Dominant Suppressors of a Muscle Mutant Define an Essential Gene of CAENORHABDITIS ELEGANS

The sup-11 I locus of C. elegans was defined by rare dominant suppressors of unc-93(e1500) III, a mutation that affects muscle structure. All ten of these dominant suppressors have a recessive "scrawny" phenotype. Two additional classes of sup-11 alleles were identified. One class, null alleles, was obtained by reversion of the dominant suppressor activity. These null alleles are recessive embryonic lethals, indicating that sup-11 is an essential gene. Members of the second class, rare semidominant revertants of the "scrawny" phenotype, are partial suppressors of unc-93(e1500). The genetic properties of the dominant suppressor mutations suggest that they are rare missense mutations that confer a novel activity to the sup-11 protein. We consider some of the ways that sup-11 alleles might suppress unc-93(e1500), including the possibilities that the altered sup-11 proteins restore function to a protein complex or are modified products of a gene that is a member of an unc-93 gene family.     

A Second Informational Suppressor, SUP-7 X, in CAENORHABDITIS ELEGANS

More than 30 independent suppressor mutations have been obtained in the nematode C. elegans through reversion analysis of two unc-13 mutants. Many of the new isolates map to the region of the previously identified informational suppressor, sup-5 III (Waterston and Brenner 1978). Several of the other suppressor mutations map to the left half of the X-linkage group and define a second suppressor gene, sup-7 X. In tests against 40 mutations in six genes, the sup-7(st5) allele was found to suppress to a greater extent the same alleles acted on by sup-5(e1464). Like sup-5(e1464), sup-7(st5) acts on null alleles of the myosin heavy-chain gene unc-54 I (MacLeod et al. 1977; MacLeod, Waterston and Brenner 1977) and the putative paramyosin gene unc-15 I (Waterston et al. 1977). Chemical analysis of unc-15(e1214); sup-7(st5) animals show that paramyosin is restored to more than 30% of the wild-type level.—As was observed for sup-5(e1464), suppression by sup-7(st5) is dose dependent and is greater in animals grown at 15° than at 25°. However, associated with this increased suppression is a decreased viability of sup-7(st5) homozygotes. Reversion of the lethality has resulted in the isolation of deficiency mutations that complement st5 lethality, but lack suppressor function. These properties of sup-7(st5) suggest that it, like sup-5(e1464), is an informational suppressor of null alleles, and its reversion via deficiencies further narrows the possible explanations of its action.     

An Autosomal Gene That Affects X Chromosome Expression and Sex Determination in CAENORHABDITIS ELEGANS

Recessive mutant alleles at the autosomal dpy-21 locus of C. elegans cause a dumpy phenotype in XX animals but not in XO animals. This dumpy phenotype is characteristic of X chromosome aneuploids with higher than normal X to autosome ratios and is proposed to result from overexpression of X-linked genes. We have isolated a new dpy-21 allele that also causes partial hermaphroditization of XO males, without causing the dumpy phenotype. All dpy-21 alleles show hermaphroditization effects in XO males that carry a duplication of part of the X chromosome and also partially suppress a transformer (tra-1) mutation that converts XX animals into males. Experiments with a set of X chromosome duplications show that the defects of dpy-21 mutants can result from interaction with several different regions of the X chromosome. We propose that dpy-21 regulates X chromosome expression and may be involved in interpreting X chromosome dose for the developmental decisions of both sex determination and dosage compensation.     

Integrative transformation of Caenorhabditis elegans

A technique for introducing exogenous DNA into the chromosomes of the nematode Caenorhabditis elegans is presented. A cloned C. elegans amber suppressor tRNA gene, sup-7, is used as a selectable marker. The activity of this amber suppressor is selected for by injecting worms which carry an amber termination mutation in a gene (tra-3) whose function is required for fertility. Transient expression of sup-7 is evidenced by the presence of fertile (rescued) animals in the generation after injection. In a fraction of cases, these fertile animals give rise to stable suppressor lines (eight have been characterized so far). Each of the stable suppressor lines carries injected DNA sequences. The suppressor activities have been mapped to chromosomal loci, indicating that the exogenous DNA has integrated into the genome. This technique has been used to introduce a chimeric gene containing a Drosophila heat shock promoter element fused to coding sequences from the Escherichia coli β-galactosidase gene. This chimeric gene functions and is heat inducible in the resulting stably transformed lines.     

