lin-35/Rb and ubc-18, an E2 ubiquitin-conjugating enzyme, function redundantly to control pharyngeal morphogenesis in C. elegans

David S. Fay1,*, Edward Large1, Min Han2 and Monica Darland1

1 Department of Molecular Biology, University of Wyoming, PO Box 3944, Laramie, WY 82071-3944, USA
2 Howard Hughes Medical Institute and Department of Molecular, Cellular, and Developmental Biology, University of Colorado, Boulder, CO 80309-0347, USA

* Author for correspondence (e-mail: davidfay{at}uwyo.edu)

Accepted 24 April 2003


    SUMMARY
 TOP
 SUMMARY
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
The retinoblastoma gene product has been implicated in the regulation of multiple cellular and developmental processes, including a well-defined role in the control of cell cycle progression. The Caenorhabditis elegans retinoblastoma protein homolog, LIN-35, is also a key regulator of cell cycle entry and, as shown by studies of synthetic multivulval genes, plays an important role in the determination of vulval cell fates. We demonstrate an additional and unexpected function for lin-35 in organ morphogenesis. Using a genetic approach to isolate lin-35 synthetic-lethal mutations, we have identified redundant roles for lin-35 and ubc-18, a gene that encodes an E2 ubiquitin-conjugating enzyme closely related to human UBCH7. lin-35 and ubc-18 cooperate to control one or more steps during pharyngeal morphogenesis. Based on genetic and phenotypic analyses, this role for lin-35 in pharyngeal morphogenesis appears to be distinct from its cell cycle-related functions. lin-35 and ubc-18 may act in concert to regulate the levels of one or more critical targets during C. elegans development.

Key words: lin-35, Retinoblastoma, ubc-18, Ubiquitin, C. elegans, Pharynx


    INTRODUCTION
 TOP
 SUMMARY
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Functional disruption of the retinoblastoma gene product (pRb) has been implicated as a causal event in the genesis of a wide range of human cancers (reviewed by Sherr, 1996Go; Nevins, 2001Go). pRb and its structurally related family members, p107 and p130, play key roles in the regulation of several fundamental cellular processes, including cell cycle entry and the induction of apoptosis (reviewed by Kaelin, 1999Go; Morris and Dyson, 2001Go). The ability of pRb to regulate these events is linked directly to its activity as a transcriptional repressor. Specifically, pRb binds to E2F family members and inhibits the expression of E2F target genes (reviewed by Dyson, 1998Go; Harbour and Dean, 2000Go). These targets include positive-acting cell cycle regulators, such as cyclins E and A (DeGregori et al., 1995Go; Duronio and O'Farrell, 1995Go; Ohtani et al., 1995Go; Schulze et al., 1995Go), genes that are required for DNA synthesis (Dou et al., 1994Go; DeGregori et al., 1995Go), and mediators of apoptosis (DeGregori et al., 1997Go; Hsieh et al., 1997Go; Tsai et al., 1998Go). pRb transcriptional repression of E2F targets occurs through a number of distinct mechanisms, many of which involve the recruitment of enzymes that modify chromatin structure. These include histone deacetylase (Brehm et al., 1998Go; Luo et al., 1998Go; Magnaghi-Jaulin et al., 1998Go), members of the nucleosome remodeling complex (Dunaief et al., 1994Go; Strober et al., 1996Go; Zhang et al., 2000Go) and proteins required for histone methylation (Nielsen et al., 2001Go).

