The Let-60 Locus Controls the Switch between Vulval and Nonvulval Cell Fates in Caenorhabditis Elegans

During induction of the Caenorhabditis elegans hermaphrodite vulva by the anchor cell of the gonad, six multipotent vulval precursor cells (VPCs) have two distinct fates: three VPCs generate the vulva and the other three VPCs generate nonspecialized hypodermis. Genes that control the fates of the VPCs in response to the anchor cell signal are defined by mutations that cause all six VPCs to generate vulval tissue (Multivulva or Muv) or that cause all six VPCs to generate hypodermis (Vulvaless or Vul). Seven dominant Vul mutations were isolated as dominant suppressors of a lin-15 Muv mutation. These mutations are dominant alleles of the gene let-60, previously identified only by recessive lethal mutations. Our genetic studies of these dominant Vul recessive lethal mutations, recessive lethal mutations, intragenic revertants of the dominant Vul mutations, and the closely mapping semi-dominant multivulva lin-34 mutations suggest that: (1) loss-of-function mutations of let-60 are recessive lethal at a larval stage, but they also cause a Vul phenotype if the lethality is rescued maternally by a lin-34 gain-of-function mutation. (2) The dominant Vul alleles of let-60 are dominant negative mutations whose gene products compete with wild-type activity. (3) lin-34 semidominant Muv alleles are either gain-of-function mutations of let-60 or gain-of-function mutations of an intimately related gene that elevates let-60 activity. We propose that let-60 activity controls VPC fates. In a wild-type animal, reception by a VPC of inductive signal activates let-60, and it generates into a vulval cell type; in absence of inductive signal, let-60 activity is low and the VPC generates hypodermal cells. Our genetic interaction studies suggest that let-60 acts downstream of let-23 and lin-15 and upstream of lin-1 and lin-12 in the genetic pathway specifying the switch between vulval and nonvulval cell types.     

Gene interactions in Caenorhabditis elegans define DPY-31 as a candidate procollagen C-proteinase and SQT-3/ROL-4 as its predicted major target

Zinc metalloproteases of the BMP-1/TOLLOID family (also known as astacins) are extracellular enzymes involved in important developmental processes in metazoans. We report the characterization of the Caenorhabditis elegans gene dpy-31, which encodes the first essential astacin metalloprotease identified in this organism. Loss-of-function mutations in dpy-31 result in cuticle defects, abnormal morphology, and embryonic lethality, indicating that dpy-31 is required for formation of the collagenous exoskeleton. DPY-31 is widely expressed in the hypodermal cells, which are responsible for cuticle secretion. We have investigated the dpy-31 function through reversion analysis. While complete reversion can be obtained only by intragenic suppressors, reversion of the Dpy-31 lethal phenotype also can be caused by dominant extragenic suppressors. Nine extragenic suppressors carry mutations in the uniquely essential collagen gene sqt-3, which we show is the same gene as rol-4. Most mutations exhibit the unusual property of exclusively dominant suppression and all affect the sequence of the SQT-3 collagen C terminus. This suggests that DPY-31 is responsible for C-terminal proteolytic processing of collagen trimers and is therefore a structural and functional homolog of vertebrate BMP-1. The results also demonstrate the critical importance of the collagen C-terminal sequence, which is highly conserved among all 49 members of the SQT-3 subfamily.     

Identification and Characterization of Genes That Interact with Lin-12 in Caenorhabditis Elegans

We identified and characterized 14 extragenic mutations that suppressed the dominant egg-laying defect of certain lin-12 gain-of-function mutations. These suppressors defined seven genes: sup-17, lag-2, sel-4, sel-5, sel-6, sel-7 and sel-8. Mutations in six of the genes are recessive suppressors, whereas the two mutations that define the seventh gene, lag-2, are semi-dominant suppressors. These suppressor mutations were able to suppress other lin-12 gain-of-function mutations. The suppressor mutations arose at a very low frequency per gene, 10-50 times below the typical loss-of-function mutation frequency. The suppressor mutations in sup-17 and lag-2 were shown to be rare non-null alleles, and we present evidence that null mutations in these two genes cause lethality. Temperature-shift studies for two suppressor genes, sup-17 and lag-2, suggest that both genes act at approximately the same time as lin-12 in specifying a cell fate. Suppressor alleles of six of these genes enhanced a temperature-sensitive loss-of-function allele of glp-1, a gene related to lin-12 in structure and function. Our analysis of these suppressors suggests that the majority of these genes are part of a shared lin-12/glp-1 signal transduction pathway, or act to regulate the expression or stability of lin-12 and glp-1.     