A New Kind of Informational Suppression in the Nematode Caenorhabditis Elegans

Independent reversions of mutations affecting three different Caenorhabditis elegans genes have each yielded representatives of the same set of extragenic suppressors. Mutations at any one of six loci act as allele-specific recessive suppressors of certain allels of unc-54 (a myosin heavy chain gene), lin-29 (a heterochronic gene), and tra-2 (a sex determination gene). The same mutations also suppress certain alleles of another sex determination gene, tra-1, and of a morphogenetic gene, dpy-5. In addition to their suppression phenotype, the suppressor mutations cause abnormal morphogenesis of the male bursa and the hermaphrodite vulva. We name these genes smg-1 through smg-6 (suppressor with morphogenetic effect on genitalia), in order to distinguish them from mab (male abnormal) genes that can mutate to produce abnormal genitalia but which do not act as suppressors (smg-1 and smg-2 are new names for two previously described genes, mab-1 and mab-11). The patterns of suppression, and the interactions between the different smg genes, are described and discussed. In general, suppression is recessive and incomplete, and at least some of the suppressed mutations are hypomorphic in nature. A suppressible allele of unc-54 contains a deletion in the 3' noncoding region of the gene; the protein coding region of the gene is apparently unaffected. This suggests that the smg suppressors affect a process other than translation, for example mRNA processing, transport, or stability.     

Genetic and molecular analysis of eight tRNA(Trp) amber suppressors in Caenorhabditis elegans

Over 100 revertants of five different amber mutants were analyzed by Southern blot hybridization using synthetic oligomers as probes to detect a single base change at the anticodon, CCA to CTA (amber), of tRNA(Trp) genes of Caenohrabditis elegans. Of the 12 members of the tRNA(Trp) gene family, a total of eight were converted to amber suppressor alleles. All eight encode identical tRNAs; three of these are new tRNA(Trp) suppressors, sup-21, sup-33 and sup-34. Previous results had suggested that individual suppressor tRNA genes were expressed differentially in a cell-type- or developmental stage-specific manner. To extend these observations to the new genes and to test the specificity of expression against additional genes, cross suppression tests of these eight amber suppressors were carried out against amber mutations in several different genes including genes likely to be expressed in the same cell-type: three nervous system-affecting genes, two muscle structure-affecting genes and two genes presumed to be expressed in hypodermis. Seven out of eight suppressors could be distinguished one from another by the spectrum of their suppression efficiencies. These results also provide further evidence of cell-type-specific patterns of expression in the nervous system, muscle and hypodermis. The suppression pattern of the suppressor against the two muscle-affecting genes, unc-15 and unc-52, suggested that either the suppressors are expressed in a developmental stage-specific manner or that the unc-52 products are expressed in cell-types other than muscle, possibly hypodermis.     

The genes sup-7 X and sup-5 III of C. elegans suppress amber nonsense mutations via altered transfer RNA

The sup-5 III and sup-7 X suppressors in C. elegans have previously been shown to have many genetic properties in common with tRNA nonsense suppressors of microorganisms. We report here the results of two lines of investigation into the molecular basis of these suppressors. In one, which sought to determine the nature of suppressible alleles, we demonstrate through DNA sequencing studies that a suppressible allele, unc-54(e 1300) I, of the myosin heavy chain gene contains a C leads to T substitution, which changes a glutamine codon to amber terminator at residue 1903. In the other approach, which sought to define the nature of the suppressing activity, we show through in vitro translation studies that tRNA fractions from the suppressor strains, but not wild-type, promote the specific readthrough of amber terminators of three different messenger RNAs. We conclude that sup-5 and sup-7 result in readthrough of amber terminators in vivo through an altered tRNA.     

Differential expression of five tRNA(UAGTrp) amber suppressors in Caenorhabditis elegans.

Caenorhabditis elegans has 12 tRNA(UGGTrp) genes as defined by Southern analysis. In order to evaluate the function of the individual members of this multigene family, we sought to recover amber (UAG)-suppressing mutations from reversion experiments with animals carrying amber mutations in a nervous system-affecting gene (unc-13) or a sex-determining gene (tra-3). Revertants were analyzed by Southern blot, exploiting the fact that the CCA to CTA change at the anticodon creates a new XbaI site. Five different members of the tRNATrp gene family were identified as suppressors: sup-7 X, sup-5 III, sup-24 IV, sup-28 X, and sup-29 IV. All five suppressor genes were sequenced and found to encode identical tRNA(UAGTrp) molecules with a single base change (CCA to CTA) at the anticodon compared with their wild-type counterparts. The flanking sequences had only limited homology. The relative expression of these five genes was determined by measuring the efficiencies of suppressers against amber mutations in genes affecting the nervous system, hypodermis, muscle, and sex determination. The results of these cross-suppression tests showed that the five members of the tRNA(Trp) gene family were differentially regulated in a tissue- or development stage-specific manner.     