In addition to cell-cycle regulation, in vitro and tissue culture studies have shown that pRb associates with a diverse set of proteins, many of which regulate the expression of genes required for tissue-specific differentiation (reviewed by Morris and Dyson, 2001Go). For example, pRb enhances the DNA binding and transactivation activities of NF-IL6 (Chen et al., 1996bGo) and the C/EBP (Chen et al., 1996aGo) family of transcription factors to promote adipocyte and leukocyte differentiation, respectively. pRb also promotes muscle differentiation by augmenting the activity of MyoD (Gu et al., 1993Go) and through inhibition of the transcriptional repressor HBP1 (Tevosian, 1997; Shih et al., 1998Go). Finally, pRb may bind and regulate the activities of a number of additional factors, including the paired homeodomain-containing proteins Pax3, Pax5, Chx10 and Mhox (Wiggan et al., 1998Go; Eberhard and Busslinger, 1999Go); several hormone-responsive transcription factors, including the glucocorticoid receptor (Singh et al., 1995Go); and the osteoblast transcription and differentiation factor, CBFA1 (Thomas et al., 2001Go). Whether or not the majority of these reported activities represent authentic in vivo functions for Rb remains to be determined.

Acting in concert with transcriptional regulatory factors, the ubiquitin-mediated degradation pathway has emerged as the other principal mechanism by which cells control the abundance of individual proteins. The process is carried out by three classes of enzymes (termed E1, E2 and E3) that act sequentially to catalyze the attachment of ubiquitin, a highly conserved ~76 amino acid protein, to the protein substrate targeted for degradation (reviewed by Weissman, 2001Go). The process is initiated by E1 enzymes (also known as ubiquitin-activating enzymes), which form a thiol-ester bond with the C-terminal glycine of ubiquitin in an ATP-dependent manner. The E2 or UBC (for ubiquitin-conjugating or ubiquitin-carrier) enzyme then accepts ubiquitin from the E1 via a transthiolation reaction involving the C terminus of ubiquitin. Finally, the transfer of ubiquitin from E2 to a lysine on the target protein is catalyzed by the E3 ubiquitin ligase. E3 enzymes can further be subdivided into two separate families containing either a HECT or a RING finger domain. E3s with a HECT domain form thiol-ester intermediates with ubiquitin prior to attachment to the target protein (Huibregtse et al., 1995Go), whereas E3s with a RING finger mediate the direct transfer of ubiquitin from E2 to the target protein (Joazeiro and Weissman, 2000Go). In either case, the majority of ubquitylated proteins are subsequently degraded by the 26S proteasome.

A recent analysis of the C. elegans genome identified 20 genes encoding predicted E2/UBC enzymes along with three UBC variants (Jones et al., 2002Go). This compares with 12 UBCs in S. cerevisiae, 25 in Drosophila and 26 that have thus far been identified in the human proteome. Thus, complexity in the ubiquitylation process begins at the level of UBCs and is further amplified by the large number of potential E3 genes found in the genomes of most higher eukaryotes; the C. elegans genome encodes for >150 RING-finger or HECT domain proteins. Interestingly, RNA-mediated interference (RNAi) experiments of the 23 C. elegans UBC genes revealed functions for only four of them (Jones et al., 2002Go). RNAi of these genes [let-70 (ubc-2), ubc-9, ubc-12, and ubc-14], all of which are conserved in yeast, results in developmental arrest at various stages. Thus, a large proportion of UBCs in C. elegans may be functionally redundant, either with each other or with other cellular factors that act to regulate protein levels.

Using a genetic screen to identify mutations causing synthetic phenotypes with lin-35/Rb in C. elegans, we have previously reported the identification of mutations in fzr-1, a regulatory subunit of the APC proteasome (Fay et al., 2002Go). lin-35; fzr-1 double mutants display a hyperproliferation phenotype that affects virtually all cell types examined. We now describe our analysis of another mutation identified in this screen. Cloning of the gene reveals that it corresponds to ubc-18, the C. elegans homolog of human UBCH7 (ARIH1 – Human Gene Nomenclature Database). The coordinate inactivation of lin-35 and ubc-18 leads to several developmental defects, including a failure to execute pharyngeal morphogenesis properly. The expanding role of lin-35 beyond cell-cycle control and vulval induction in C. elegans should shed light on the conserved role of Rb in higher eukaryotes.


