis of spindle morphology: spd-1, zyg-1, spd-2, and spd-3embryos possessed abnormal mitotic spindles, while the spindlesof cyk-2 embryos appeared normal. Among the other mutants, oneexhibited a defect in nuclear division (abc-1), two exhibiteddefects in the positioning of the mitotic spindle (stu-10 andstu-11), one exhibited a defect in spindle morphology not associatedwith cytokinesis failure (stu-18), and another exhibited a defectin the timing of developmental events (slo-1). A more detaileddescription of the cytological phenotypes of these 10 mutantsfollows.

The spd-1, spd-2, spd-3, and zyg-1 mutations affect the mitotic spindle:
Embryos produced by spd-1 mothers exhibited a defect in thelate stages of cytokinesis. Some cells initiated furrowing normallybut failed in the final pinching off of the membrane. Indeed,in those divisions that ultimately failed, cytokinesis seemedto be complete before regression of the furrow (Figure 4B and Figure C). These embryos also exhibited a defect in the behaviorof the mitotic spindle. Through most of mitosis it appearednormal, but late in anaphase it broke at the midzone into twohalf-spindles (Figure 4A). While it is possible that the cytokinesisdefect is a direct consequence of the spindle defect, we havenot yet investigated the relationship between these two events.

Most zyg-1 embryos appeared normal through interphase of thesecond cell cycle. Invariably, however, both blastomeres oftwo-cell embryos exhibited an abortive mitosis and failed todivide (Figure 4D). Neither a metaphase plate nor a bipolarspindle was apparent following nuclear envelope breakdown. Instead,the DNA remained as a single large mass in the center of thecell throughout mitosis, ultimately being incorporated intoan odd number of small nuclei. A smaller fraction of the embryosexhibited a similar pattern of defects during the first cellcycle. In all embryos, nuclear envelopes continued to disassembleand re-form at regular intervals, indicating that the cell cycleprogressed unabated. Closer inspection of the time-lapse datasets revealed a defect in centrosome duplication or separation.In all cases, an aberrant mitosis was preceded in interphaseby the formation of a single, abnormally large microtubule organizingcenter (MTOC). Typically, centrosomes are visible by means ofDIC optics as granule-free regions associated with nuclei. ThisMTOC failed to resolve into two daughter centrosomes and remainedpositioned on the previous division axis. It was not clear fromthe DIC images whether the centrosome had divided, but underimmunofluorescence microscopy, microtubules appeared to be organizedaround a single large centrosome (data not shown), consistentwith a defect in duplication.

Failure to assemble a mitotic spindle was also observed in spd-2embryos (Figure 4E and Figure F). As in zyg-1 embryos, themass of DNA remained in the center of the cell, while the embryoscontinued to cycle through periods of nuclear envelope breakdownand re-formation (Figure 4F). The defect in spindle morphogenesiswas accompanied by several other defects, the most obvious ofwhich was the apparent absence of an MTOC. In contrast to wild-typezygotes, in which the pronuclei-associated centrosomes are observableby means of DIC optics (Figure 3B and Figure C, arrowheads),such structures were not visible in spd-2 zygotes. The pronucleiof these embryos also exhibited defects in a number of microtubule-associatedmovements (STROME and WOOD 1983 ; HYMAN 1989 ; HYMAN and WHITE1987 ). That is, the sperm pronucleus did not remain anchoredat the posterior pole during pronuclear migration, but insteadmoved to the center of the zygote like the acentrosomal femalepronucleus. Once apposed, the two pronuclei did not rotate by90°, as occurs in wild-type embryos (compare Figure 3Band Figure 4E). Thus, spd-2 embryos exhibited a number of defects,all of which can be attributed to a defect in microtubule organization.