Mutations in the unc-54 myosin heavy chain gene of caenorhabditis elegans that alter contractility but not muscle structure

Reversion analysis of mutants of unc-22 IV, a gene affecting muscle structure and function in Caenorhabditis elegans, led to the isolation of six extragenic dominant suppressors of the “twitching” phenotype of unc-22 mutants. All six suppressors are new alleles of unc-54 I, the major body wall myosin heavy chain gene. Homozygous suppressor strains are slow, stiff and have normal muscle structure, whereas previously identified unc-54 alleles confer flaccid paralysis and drastic reduction in thick filament number and organization. Placement of the three suppressor mutations s74, s77 and s95 on the genetic fine structure map of unc-54 demonstrates that they are clustered near the right end of the map. Since this end of the gene corresponds to the 5′ end of the coding sequence, these suppressor mutations probably result in amino acid substitutions in the globular head of the myosin molecule, and should be of value in studies of myosin force generation.     

Suppression of methionine mutants in Coprinus

Summary The met-1-1 mutation in Coprinus lagopus is known to be suppressed by five recessive non-allelic suppressor genes (sup-1 to sup-5). Two of these genes complement normally in heterozygotes but the other three fail to complement each other in any combination. Four of the suppressor genes, sup-1, sup-2, sup-3 and sup-5, were tested for ability to suppress met-1-2 a second met-1 mutation. Non-identity of the two met-1 alleles was first confirmed by demonstrating intragenic recombination. The complementing suppressors, sup-1 and sup-2, proved to be allele unspecific and suppressed both met-1 mutations. The non-complementing suppressors, sup-3 and sup-5, were allele specific and could only suppress the met-1-1 mutation. This is interpreted to mean that sup-1 and sup-2 act indirectly to circumvent the metabolic lesion caused by any met-1 mutation whereas sup-3 and sup-5 are missense informational suppressors involving modified tRNA species which specifically mistranslate the met-1-1 mutant codon.     

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.     

Indirect Suppression in CAENORHABDITIS ELEGANS

Two cases of indirect suppression have been characterized. One case involves suppressors compensating for defects in muscle structure. Nine independent suppressor mutations were judged to lie in a single suppressor gene, sup-3. Suppression is dominant, but dose dependent, and results in improved locomotion, as well as in an increase in the ability of mutant animals to lay eggs. Mutations in six genes known to affect muscle structure were tested for suppression by representative sup-3 mutations. Alleles of three of the six genes are suppressed, two of which are known to code for thick filament proteins. One suppressor allele was identified as a deletion by genetic criteria. A second case of indirect suppression is not associated with muscle defects, but involves two mutant genes producing uncoordinated phenotypes very similar to one another. As in the first case, suppression is dominant but dose dependent and is not allele specific.     

unc-93(e1500): A Behavioral Mutant of CAENORHABDITIS ELEGANS That Defines a Gene with a Wild-Type Null Phenotype

The uncoordinated, egg-laying-defective mutation, unc-93(e1500) III, of the nematode Caenorhabditis elegans spontaneously reverts to a wild-type phenotype. We describe 102 spontaneous and mutagen-induced revertants that define three loci, two extragenic (sup-9 II and sup-10 X) and one intragenic. Genetic analysis suggests that e1500 is a rare visible allele that generates a toxic product and that intragenic reversion, resulting from the generation of null alleles of the unc-93 gene, eliminates the toxic product. We propose that the genetic properties of the unc-93 locus, including the spontaneous reversion of the e1500 mutation, indicate that unc-93 may be a member of a multigene family. The extragenic suppressors also appear to arise as the result of elimination of gene activity; these genes may encode regulatory functions or products that interact with the unc-93 gene product. Genes such as unc-93, sup-9 and sup-10 may be useful for genetic manipulations, including the generation of deficiencies and mutagen testing.     

First identification of an amber nonsense mutation in Schizosaccharomyces pombe: major differences in the efficiency of homologous versus heterologous yeast suppressor tRNA genes

Summary In Saccharomyces cerevisiae ochre and opal, as well as amber mutations are known, whereas in the fission yeast Schizosaccharomyces pombe no amber alleles have been described. We have characterized trp1-566, an amber allele in the trp1 locus of S. pombe. The identification of trp1-566 as an amber allele is based on the following results: (a) The nonsense allele can be converted to an ochre allele by nitrosoguanidine mutagenesis. (b) trp1-566 is suppressed by a bona fide S. pombe amber suppressor tRNA, supSI. The supSI gene was obtained by primer-directed in vitro mutagenesis of a tRNASer from S. pombe. Unexpectedly, an S. cerevisiae amber suppressor tRNASer, supR21, transformed into S. pombe, failed to suppress trp1-566. Northern analysis of S. pombe transformants, containing supRL1 or S. cerevisiae tRNA^Leu or tRNA^Tyr genes reveals that these genes are not transcribed in the fission yeast. As an additional tool for the analysis of nonsense mutations in S. pombe, we obtained by nitrosoguanidine mutagenesis two unlinked amber suppressor alleles, sup13 and sup14, which act on trp1-566.     