    MATERIALS AND METHODS
 TOP
 SUMMARY
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Strains and genetic methods
Maintenance, culturing, and genetic manipulations of C. elegans were carried out according to standard procedures at 20°C (Sulston and Hodgkin, 1988Go). Strains used in the phenotypic analysis included WY43 [ubc-18(ku354)], WY83 [lin-35; ubc-18; kuEx119], WY78 [lin-35; dpy-17(e164), ubc-18(ku354); unc-32(e189); kuEx119], MH1834 [ubc-18(ku354), unc-32], SM469(pha-4::GFP-NLS), SM481(pha-4::GFP-mem), MH1384 (ajm-1::GFP), PD4792 (myo-2::GFP) and DP132 (unc-119::GFP).

Strains used to map ubc-18(ku354) included: lin-35(n745); dpy-17(e164), unc-32(e189)III [6/19 Unc-non-Dpy (UND) and 9/12 Dpy-non-Unc (DNU) recombinants picked up the ubc-18 mutation]; and lin-35(n745); sma-3(e491), unc-32(e189) [16/16 UNS and 0/7 SNU picked up the ubc-18 mutation]. Strains WY2 [dpy-17(e164), ubc-18(ku354); unc-32(e189)], WY78 and CB4856 were used in SNP mapping procedures to place ubc-18(ku354) between SNP markers eam34f12.s1@151 on cosmid R01H2 and eam49b07.s1@287 on cosmid T21D11. For this effort, a total of 98 DNU and UND recombinants were isolated, homozygosed and (in the case of recombinants derived from WY2) injected with lin-35 dsRNA to ascertain the status of the ubc-18 mutation. For SNP mapping with WY78, we used a lin-35 strain that had been backcrossed five times to CB4856 (WY72) and followed the presence of ubc-18 based on the requirement for kuEx119. For additional details on genetic mapping, see Fay et al. (Fay et al., 2002Go).

Duplication and deficiency analysis
lin-35; ubc-18/ubc-18; qDp3 animals were generated by crossing JK867 [dpy-17(e164) ncl-1(e1865) unc-36(e251)III; qDp3(III;f)] hermaphrodites to lin-35 males, then crossing F1 male progeny to lin-35; ubc-18, unc-32; kuEx119 hermaphrodites. Putative lin-35; d17, ncl-1, unc-36/ubc-18, unc-32; qDp3 animals were identified, as well as lin-35; ubc-18; unc-32; qDp3 animals in the next generation. Such animals were wild type and generated UNC-32 but not DPY-17, UNC-36 progeny. The presence of the lin-35 homozygous mutation was confirmed by the phenotypes of the Unc animals (lin-35; ubc-18; unc-32) as well as through the use of lin-15a(RNAi) which led to a high penetrance of the Muv phenotype when lin-35 was homozygous. To generate lin-35; ubc-18, unc-32/+; qDp3 animals, lin-35; ubc-18; unc-32; qDp3 animals were crossed to lin-35; dpy-17, unc-32/+ males and wild-type cross progeny hermaphrodites that gave rise to DpyUnc animals were identified, indicating the genotype lin-35; ubc-18; unc-32/dpy-17, unc-32; qDp3. For deficiency mapping, lin-35; dpy-17, ubc-18, unc-32/+ males were crossed to MT1978 [nDf16/unc-36(e251) dpy-19(e1259)] and lin-35; nDf16/dpy-17, ubc-18, unc-32; kuEx119 animals were identified. However, such animals, when fertile, were rapidly out-competed by homozygous lin-35; ubc-18; kuEx119 sibling progeny. Similar results were obtained when we attempted to produce animals with the genotype lin-35; nDf16/+; kuEx119, suggesting that the lin-35 mutation may be deleterious in conjunction with the deficiency. Direct testing of nDf16/+ animals for sensitivity to lin-35 reduction using RNAi led to first generation nDf16/+ progeny that were uniformly sterile (data not shown). Thus, our inability to isolate stable lin-35; ubc-18/nDf16:kuEx119 strains stems from an apparent toxic genetic interaction between lin-35 and nDf16.