Embryos produced by spd-3 mothers exhibited several defects.Polar bodies were often not properly extruded, leaving severalmaternally derived nuclei at the anterior of the zygote. Duringthe ensuing interphase, these sister pronuclei co-migrated towardthe sperm pronucleus at the posterior of the embryo. Mitoticspindles were difficult to detect by means of DIC optics, butin all embryos examined, the first spindle appeared to format an angle to the anterior-posterior (A-P) axis and remainedtightly associated with the posterior cortex throughout mitosis(Figure 4G). Two furrows were often observed: a unilateral furrowthat bisected the spindle and a pseudocleavage furrow at somedistance from and parallel to the spindle. Typically, firstdivision failed, resulting in a multinucleate embryo.

The abc-1 mutation affects chromosome segregation:
Embryos produced by abc-1 mothers possessed what appeared tobe morphologically normal spindles. However, during telophaseit became evident that the DNA had not segregated properly.The re-forming daughter nuclei remained connected to one anotherby a bridge that spanned the final connection between the daughtercells (Figure 4H). This connection, however, did not affectcleavage, as the furrow did not regress. Following cleavage,daughter nuclei often remained tightly associated with the formerdivision plane. The connection between daughter nuclei is similarto that described for topoisomerase II mutants of yeast (HOLMet al. 1985 ; UEMURA et al. 1987 ) and may be explained bya failure to decatenate sister chromatids.

The cyk-2 mutation affects cytokinesis:
About half of the embryos produced by cyk-2 mothers possesseda defect in the late stages of cytokinesis (Figure 4I). Spindlemorphology appeared normal, and blastomeres underwent nucleardivision. Cytokinetic furrows formed but progressed slowly andoften failed to partition daughter nuclei. Incomplete furrowswere seen to regress. Many cyk-2 embryos exhibited other defectsas well. The positions of many nuclei were unstable and eccentric(Figure 4J), and the cytoplasm had an abnormal appearance, withgranules exhibiting increased Brownian motion. cyk-2 blastomeresoften lacked the well-defined contours of their wild-type counterparts,and the mutant embryos expanded to fill the entire volume ofthe eggshell.

The stu-10 and stu-11 mutations affect spindle positioning:
Two of the mutants exhibited abnormal positioning of the earlymitotic spindles. The mutations stu-10 and stu-11 caused similarincompletely penetrant defects at the two-cell stage (Figure4K). In 80% of stu-10 mutants and 50% of stu-11 mutants, thecentrosome-nucleus complex of the posterior cell, P₁, failedto rotate onto the A-P axis and remained in a transverse orientationuntil late in the cell cycle, when it appeared to be pushedonto the A-P axis by the elongating spindle of the anteriorcell, AB. In both cases, the centrosome-nucleus complex wasclosely associated with the anterior P₁ cortex. Although inboth mutants this was the most common defect, it was not theonly one: in a few stu-10 and stu-11 embryos, the centrosome-pronucleuscomplex did not complete rotation before first mitosis.

The stu-18 mutation affects centrosome morphology:
The only visible defect in stu-18 embryos was a failure of theposterior spindle pole to undergo a shape change at the endof the first asymmetric division. In wild-type embryos, thecentrosome inherited by the smaller P₁ cell flattens from asphere into a disc, whereas that of the larger AB cell remainsspherical (Figure 3E). The significance of the shape changeis not known, but it may be related to the close proximity ofthis centrosome to the cell cortex. In 11 out of 12 stu-18 embryosexamined, the posterior centrosome failed to flatten completely(Figure 4L). We are not certain of the immediate consequencesof such a defect and how the defect relates to the embryoniclethality of this strain, as stu-18 embryos continued to dividenormally during the period of observation. Nonetheless, we findthis phenotype intriguing, as centrosome flattening appearsto be a common feature of unequal cell divisions (DAN 1979 ; DAN and ITO 1984 ).

The slo-1 mutation affects the rate of development:
slo-1 embryos exhibited a phenotype completely different fromthat of the other mutants. These embryos appeared to developnormally but at a much slower rate than wild type. The longerthe mother spent at 25°, the more slowly the embryos appearedto develop. Mothers that spent the longest periods at 25°produced embryos whose development was arrested during the firstfew cell cycles. While development seemed otherwise normal,we were unable to rescue one of these animals by returning itto low temperature.