Genetic and fine structure analysis of unc-26(IV) and adjacent regions in Caenorhabditis elegans

Summary The genetic organization of unc-26(IV) and adjacent regions was studied in Caenorhabditis elegans. We constructed a fine structure genetic map of unc-26(IV), a gene that affects locomotion and pharyngeal muscle movement but not muscle structure. Eleven alleles were positioned relative to each other recombinationally and were classified according to phenotypic severity. The unc-26 gene spans at least 0.026 map units, which is exceptionally large for a C. elegans gene. All but one allele, e205, are amorphic alleles. Interestingly, e205 is hypomorphic but also suppressible by the amber suppressor sup-7. Nineteen lethal mutations in the unc-26 region were isolated and characterized. The unc-26 region is subdivided into four zones by five deficiency breakpoints. These mutations fall into 15 complementation groups. The stages of development affected by these mutations were determined.     

Isolation and characterization of a temperature-sensitive amber suppressor mutant of Escherichia coli K12

Summary By mutagenizing an E. coli strain carrying an amber suppressor supD ^- (or su _I ⁺), we isolated a mutant whose amber suppressor activity was now temperature-sensitive. The mutant suppressor gene was named sup-126, which was found to be cotransduced with the his gene by phage P1vir at the frequency of ca. 20%. At 30° C it suppresses many amber mutations of E. coli, phage T4, and phage . At 42° C, however, it can suppress none of over 30 amber mutations tested so far. The sup-126 mutation is unambiguous and stable enough to be useful for making production of an amber protein temperature-sensitive.     

Frameshift Suppression in SACCHAROMYCES CEREVISIAE. II. Genetic Properties of Group II Suppressors

Suppressors of ICR-induced mutations that exhibit behavior similar to bacterial frameshift suppressors have been identified in the yeast Saccharomyces cerevisiae. The yeast suppressors have been divided into two groups. One of these groups (Group II: SUF1, SUF3, SUF4, SUF5 and SUF6) appears to include a set of informational suppressors in which the vehicle of suppression is glycyl-tRNA. Some of the genetic properties of Group II suppressors are described in this communication.——Corevertants of the Group II frameshift mutations his4–519 and leu2–3 have been characterized to determine the spectrum of reversion events induced by the frameshift mutagen ICR-170. Seventythree ICR-induced corevertants were analyzed. With the exception of one corevertant, which carried an allele of SUF1, all carried alleles of SUF3 or SUF5. SUF1, SUF3, SUF4 and SUF6 were represented among spontaneous and UV-induced corevertants. In the course of these experiments one of the suppressors was mapped. SUF5, the probable structural gene for tRNA^GLY1, is located between ade2 and ade9 on chromosome XV.——SUF1, SUF4 and SUF6 have novel properties and comprise a distinct subset of suppressors. Although these suppressors show no genetic linkage to each other, they share several common features including lethality in haploid pairwise combinations, reduced tRNA^GLY3 isoacceptor activity and increased efficiency of suppression in strains carrying the cytoplasmically inherited [PSI] element. In addition, strains carrying SUF1, SUF4 or SUF6 are phenotypically unstable and give rise to mitotic Suf⁺ segregants at high frequency. These segregants invariably contain a linked, second-site mutation that maps in or adjacent to the suppressor gene itself. Strains carrying any of these suppressors also give rise to mitotic segregants that exhibit enhanced efficiency of suppression; mutations responsible for this phenotype map at two loci, upf1 and upf2. These genes show no genetic linkage to any of the Group II suppressors.——Methods that permit positive selection for mutants with decreased or enhanced efficiency of suppression have been devised in order to examine large numbers of variants. The importance of these interacting mutants is underscored by their potential utility in studying suppressor function at the molecular level.     