Other methods
Cosmid rescue
Rescue was obtained by co-injection of C. elegans genomic cosmids or PCR products with pRF4 into WY83 using standard procedures (Mello and Fire, 1995Go). Rescued animals were fertile and showed a roller (Rol) phenotype. For single-gene rescue of WY83 animals, a 2570 bp PCR fragment corresponding to nucleotides 31,220-33,790 of R01H2 was used. The ubc-18-coding region spans nucleotides 32,225-32,928 and is encoded by the reverse strand.

RNAi
RNAi was carried out according to standard methods (Fire et al., 1998Go; Fraser et al., 2000Go). Feeding vectors were constructed as previously described (Fay et al., 2002Go). For lin-37, a 774 bp fragment of C. elegans genomic DNA corresponding to nucleotides 1763-2555 of cosmid ZK418 (261-816 of lin-37) was subcloned into the polylinker of PD129.36. For ubc-18, a 691 bp PCR fragment of C. elegans genomic DNA corresponding to nucleotides 32,232-32,923 of R01H2 (the entire ubc-18 coding region) was subcloned into vector pPD129.36.


    RESULTS
 TOP
 SUMMARY
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
ubc-18/slr-5 is synthetically lethal with lin-35/Rb
We have previously described a genetic screen in C. elegans that leads to the efficient isolation of mutations that are synthetically lethal with lin-35 (Fay et al., 2002Go). Briefly, the strategy employs a strain with two attributes: (1) the strain is homozygous for a strong loss-of-function mutation in lin-35; and (2) the strain carries a meiotically unstable extrachromosomal array (kuEx119) that contains both wild-type lin-35-rescuing sequences and a ubiquitously expressed GFP reporter. Because lin-35 is nonessential, animals that fail to inherit the array are nevertheless viable and can be identified by their absence of GFP expression. After mutagenesis, animals acquiring mutations that are synthetically lethal with lin-35 are identified by their complete dependence on the array for viability. To date, we have screened ~7000 haploid genomes and have identified 11 Slr mutations (for synthetic with lin-35/Rb) that represent at least 10 loci. We describe the identification of slr-5(ku354), which, based on its molecular identity (see below), we refer to as ubc-18.

lin-35; ubc-18; kuEx119 animals are healthy, fertile and generally appear indistinguishable from wild-type animals (Fig. 1A,B). By contrast, most lin-35; ubc-18 animals that fail to inherit the array arrest or die as larvae, and those animals reaching adulthood are typically small and sterile (Fig. 1A,B; Table 1). As predicted for a synthetically lethal mutation, inactivation of lin-35 (expressed from the extrachromosomal array) using RNAi caused lin-35; ubc-18; KuEx119 animals to adopt the double-mutant phenotype (Fig. 1A,B). As previously described, lin-35 single mutants are viable but show a substantial reduction in brood sizes compared with wild type (Table 1) (Lu and Horvitz, 1998Go; Fay et al., 2002Go). Similarly, ubc-18 single mutants exhibit a marked reduction in brood size and are slightly growth retarded (Table 1; data not shown).



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Fig. 1. Synergism between mutations in lin-35 and ubc-18. DIC (A) and corresponding GFP fluorescence (B) images. The large adult with GFP fluorescence is of genotype lin-35; ubc-18; kuEx119. The white arrows indicate the position of an arrested lin-35; ubc-18 L1 larva that failed to inherit the array; the white arrowheads indicate a sterile lin-35; ubc-18 young adult. Inset in A shows an arrested lin-35; ubc-18; KuEx119 larval-stage animal treated with lin-35(RNAi) (same animal is shown in the inset in B). (C,D) L1 animals of genotypes lin-35; ubc-18 and wild type, respectively. White and black arrowheads indicate anterior and posterior pharyngeal boundaries, respectively. Note the failure of the mutant pharynx to extend to the anterior end of the animal. (Inset in D) myo-2::GFP fluorescence in the wild-type background, highlighting the bi-lobed shape of the pharynx. Scale bars: in A, 100 µm for A,B; in C, 10 µm for C; in D, 10 µm for D.