EMB-4: a predicted ATPase that facilitates lin-12 activity in Caenorhabditis elegans

The sel-6 gene was previously identified in a screen for suppressors of the egg-laying defect associated with hypermorphic alleles of lin-12 (Tax et al. 1997). Here we show that sel-6 and two other previously defined genes, mal-2 and emb-4, are the same gene, now called "emb-4." We perform a genetic and molecular characterization of emb-4 and show that it functions cell autonomously as a positive regulator of lin-12 activity. Viable alleles identified as suppressors of lin-12 are partial loss-of-function mutations, whereas the null phenotype encompasses a range of lethal terminal phenotypes that apparently are not related to loss of lin-12/Notch signaling. emb-4 encodes a large nuclearly localized protein containing a predicted ATPase domain and has apparent orthologs in fission yeast, plants, and animals.     

Effects of mutations at thestambh A locus ofDrosophila melanogaster

We report novel findings on the cytogenetic location, functional complexity and maternal and germline roles of thestambh A locus ofDrosophila melanogaster. stmA is localized to polytene bands 44D1.2 on 2R.stmA mutations are of two types: temperature-sensitive (ts) adult and larval paralytic or unconditional embryonic or larval lethal. Twelve alleles reported in this study fall into two intragenic complementing groups suggesting thatstmA is a complex locus with more than one functional domain. Some unconditional embryonic lethal alleles show a ‘neurogenic’ phenotype of cuticle loss accompanied by neural hypertrophy. It is shown that embryos of ts paralytic alleles also show mild neural hypertrophy at permissive temperatures while short exposure to heat induces severe cuticle loss in these embryos.stmA exerts a maternal influence over heat-induced cuticle loss. Unconditional embryonic lethal alleles ofstmA are also germline lethal.     

Characterization of third chromosome dominant alpha-methyl dopa resistant mutants (Tcr) and their interactions with l(2)amd alpha-methyl dopa hypersensitive alleles in Drosophila melanogaster

In Drosophila melanogaster two alleles at the Third chromosome resistance locus (Tcr; 3-39-6) were isolated in a screen of EMS mutagenized third chromosomes for dominant resistance to dietary alpha-methyl dopa, alpha-MD, a structural analogue of DOPA. Both alleles of Tcr are recessive lethals exhibiting partial complementation. Almost half (48.3%) of the Tcr40/Tcr45 heterozygotes die as embryos but some survive past adult eclosion. Both the embryonic lethal phenotype and the adult phenotype suggest that Tcr is involved in cuticle synthesis. Tcr mutants suppress the lethality of partially complementing alleles at the alpha-MD hypersensitive locus, l(2)amd. The viability of Tcr40/Tcr45, however, is not increased by the presence of a l(2)amd allele. The possibility that the Tcr and l(2)amd mutations reveal a catecholamine metabolic pathway involved in cuticle structure is discussed.     

Mutations in the Bli-4 (I) Locus of Caenorhabditis Elegans Disrupt Both Adult Cuticle and Early Larval Development

The bli-4 (I) gene of Caenorhabditis elegans had been previously defined by a single recessive mutation, e937, which disrupts the structure of adult-stage cuticle causing the formation of fluid-filled separations of the cuticle layers, or blisters. We report the identification of 11 new alleles of bli-4, all early larval lethals, including an allele induced by transposon mutagenesis. Nine of the lethal alleles failed to complement the blistered phenotype of e937; two alleles, s90 and h754, complement e937. The complementing alleles arrested development somewhat later than the noncomplementing alleles, which blocked just prior to hatching. We conclude that bli-4 is a complex locus with an essential function late in embryogenesis. We investigated the blistered phenotype of e937 through interactions with other mutations that alter worm morphology or cuticle structure. Recessive and dominant epistasis of several dumpy mutations over the blistered phenotype was observed. Using two heterochronic mutations that alter the developmental stage at which adult cuticle is expressed, we observed that adult worms that lack an adult-stage cuticle could not express blisters. However, late larval worms that expressed the adult cuticle did not express blisters either. It seems likely that the presence of the adult cuticle is necessary, but not sufficient, for blister expression. Blistering resulting from e937 is more severe in trans to null alleles, indicating that e937 is hypomorphic. We postulate that the adult-specific blistering is due to an altered or reduced function of bli-4 gene product in the adult cuticle.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic Analysis of a Major Segment [Lgv(left)] of the Genome of Caenorhabditis Elegans