Mutations in genes encoding extracellular matrix proteins suppress the emb-5 gastrulation defect in Caenorhabditis elegans

The second division of the gut precursor E cells is lethally accelerated during Caenorhabditis elegans gastrulation by mutations in the emb-5 gene, which encodes a presumed nuclear protein. We have isolated suppressor mutations of the temperature-sensitive allele emb-5(hc61), screened for them among dpy and other mutations routinely used as genetic markers, and identified eight emb-5 suppressor genes. Of these eight suppressor genes, at least four encode extracellular matrix proteins, i.e., three collagens and one proteoglycan. The suppression of the emb-5 gastrulation defect seemed to require the maternal expression of the suppressors. Phenotypically, the suppressors by themselves slowed down early embryonic cell divisions and corrected the abnormal cell-division sequence of emb-5 mutant embryos. We propose an indirect stress-response mechanism to be the main cause of the suppression because: (1) none of these suppressors is specific, either to particular temperature-sensitive emb-5 alleles or to the emb-5 gene; (2) suppressible alleles of genes, reported here or elsewhere, are temperature sensitive or weak; (3) the suppression is not strong but marginal; (4) the suppression itself shows some degree of temperature dependency; and (5) none of the extracellular matrix proteins identified here is known to be expressed in oocytes or early embryos, despite the present observation that the suppression is maternal.     

Identification of transfer RNA suppressors in Escherichia coli. II. Duplicate genes for tRNA2Gln.

The number of gene copies for tRNA₂^Gln in λpsu⁺2 was determined by genetic and biochemical studies. The transducing phage stimulates the production of the su⁺2 (amber suppressor) and su°2 glutamine tRNAs and methionine tRNA_m. When the su⁺2 amber suppressor was converted to an ochre suppressor by single-base mutation, the phage stimulated ochre-suppressing tRNA₂^Gln, instead of the amber-suppressing tRNA₂^Gln. From the transducing phage carrying the ochre-suppressing allele, strains carrying both ochre and amber suppressors were readily obtainable. These phages stimulated both ochre-suppressing and amber-suppressing tRNA₂^Gln, but not the non-suppressing form. We conclude that the original transducing phage carries two tRNA₂^Gln genes, one su⁺2 and one su°2. The transducing phage carrying two suppressors, ochre and amber, segregates one-gene derivatives that encode only one or the other type of suppressor tRNA. These derivatives apparently arise by unequal recombination involving the two glutamine tRNA genes in the parental phage. This segregation is not accompanied by the loss of the tRNA_m^Met gene. Based on these results, it is suggested that Escherichia coli normally carries in tandem two identical genes specifying tRNA₂^Gln at 15 minutes on the bacterial chromosome. su⁺2 mutants may arise by single-base mutations in the anticodon region of either of these two, leaving the other intact. By double mutations, tRNA₂^Gln genes could also become ochre suppressors. A tRNA_m^Met gene is located near, but not between, these two tRNA₂^Gln genes.     

Allele-specific suppression in Caenorhabditis elegans reveals details of EMS mutagenesis and a possible moonlighting interaction between the vesicular acetylcholine transporter and ERD2 receptors

A missense mutant, unc-17(e245), which affects the Caenorhabditis elegans vesicular acetylcholine transporter UNC-17, has a severe uncoordinated phenotype, allowing efficient selection of dominant suppressors that revert this phenotype to wild-type. Such selections permitted isolation of numerous suppressors after EMS (ethyl methanesulfonate) mutagenesis, leading to demonstration of delays in mutation fixation after initial EMS treatment, as has been shown in T4 bacteriophage but not previously in eukaryotes. Three strong dominant extragenic suppressor loci have been defined, all of which act specifically on allele e245, which causes a G347R mutation in UNC-17. Two of the suppressors (sup-1 and sup-8/snb-1) have previously been shown to encode synaptic proteins able to interact directly with UNC-17. We found that the remaining suppressor, sup-2, corresponds to a mutation in erd-2.1, which encodes an endoplasmic reticulum retention protein; sup-2 causes a V186E missense mutation in transmembrane helix 7 of ERD-2.1. The same missense change introduced into the redundant paralogous gene erd-2.2 also suppressed unc-17(e245). Suppression presumably occurred by compensatory charge interactions between transmembrane helices of UNC-17 and ERD-2.1 or ERD-2.2, as previously proposed in work on suppression by SUP-1(G84E) or SUP-8(I97D)/synaptobrevin. erd-2.1(V186E) homozygotes were fully viable, but erd-2.1(V186E); erd-2.2(RNAi) exhibited synthetic lethality [like erd-2.1(RNAi); erd-2.2(RNAi)], indicating that the missense change in ERD-2.1 impairs its normal function in the secretory pathway but may allow it to adopt a novel moonlighting function as an unc-17 suppressor.