 


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Table 1. Viability of lin-35 and ubc-18 mutant derivatives

 
Approximately 4% of lin-35; ubc-18 larvae display a Pun (pharyngeal unattached) phenotype, whereby the pharynx has failed to elongate and form an attachment to the anterior alimentary opening or buccal cavity (Fig. 1C,D; Table 1). Such animals fail to ingest food and arrest growth during the first larval stage. The frequency of Pun animals was dramatically increased following inactivation of lin-35 by RNAi in either a lin-35; ubc-18; KuEx119 or ubc-18 single-mutant background (Table 1; data not shown). This difference in the penetrance of the Pun phenotype between lin-35; ubc-18 and ubc-18; lin-35(RNAi) animals may be due to a low frequency of LIN-35 maternal rescue derived from the extrachromosomal array. Alternatively, although less likely, lin-35(n745), a strong loss-of-function allele containing an early nonsense mutation (Lu and Horvitz, 1998Go), may have some residual activity. The cause for growth arrest in lin-35; ubc-18 animals that contain normal-appearing pharynges is currently unknown. It is possible that such animals are defective at feeding because of more subtle alterations in pharyngeal structure or attachments. However, as most of these animals do undergo some degree of growth prior to arrest, their defect may be unrelated to their ability to feed. No obvious abnormalities in the proliferation or differentiation of other somatic cells were observed in lin-35; ubc-18 double mutants that reach adulthood (data not shown).

We also observed a high incidence of larval arrest in animals that were homozygous for lin-35, but heterozygous for ubc-18, though the rate of arrest was lower than that observed for homozygous double mutants (Table 1). In addition, lin-35; ubc-18/+ animals that reached adulthood showed an ~50% reduction in brood size compared with lin-35 mutants alone (Table 1). These results suggest that the ubc-18 mutation could be semi-dominant or haplo-insufficient, or, based on the method used to generate the heterozygous animals, ubc-18 could be maternally required. Further experiments indicated that the effect in heterozygous animals results from a combination of the latter two possibilities: (1) lin-35 mutant animals that are heterozygous, but maternally wild type, for ubc-18 show lower rates of larval arrest then those that are heterozygous but maternally deficient (Table 1); thus, the presence of maternal ubc-18 can partially reduce the severity of lin-35; ubc-18 genetic interactions; (2) overexpression of the ku354 variant of UBC-18 (via an extrachromosomal array), together with lin-35 inactivation by RNAi, did not lead to a phenocopy of the double-mutant phenotype (data not shown); (3) in an otherwise wild-type background, ubc-18/+ heterozygous animals had wild-type brood sizes, indicating that the effects in heterozygous animals were specific to ubc-18 genetic interactions with lin-35 (Table 1); and (4) RNAi of ubc-18 performed on lin-35; ubc-18; kuEx119 animals strongly enhanced the penetrance of the Pun phenotype in progeny not harboring the array compared with the array-deficient progeny of untreated lin-35; ubc-18; kuEx119 animals [Table 1 and see discussion of ubc-18(RNAi) below]. This latter result also indicates that ku354 represents a partial loss-of-function allele of ubc-18.

We also carried out further genetic analysis using a regional free duplication (qDp3) that contains sequences from an ~ 0.5 Mb region of chromosome III, including ubc-18. Briefly, we found that lin-35; ubc-18/ubc-18; qDp3 animals displayed a similar phenotype to lin-35; ubc-18/+ animals (Table 1 and data not shown), further supporting our conclusion that ku354 is a LOF allele and does not act in a dominant or dose-dependent manner. We note that we were unable to generate stable strains that were heterozygous for ubc-18 and nDf16 (a large chromosomal deficiency that deletes ubc-18) in the lin-35; KuEx119 background, as the lin-35 mutation surprisingly showed a synthetic genetic interaction with the deficiency itself (also see Materials and Methods).