From 10,900 F1 progeny of ethyl methanesulfonate (EMS)-mutagenized Caenorhabditis elegans nematodes, we isolated 194 lethal mutations on the left arm of LGV, a region balanced by the reciprocal translocation of eT1. The analysis of 166 of those mutations resulted in the identification of one deficiency and alleles of 78 genes including 38 new genes, thus increasing the number of identified essential genes to 101. We estimate that there are a minimum of 120 essential genes in this region, which comprises approximately 7% of the recombinational distance, although only about 4.2% of the genes, in C. elegans. We calculate that there are a minimum of 2850 essential genes in the genome. The left arm of LGV has two recombinational gene clusters separated by a high-recombination and/or essential gene-sparse region. One gene in this region, let-330, is the largest EMS target on the left arm of LGV, with twice as many alleles (16) as the next most EMS-mutable genes, let-332 and rol-3. Another gene in the sparse region, lin-40, and the region near lin-40 are major targets for Tc1 mobilization-induced mutagenesis. The analysis of essential genes in large regions should help to define C. elegans in terms of all its genes and aid in the understanding of the relationship of genome structure to genome function.     

Analysis of Mutations in the Sqt-1 and Rol-6 Collagen Genes of Caenorhabditis Elegans

Different mutations in the sqt-1 and rol-6 collagen genes of Caenorhabditis elegans can cause diverse changes in body morphology and display different genetic attributes. We have determined the nucleotide alterations in 15 mutant alleles of these genes. Three mutations in sqt-1 and one in rol-6 that cause dominant right-handed helical twisting (RRol) of animals are arginine to cysteine replacements. These mutations are all within a short conserved sequence, on the amino terminal side of the Gly-X-Y repeats, that is found in all C. elegans cuticle collagens. A recessive RRol mutation of rol-6 is a replacement of one of the same conserved arginines by histidine. In contrast, three sqt-1 mutations that cause recessive left-handed helical twisting (LRol) are replacements of a conserved carboxyterminal cysteine residue with either tyrosine or serine. These results suggest that disulfide bonding is important in collagen organization and that a deficit or surplus of disulfides may cause cuticle alterations of opposite handedness. In contrast to other collagens, glycine replacement mutations in the Gly-X-Y repeats of sqt-1 cause very mild phenotypes. Nonsense mutations of both sqt-1 and rol-6 cause nearly, but not totally, wild-type phenotypes. A nonsense mutation in sqt-1 suppresses the phenotype of rol-6 RRol mutations, suggesting that rol-6 collagen function is dependent on the presence of sqt-1 collagen. Mutations of sqt-1 are not suppressed by a rol-6 nonsense mutation, however, indicating that sqt-1 collagen can function independently of rol-6.     

The Mec-8 Gene of Caenorhabditis Elegans Affects Muscle and Sensory Neuron Function and Interacts with Three Other Genes: Unc-52, Smu-1 and Smu-2

Mutations in the Caenorhabditis elegans gene mec-8 were previously shown to cause defects in mechanosensation and in the structure and dye filling of certain chemosensory neurons. Using noncomplementation screens, we have identified eight new mec-8 alleles and a deficiency that uncovers the locus. Strong mec-8 mutants exhibit an incompletely penetrant cold-sensitive embryonic and larval arrest, which we have correlated with defects in the attachment of body muscle to the hypodermis and cuticle. Mutations in mec-8 strongly enhance the mutant phenotype of unc-52(viable) mutations; double mutants exhibit an unconditional arrest and paralysis at the twofold stage of embryonic elongation, a phenotype characteristic of lethal alleles of unc-52, a gene previously shown to encode a homolog of the core protein of heparan sulfate proteogylcan, found in basement membrane, and to be involved in the anchorage of myofilament lattice to the muscle cell membrane. We have identified and characterized four extragenic recessive suppressors of a mec-8; unc-52(viable) synthetic lethality. The suppressors, which define the genes smu-1 and smu-2, can weakly suppress all mec-8 mutant phenes. They also suppress the muscular dystrophy conferred by an unc-52(viable) mutation.     