Mutants not exhibiting early defects:
Although examined extensively, stu-8, stu-9, stu-12–stu-17,and stu-19 embryos did not exhibit reproducible cytologicaldefects during the early divisions. Many of these mutationshad only moderate effects on embryonic viability, and thus theabsence of a recurring defect was not surprising. On the otherhand, several mutants had very strong (stu-13) or absolute (stu-15and stu-19) Emb phenotypes yet failed to exhibit an early defect.It is possible that for these strains, the actual defects arenot detectible by means of light microscopy. However, in thecases of stu-13 and stu-15, maternal gene activity was not foundto be necessary, indicating that these genes are not requiredfor early development. In the current study, we have analyzedmutant embryos only during the first several rounds of division.Analysis of the later stages of embryogenesis, including descriptionsof the terminal phenotypes, might be helpful in determiningthe cytological basis for these cases of embryonic lethality.

DISCUSSION

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Identification of new cell division genes:
We have described the isolation and initial characterizationof a set of ts cell-division mutants in C. elegans. Our approachwas based in part on the phenotypes exhibited by two cell-divisionmutations described previously. The lin-5(e1348) and lin-6(e1466)mutations block virtually all postembryonic cell divisions—theprincipal exceptions being a few rounds of division in the germline—including those of the gonad and ventral nerve cord(ALBERTSON et al. 1978 ; HORVITZ and SULSTON 1980 ; SULSTONand HORVITZ 1981 ). While these two mutations affect differentaspects of cell division, they confer similar Stu phenotypes,and neither affects viability. Thus, we reasoned that the Stuphenotype could be used to identify cell-division mutants whileavoiding other types of lethal mutants. Another common propertyshared by the lin-5 and lin-6 mutations is that neither affectsthe embryonic divisions. While there are several possible explanationsfor this specificity, it seems likely that the lack of embryonicdefects reflects maternal rescue of those cell divisions. Asour data show, all of the mutants we isolated can be maternallyrescued, indicating that most embryonic cell-division functionsare maternally provided.

In formulating our approach, we decided that it would be mostadvantageous to screen for ts mutations. We wanted to identifycell-division genes by screening for mutants with a Stu phenotype,but we did not want to analyze postembryonic cell-division defects.Instead, we preferred to study the effects of cell-divisionmutations on the early embryonic divisions. Conditional alleleswould allow us to inhibit maternally supplied gene activitiesand analyze the cytological effects of these mutations duringthis period. As the genes we were interested in were those encodingactivities fundamental to proliferative and/or determinativecell division, we believed that the desired mutants would exhibitdefects during all stages of the life cycle when cell divisionwas occurring. Thus, we envisioned that the desired mutantswould exhibit both an Emb and a Stu phenotype.

The results of the screen validate our approach. Nineteen tsmutations that conferred both Stu and Emb phenotypes were identified(Table 3). When analyzed for cytological defects, many mutantswere found to exhibit defects in cell division. These includedfailure to properly segregate DNA (abc-1), defects in placement(stu-10 and stu-11) and morphogenesis (zyg-1, spd-1, spd-2,and spd-3) of the mitotic spindle, defects in cytokinesis (spd-1,spd-2, spd-3, and cyk-2) and prolonged cell cycle times (slo-1).Although not all mutants were found to exhibit cell-divisiondefects, all remained viable when shifted to the restrictivetemperature postembryonically, arguing that none of the mutationsaffected essential metabolic functions. These results stronglysupport our assumption that the Stu phenotype can serve as areliable indicator of cell-division defects. However, we donot believe the Stu phenotype to be absolutely specific to cell-divisionfailure. Mutations affecting any developmental process requiredfor formation of the gonad and ventral nerve cord could conceivablyyield a Stu phenotype. For instance, genes with general rolesin cell differentiation could be mutated to a Stu phenotype.Despite exhaustive analysis of a number of mutant lines (stu-8,stu-9, stu-12–stu-17, and stu-19), we were unable to detectearly cell-division defects. It therefore seems probable thatat least some of the Stu mutations affect developmental processesother than cell division; only further analysis of the embryonicand postembryonic developmental defects associated with thesemutations will allow us to determine the types and frequenciesof defects that give rise to this phenotype. Nonetheless, whencombined with cytological analysis, the screen provides a verypowerful approach to identifying cell-division mutations inC. elegans.