ubc-18 encodes a homolog of the ubiquitin activating enzyme UbcH7
ku354 was mapped to a small segment of chromosome III between sma-3 and unc-32 using genetic markers and single-nucleotide polymorphisms (SNPs). To identify the affected gene, lin-35; ubc-18; KuEx119 animals were co-injected with regional cosmids and a dominant marker conferring a Rol phenotype. Rescued lines were identified by the presence of healthy Rol animals that no longer required the original array containing lin-35 (kuEx119) for viability. Two overlapping cosmids in the region, R01H2 and C49B6, were found to rescue the lin-35; ubc-18 synthetic lethality. A minimal rescuing sequence was identified that contained only a single predicted open reading frame: that encoding the C. elegans gene ubc-18/R01H2.6. Six out of eight independently derived transgenic lines containing the wild-type ubc-18 gene efficiently rescued the double-mutant phenotype (also see Materials and Methods).

ubc-18 encodes a predicted protein of 153 amino acids that is highly similar to known E2-type ubiquitin-conjugating enzymes (Jones et al., 2002Go). UBC-18 shows greatest similarity to UbcH7 in humans (29% identical and 86% similar) and is approximately equally similar to S. cerevisiae proteins Ubc-5p and Ubc-4p (Fig. 2; data not shown). The database prediction for ubc-18 is supported by the existence of multiple sequenced cDNA clones (kindly provided by Y. Kohara) that confirm both the 3' terminus of the gene as well as the precise locations of its four exons. In addition, the 5' untranslated region that was identified by the cDNA clones contains two in-frame stop codons located just upstream (15 and 24 nucleotides) of the start ATG.



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Fig. 2. Alignment of UBC-18 with UBCH7 and Ubc5. Clustal analysis was used to align C. elegans UBC-18 with UBCH7 from humans and Ubc5 from S. cerevisiae. Black boxes indicate identity; gray boxes indicate similarity. The location of the mutation in ku354 mutant animals is indicated by an asterisk.

 
We sequenced the entire genomic region of ubc-18 from ku354 mutant animals and identified a single lesion that resulted in a nonconservative amino acid substitution at position 10 of UBC-18. The mutation converts a glutamic acid residue that is highly conserved in many E2 proteins to a lysine (Fig. 2 and data not shown). This region of the protein facilitates interactions of E2 enzymes with E1 ubiquitin-activating enzymes (Haas and Siepmann, 1997Go; Tong et al., 1997Go) and may play a minor role in interactions with some E3 ubiquitin ligases (Huang et al., 1999Go; Zheng et al., 2000Go; Martinez-Noel et al., 2001Go). A failure to interact with E1 (or with E3) enzymes would be predicted to result in a strong loss of function in this E2, or could possibly lead to an E2 with dominant-negative activity (Townsley et al., 1997Go; Yamanaka et al., 2000Go) (however, see previous discussion concerning haploinsufficiency).

RNAi of ubc-18 has previously been reported to have no phenotype in wild-type animals (Jones et al., 2002Go). Consistent with this, we observed, at most, a subtle effect of ubc-18(RNAi) on viability and brood size in N2 animals, although treated animals generally took an extra day to reach maturity when compared with control animals (Table 1; data not shown). Mutations in rrf-3, a predicted RNA-directed RNA polymerase, have recently been reported to enhance the overall efficacy of gene inactivation by RNAi feeding methods (Simmer et al., 2002Go). Consistent with this, RNAi inactivation of ubc-18 in the rrf-3 mutant background led to an ~50% reduction in brood size when compared with rrf-3 mutants alone (Table 1).

To see if we could reiterate the double-mutant phenotype, we performed ubc-18(RNAi) on lin-35 and lin-35; rrf-3 animals. RNAi treatment of lin-35; rrf-3 double mutants resulted in first-generation progeny that either arrested as larvae or developed into completely sterile adults (Table 1). These adults often failed to generate sperm and contained abnormal-appearing oocytes, similar to some lin-35; ubc-18 double mutants (data not shown). We note that even without RNAi treatment, lin-35; rrf-3 double mutants were markedly less healthy than either lin-35 or rrf-3 single mutants (Table 1). Treatment of lin-35 mutants with ubc-18(RNAi) led to more subtle defects in the first generation (Table 1), though prolonged exposure resulted in higher rates of larval arrest and adult sterility in subsequent generations (data not shown).