Genetic Studies of Unusual Loci That Affect Body Shape of the Nematode CAENORHABDITIS ELEGANS and May Code for Cuticle Structural Proteins

In Caenorhabditis elegans, four loci (sqt-1, sqt-2, sqt-3 and rol-8) in which mutations affect body shape and cuticle morphology have unusual genetic properties. Mutant alleles of sqt-1 can interact to produce animals with a variety of mutant phenotypes: left roller, right roller, dumpy and long. At least three mutant phenotypes are specified by mutations in the sqt-3 locus. Most alleles at these loci are either dominant or cryptic dominant (i.e., are dominant only in certain genetic backgrounds). Most alleles of these loci exhibit codominance. Two putative null alleles of the sqt-1 locus produce a wild-type phenotype. Many alleles of these genes demonstrate unusual intergenic interactions that are not the result of simple epistasis: animals doubly heterozygous for mutations at two loci often display unexpected and unpredictable phenotypes. We suggest that these genetic properties might be expected of genes, such as the collagen genes, the products of which interact to form the animal's cuticle, and which are member genes of a gene family.     

Sli-1, a Negative Regulator of Let-23-Mediated Signaling in C. Elegans

By screening for suppressors of hypomorphic mutations of let-23, a receptor tyrosine kinase necessary for vulval induction in Caenorhabditis elegans, we recovered >/=12 mutations defining the sli-1 (suppressor of lineage defect) locus. sli-1 mutations suppress four of five phenotypes associated with hypomorphic alleles of let-23 but do not suppress let-23 null alleles. Thus, a sli-1 mutation does not bypass the requirement for functional let-23 but rather allows more potent LET-23-dependent signaling. Mutations at the sli-1 locus are otherwise silent with respect to vulval differentiation and cause only a low-penetrance abnormal head phenotype. Mutations at sli-1 also suppress the vulval defects but not other defects associated with mutations of sem-5, whose product likely interacts with LET-23 protein during vulval induction. Mutations at sli-1 suppress lin-2, lin-7 and lin-10 mutations but only partially suppress lin-3 and let-60 mutations and do not suppress a lin-45 mutation. The sli-1 locus displays dosage sensitivity: severe reduction of function alleles of sli-1 are semidominant suppressors; a duplication of the sli-1 (+) region enhances the vulvaless phenotype of hypomorphic mutations of let-23. We propose that sli-1 is a negative regulator that acts at or near the LET-23-mediated step of the vulval induction pathway. Our analysis suggests that let-23 can activate distinct signaling pathways in different tissues: one pathway is required for vulval induction; another pathway is involved in hermaphrodite fertilty and is not regulated by sli-1.     

Essential genes in proximal 3L heterochromatin of Drosophila melanogaster

We have further characterized essential loci within the centric heterochromatin of the left arm of chromosome 3 (3L) of Drosophila melanogaster, using EMS, radiation and P element mutagenesis. We failed to find any new essential genes, a result that suggests a lower-than-average gene density in this region. Mutations affecting expression of the most proximal gene [lethal 1, l1 or l(3)80Fj] act as dominant suppressors of Polycomb (Pc), behavior which is consistent with a putative trithorax group (trx-G) gene. The third gene to the left of the centromere [lethal 3, l3 or l(3)80Fh] is likely to correspond to verthandi (vtd), a known trx-G gene that plays a role in the regulation of hedgehog (hh) expression and signalling. The intervening gene [lethal 2, l2 or l(3)80Fi] is required throughout development, and mutant alleles have interesting phenotypes; in various allelic combinations that survive, we observe fertility, bristle, wing, eye and cuticle defects.     

Allelic interactions at the engrailed locus of Drosophila: engrailed protein expression in imaginal discs

Many embryonic lethal engrailed (enlethal) mutations are known to partially complement the cuticular defects of the original engrailed mutation, en1. To explore the nature of this complementation, the adult phenotypes of several different en1/enlethal transheterozygotes were compared with the corresponding patterns of engrailed protein expression in third larval instar imaginal discs (determined by immunofluorescence). Transheterozygotes of en1 and deletions of the locus (enDf) typically show slight complementation in the adult cuticle. The pattern of engrailed protein expression in some en1/enDf wing discs is indistinguishable from en1 homozygotes, but in others the pattern is nearly normal. en1/enDf leg discs appear to express engrailed protein normally. Transheterozygotes of en1 and EMS-induced, cytologically normal enlethal alleles have almost normal adult cuticle phenotypes and also exhibit normal patterns of engrailed protein expression in all of the thoracic imaginal discs. Surprisingly, the intensity of anti-engrailed staining in these discs is elevated relative to that in wild type. en2 is an unusual lethal allele in that it does not complement either the en1 adult cuticle phenotype or the protein expression pattern in imaginal discs. Moreover, the cytologically normal enlethal alleles also complement en2, at least partially. Both wing and leg imaginal discs from en2/enlethal transheterozygotes show abnormal patterns of engrailed protein expression. These results are discussed in the context of an autoregulatory model for engrailed regulation.     