A measure of success of any screen is whether it has identifiednovel genes. A large number of conditional emb mutations alreadyexist, and many of these confer gonadogenesis defects when exposedto the restrictive temperature postembryonically (HODGKIN 1997). While earlier screens were able to identify mutations thatconferred both Emb and Stu (or sterile) phenotypes, they didnot specifically focus on this group of polyphasic mutants (HIRSHand VANDERSLICE 1976 ; MIWA et al. 1980 ; CASSADA et al. 1981). We therefore reasoned that a screen designed specificallyto isolate such mutants would likely identify many new genes.Our results strongly support this notion: mapping and complementationtests have indicated that 17 of the 18 Stu mutations testeddefine novel genes.

Can we estimate the number of genes that can be mutated to aconditional Stu phenotype? As no two of the new mutations areallelic, we are unable to do so. However, the fact that we havenot obtained multiple alleles of any of the 18 mapped genessuggests that the screen is far from saturation. In fact, noneof the new mutations are allelic to lin-5 or lin-6 mutationsor to any one of three ts Stu mutations identified in an earlierscreen (LIVINGSTONE 1991 ).

Genetic analysis:
Our results indicate that the new mutants are diverse with respectto their requirements for maternal expression. Embryonic lethalityassociated with 13 mutants behaved like a strict maternal effect.Five such mutants exhibited a complete Emb phenotype, and fourof these possessed cell-division defects during the early cleavages—indicating,as expected, that genes with a strict maternal effect are likelyto be required for the earliest cell divisions. In contrast,six Stu mutations were found to have a partial parental effect,either parental or zygotic expression being sufficient for embryogenesis.Of these, three were found to possess early defects (slo-1,stu-18, and cyk-2). In situ hybridization studies have indicatedthat at least some zygotic genes are transcribed as early asthe four-cell stage (SEYDOUX and FIRE 1994 ); these three partialparental-effect mutations with early defects may thus definegenes that are expressed very early in development. On the otherhand, for some of these genes, the absence of a strict maternaleffect may be specific to the alleles tested; stronger allelesmay behave like strict maternal-effect lethal mutations.

Remarkably, for all Stu mutations, tests to determine whethera wild-type maternal allele was sufficient for embryogenesisyielded nearly identical results. For each of the 19 mutantstested, embryonic lethality was strongly rescued by the maternallysupplied gene product. This result was obtained irrespectiveof the strength of the mutation or of the process affected.Roughly 550 divisions occur during embryogenesis, and the resultsof the S test strongly suggest that all of these divisions areexecuted using predominantly maternally supplied factors. Ourresults have an important implication for identification ofcell-division mutants in C. elegans; that is, many such mutantswould likely not present as zygotic-effect embryonic lethals.

Cytological analysis:
In analyzing the early divisions of mutant embryos, we foundthat many of the mutations recovered in this screen conferredintriguing cell-division defects. Although the mutation setwas rather small, we did not notice a bias in the type of cell-divisionmutant isolated. The phenotypes observed were varied and includeddefects in chromosome segregation, spindle morphogenesis andalignment, centrosome duplication, and cytokinesis. Thus, aswe hypothesized, our approach is capable of identifying geneswith a broad range of cell-division functions.

The abc-1 mutation affects chromosome segregation:
The abc-1 mutation was unique in that it was the only memberof this set of mutations that appeared to primarily affect chromosomesegregation. During anaphase in abc-1 embryos, a thin bridgeconnected the separating DNA complements. This "anaphase bridging"is similar to the phenotypes described for topoisomerase IImutants of yeast (HOLM et al. 1985 ; UEMURA et al. 1987 ) andbarren (barr) mutations of Drosophila (BHAT et al. 1996 ). barrencodes a novel, chromosome-associated protein that interactswith Topoisomerase II and modulates its activity. During mitosisin barr embryos, centromeres move apart at anaphase, but sisterchromatids remain linked, suggesting that Topisomerase II andBarren protein act to decatenate chromatids at anaphase. Thephenotype of abc-1 mutants suggests that the product encodedby this gene may play a role in this process in C. elegans.We searched the GenBank Sequence Database for C. elegans Barrenand Topoisomerase II homologues. While a Barren homologue wasnot detected, several sequences with similarity to TopoisomeraseII were found, but none of these mapped in the vicinity of abc-1.