We failed to observe any Pun animals arising from ubc-18(RNAi) treatment of lin-35 or lin-35; rrf-3 animals (Table 1) or in experiments where both genes were simultaneously inactivated by RNAi (data not shown). Such results may reflect a failure to sufficiently inactivate ubc-18 by RNAi methods, or they may occur if strong inactivation of ubc-18 led to sterility of the treated parent prior to the production of Pun progeny.

lin-35; ubc-18 embryos are defective at pharyngeal morphogenesis
An initial examination of both lin-35; ubc-18 and ubc-18; lin-35(RNAi) embryos (hereafter referred to as double-mutant embryos) indicated that the first observed defects in pharyngeal development coincided with events taking place at or just prior to the 1.5-fold stage of embryogenesis. At this time in wild-type animals, a subset of anterior pharyngeal cells reorient their longitudinal axes, form associations with neighboring cells and then shift their positions towards the anterior region of the embryo through a localized contraction mechanism, leading to pharyngeal elongation (Portereiko and Mango, 2001Go) (see below). By contrast, pharyngeal cells of double-mutant embryos remain stationary and fail to move towards the anterior (Fig. 3A-D). In addition, whereas the anterior border of the basement membrane that encapsulates the pharyngeal primordium becomes less distinct during elongation in wild-type embryos, this feature remains prominent in the double mutants (Fig. 3A,C; see Fig. 5). The failure of mutant embryos to undergo pharyngeal elongation could result from several distinct underlying defects: (1) mutant embryos may generate incorrect numbers of pharyngeal precursor cells during early embryonic development, leading to defects at later stages; (2) these precursor cells, once generated, may fail to differentiate properly; and (3) properly specified pharyngeal cells may fail to execute one or more steps during morphogenesis of the organ.



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Fig. 3. pha-4::GFP expression in wild-type and mutant animals. DIC (A,C,E,G) and corresponding pha-4::GFP fluorescence (B,D,F,H) images. (A-D) ~1.5-fold-stage wild-type (A,B) and ubc-18; lin-35(RNAi) mutant (C,D) embryos. Anterior is towards the left and ventral is downwards. Arrows indicate the dorsoventral pharyngeal boundaries. Note gross differences in pharyngeal shape and borders in double mutants versus wild-type embryos. In addition, note the overall similarity in the numbers of GFP-expressing cells in wild-type and double-mutant embryos. (The mutant and wild-type embryos contained 102 and 101 GFP+ nuclei, respectively.) The white bracket (D) demarcates the presence of several GFP-expressing arcade cells that failed to integrate with the rest of the pharynx. Intestinal cell nuclei, which are large, round and reside to the posterior, can readily be distinguished from pharyngeal nuclei at this stage. (E-H) pha-4::GFP expression in wild-type (E,F) and ubc-18; lin-35(RNAi) mutant L1 larvae (G,H). White and black arrowheads indicate anterior and posterior pharyngeal boundaries, respectively. As above, note the overall similarity in the number of GFP-expressing cells in contrast to the gross differences in pharyngeal shape between wild-type and double-mutant animals. The bracket (H) indicates the non-integrated arcade cells. Scale bars: in A, 10 µm for A-D; in E, 10 µm for E-H.