A Network of Genes Antagonistic to the LIN-35 Retinoblastoma Protein of Caenorhabditis elegans

The Caenorhabditis elegans pRb ortholog, LIN-35, functions in a wide range of cellular and developmental processes. This includes a role of LIN-35 in nutrient utilization by the intestine, which it carries out redundantly with SLR-2, a zinc-finger protein. This and other redundant functions of LIN-35 were identified in genetic screens for mutations that display synthetic phenotypes in conjunction with loss of lin-35. To explore the intestinal role of LIN-35, we conducted a genome-wide RNA-interference-feeding screen for suppressors of lin-35; slr-2 early larval arrest. Of the 26 suppressors identified, 17 fall into three functional classes: (1) ribosome biogenesis genes, (2) mitochondrial prohibitins, and (3) chromatin regulators. Further characterization indicates that different categories of suppressors act through distinct molecular mechanisms. We also tested lin-35; slr-2 suppressors, as well as suppressors of the synthetic multivulval phenotype, to determine the spectrum of lin-35-synthetic phenotypes that could be suppressed following inhibition of these genes. We identified 19 genes, most of which are evolutionarily conserved, that can suppress multiple unrelated lin-35-synthetic phenotypes. Our study reveals a network of genes broadly antagonistic to LIN-35 as well as genes specific to the role of LIN-35 in intestinal and vulval development. Suppressors of multiple lin-35 phenotypes may be candidate targets for anticancer therapies. Moreover, screening for suppressors of phenotypically distinct synthetic interactions, which share a common altered gene, may prove to be a novel and effective approach for identifying genes whose activities are most directly relevant to the core functions of the shared gene.     

Molecular cloning of lin-29, a heterochronic gene required for the differentiation of hypodermal cells and the cessation of molting in C.elegans.

The lin-29 gene product of C.elegans activates a temporal developmental switch for hypodermal cells. Loss-of-function lin-29 mutations result in worms that fail to execute a stage-specific pattern of hypodermal differentiation that includes exist from the cell cycle, repression of larval cuticle genes, activation of adult cuticle genes, and the cessation of molting. Combined genetic and physical mapping of restriction fragment length polymorphisms (RFLPs) was used to identify the lin-29 locus. A probe from the insertion site of a Tc1 (maP1), closely linked and to the left of lin-29 on the genetic map, was used to identify a large set of overlapping cosmid, lambda and yeast artificial chromosome (YAC) clones assembled as part of the C.elegans physical mapping project. Radiolabeled DNA from one YAC clone identified two distinct allele-specific alterations that cosegregated with the lin-29 mutant phenotype in lin-29 intragenic recombinants. lin-29 sequences were severely under-represented in all cosmid and lambda libraries tested, but were readily cloned in a YAC vector, suggesting that the lin-29 region contains sequences incompatible with standard prokaryotic cloning techniques.     

Phenotypes of lethal alleles of the recessive temperature sensitive paralytic mutantstambh A ofDrosophila melanogaster suggest its neurogenic function

The mutantstambhA ¹ (2–56.8) ofDrosophila melanogaster was identified as a reversible temperature sensitive adult and larval paralytic. We have (i) isolated and analysed phenotypes of one new homozygous viable paralytic allele and two recessive unconditional embryonic lethal alleles ofstmA and (ii) studied the interaction of the viable paralytic alleles with ts paralytic mutantsnap ^ts1 (2–55.2) andpara ^ts1 (1–53.9). The homozygous viable paralytic allelesstmA ² andstmA ¹ are semi dominant neomorphs. The lethal allelesstmA ¹² andstmA ⁷ appear to be amorphs. Unhatched embryos expressing lethalstmA alleles showed hypotrophy of the anterior dorsal cuticle overlying the brain with a concomitant hypertrophy of the anterior dorsal neurogenic region (the brain). The ventral cuticle was poorly differentiated, and the ventral nerve chord showed mild hypertrophy and poor organisation. The epidermal cells in 12–13 h old embryos did not show the normal palisade layer arrangement. These phenotypes are similar to mutant phenotypes of the neurogenic class of genes whose wild type functions are necessary for intercellular communication. The allelesstmA ¹ andstmA ² do not appear to interact with the paralytic mutantsnap ^ts1 orpara ^ts1 in double mutant combinations. On the basis of our results it is proposed thatstmA may belong to the neurogenic class of genes.     