Four mutations affect spindle morphogenesis:
A distinct and dramatic anaphase defect was observed in spd-1mutant embryos. Although the spindle formed and behaved normallythrough most of mitosis, late in anaphase it bent at the midzone.Often it appeared to break, completely separating into two half-spindles.Associated with this phenotype was a late cytokinesis defect:furrows initiated normally but failed to complete. As not allcells that exhibited the spindle defect exhibited the cytokinesisdefect, we are not sure of the relationship between these twodefects. One possibility is that the cytokinesis defect is adirect consequence of disruption of the spindle midzone. Experimentsin tissue-culture cells suggest that in at least some cell types,the midzone appears to be required for cytokinesis (WHEATLEYand WANG 1996 ). Similarly, mutations in the gene encoding theDrosophila kinesin-like protein KLP3A disrupt the central spindlein spermatocytes and lead to defects in cytokinesis (WILLIAMSet al. 1995 ).

The zyg-1 and spd-2 mutations blocked formation of a bipolarmitotic spindle. In zyg-1 embryos, the centrosomes failed todivide during the first or second round of division. In allcases, a single large MTOC was apparent. Under indirect immunofluorescence,this structure appeared as a single large focus of microtubules(data not shown) and not as two closely apposed foci. Theseobservations are consistent with a defect in centrosome duplicationrather than a defect in separation of daughter centrosomes.

Including oj7, there are six mutant alleles of the zyg-1 gene.Only the oj7 and b1 alleles cause Stu phenotypes, and in thecase of b1, this phenotype is incompletely penetrant. All, however,cause defects in formation of the vulva and strong maternal-effectlethal phenotypes. Cytologically, all confer defects in centrosomeduplication (C. CARON and K. KEMPHUES, personal communication).While all zyg-1 mutations affect duplication at the two-cellstage, it appears that only oj7 affects duplication in the zygote.Given the more severe embryonic and postembryonic phenotypesassociated with oj7, it is likely to be the strongest memberof this allelic series. Interestingly, two of the mutants oftenhave multiple centrosomes associated with the sperm pronucleus,but these fail to duplicate after the first cell cycle (C. CARONand K. KEMPHUES, personal communication). Thus, the zyg-1 geneproduct appears to play a complex role in regulating the numberof centrosomes.

The spd-2 mutation appeared to affect microtubule organization.In addition to the defect in spindle morphogenesis, two microtubule-dependentmovements of the pronuclei were affected. In wild-type embryos,migration of the two pronuclei toward one another can be blockedwith drugs that disrupt microtubules (STROME and WOOD 1983 ).Although the spd-2 mutation did not block migration, it diddisrupt the normal migration pattern; in wild-type embryos,the pronuclei travel unequal distances and meet near the posteriorpole, while in spd-2 embryos the nuclei travel equal distancesand meet in the center of the embryo. In wild-type embryos,the pronuclei also undergo a second microtubule-dependent movement.Prior to spindle morphogenesis, the two pronuclei and associatedcentrosomes rotate by 90° to position the first mitoticspindle on the A-P axis. In spd-2 embryos, the pronuclei donot rotate. These observations suggest that some aspect of themicrotubule cytoskeleton is affected by the spd-2 mutation.Consistent with this idea, we have found by immunofluorescencemicroscopy that microtubules are poorly organized in spd-2 embryos(data not shown).

spd-3 embryos exhibited defects in polar-body formation, spindlepositioning, and cytokinesis. The first spindle was typicallytransverse and misplaced toward the posterior of the zygote,where it often elicited a furrow midway between the poles. Inaddition, an ectopic furrow,