Loss-of-function mutations in a glutathione S-transferase suppress the prune-Killer of prune lethal interaction

The prune gene of Drosophila melanogaster is predicted to encode a phosphodiesterase. Null alleles of prune are viable but cause an eye-color phenotype. The abnormal wing discs gene encodes a nucleoside diphosphate kinase. Killer of prune is a missense mutation in the abnormal wing discs gene. Although it has no phenotype by itself even when homozygous, Killer of prune when heterozygous causes lethality in the absence of prune gene function. A screen for suppressors of transgenic Killer of prune led to the recovery of three mutations, all of which are in the same gene. As heterozygotes these mutations are dominant suppressors of the prune-Killer of prune lethal interaction; as homozygotes these mutations cause early larval lethality and the absence of imaginal discs. These alleles are loss-of-function mutations in CG10065, a gene that is predicted to encode a protein with several zinc finger domains and glutathione S-transferase activity.     

Molecular and Genetic Organization of the Suppressor of Sable and Minute(1)1b Region in Drosophila Melanogaster

Recessive mutations at the suppressor of sable [su(s)] locus in Drosophila melanogaster result in suppression of second site mutations caused by insertions of the mobile element 412. In order to determine whether su(s) mutations might have other phenotypes, a saturation mapping of the su(s) region was carried out. The screen yielded 76 mutations that comprise ten genetic complementation groups ordered distal to proximal as follows: l(1)1Bh, l(1)1Bi, M(1)1B, su(s), l(1)1Bk, l(1)1Ca, mul, tw, l(1)lDa and brc. Twenty-three of the mutations are su(s) alleles, and all are suppressors of the 412-insertion-caused v1 allele. Although the screen could have detected su(s) mutations causing sex-specific dominant lethality or sterility as well as all types of recessive lethality or sterility, the only other phenotype observed was male sterility that is enhanced by cold temperature. This type of sterility is exhibited only by alleles induced by base-substitution-causing mutagens. Genetic functions of the poly(A+) messages transcribed from the su(s) microregion were identified by the reintroduction of cloned sequences into embryos by P element transformation. su(s) function has been attributed to a 5-kb message. The segment of DNA encoding only this 5-kb message rescues both the suppression and cold-sensitive male sterility phenotypes of su(s). Minute (1) 1B has been provisionally identified as encoding a 3.5-kb message; lethal (1)1Bi encodes a 1-kb message; and lethal (1)1Bk encodes a 4-kb message. The possible functions of su(s) and M(1)1B are discussed.     

Mutations Affecting the Meiotic and Mitotic Divisions of the Early Caenorhabditis Elegans Embryo

We describe interactions between maternal-effect lethal mutations in four genes of Caenorhabditis elegans whose products appear to be involved in the meiotic and mitotic divisions of the one-cell embryo. Mitosis is disrupted by two dominant temperature-sensitive gain-of-function maternal-effect lethal mutations, mei-1(ct46) and mel-26(ct61), and by recessive loss-of-function maternal-effect lethal mutations of zyg-9. The phenotypic defects resulting from these mutations are similar. Doubly mutant combinations show a strong enhancement of the maternal-effect lethality under semipermissive conditions, suggesting that the mutant gene products interact. We isolated 15 dominant suppressors of the gain-of-function mutation mei-1(ct46). Thirteen of these suppressors are apparently intragenic, but 11 of them suppress in trans as well as cis. Two extragenic suppressors define a new gene, mei-2. The suppressor mutations in these two genes also result in recessive maternal-effect lethality, but with meiotic rather than mitotic defects. Surprisingly, most of these suppressors are also able to suppress mel-26(ct61) in addition to mei-1(ct46). The products of the four genes mei-1, mei-2, zyg-9 and mel-26 could be responsible for some of the specialized features that distinguish the meiotic from the mitotic divisions in the one-cell embryo.