 



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Fig. 5. Pharyngeal morphogenesis in wild-type and mutant animals. DIC (A,C,E,G,I,K) and corresponding GFP fluorescence (B,D,F,H,J,L) images showing the outline of pharyngeal (and intestinal) cells in wild-type (A-D) and ubc-18; lin-35(RNAi) mutant (E-L) embryos. Anterior is towards the left and ventral is downwards. Black arrows demarcate the anterior pharyngeal boundary. (M) A schematic for pharyngeal extension involving three discrete steps (also see text). (A,B) An early comma-stage embryo, before overt signs of morphogenesis have begun. Note the teardrop shape of the leading-edge epithelial cells (white arrowheads, B). (C,D) 1.5-fold-stage embryo with pharynx now extended to the anterior. Note the transformation in the shape of the leading-edge epithelial cells (white arrows, D). (E,F) 1.5-fold and (G,H) 2-fold-stage mutant embryos where leading edge epithelial cells have failed to reorient (white arrowheads in F,H). (I-L) 1.5-fold-stage mutant embryos in which dorsal epithelial cells have failed to reorient their axes (white arrowheads) whereas ventral cells in the same embryo appear to have undergone the proper transformation (white arrows). (M) Pharyngeal extension with three distinct steps (Portereiko and Mango, 2001Go) (see text). Scale bars: in A, 10 µm for A,C,E,G,I,K; in B, 10 µm for B,D,F,H,J,L.

 
To test this first possibility we assayed the number of pharyngeal cells in mutant embryos using a GFP reporter, pha-4::GFP (kindly provided by S. Mango), which is strongly expressed in the nuclei of both primordial and differentiated pharyngeal cells as well as in cells comprising the posterior intestinal tract (Horner et al., 1998Go). We focused on embryos at the 1.5-fold stage, as this period of development coincided with the first observed defects in our double mutants. Importantly, at this stage, mutant embryos that had failed to initiate elongation could be readily distinguished from wild-type-appearing embryos. In addition, the relative distribution of most pharyngeal nuclei did not vary significantly between Pun and wild-type embryos at this time, allowing for an even comparison.

An examination of wild-type embryos at the 1.5-fold stage identified an average of 100±3 (n=11; range, 95-104) GFP+ cells in the head region. This figure is in close agreement with previously reported numbers using antibodies against PHA-4 in similar-stage embryos (97±3) (Horner et al., 1998Go) (Fig. 3A,B). An analysis of Pun double-mutant embryos revealed an average of 93±13 GFP+ cells (n=13) with numbers ranging from 66-105. Importantly, 8/13 mutant embryos contained 95 or more GFP+ cells, whereas only 3/13 contained fewer than 91 cells (Fig. 3C,D). Thus, for most embryos examined, the number of cells adopting a pharyngeal identity (based on this GFP marker) was indistinguishable from that of wild type. Similar results were also obtained by examining pha-4::GFP-expressing cells in L1 larvae of double-mutant and wild-type animals (Fig. 3E-H; data not shown). These findings indicate that gross differences in the number of pharyngeal cells alone cannot account for the observed defects in a large subset (perhaps the majority) of the double-mutant embryos. Thus, the failure to elongate is probably unrelated to early steps of pharyngeal cell specification or survival.

We next examined mutant animals for their ability to generate terminally differentiated pharyngeal cell types. The adult pharynx comprises muscle, epithelial and neuronal cells, as well as marginal and gland cell types (Albertson and Thomson, 1976Go; Sulston and Horvitz, 1977Go). We used several different GFP reporter strains to assay for the presence of muscle (Okkema et al., 1993Go), epithelial (Mohler et al., 1998Go) and neuronal cells (Maduro and Pilgrim, 1995Go) in double-mutant embryos and larvae. We found that all three cell types were produced, indicating that mutants are capable of generating most or all of the correct pharyngeal cell types (Fig. 4). Consistent with this, we have observed sustained rhythmic pumping in many severely Pun pharynges of L1 mutant animals, suggesting that most or all terminal cell types have been specified and are physiologically functional, although the overall pharyngeal structure is grossly perturbed. We note that our level of analysis does not allow us to make conclusions regarding the differentiation status of individual cells within the pharynx. Therefore, it is possible that double mutants may contain a subset of improperly or incompletely differentiated pharyngeal cells that could contribute to the observed defects.



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Fig. 4. Expression of differentiation markers in mutant animals. DIC (A,C,E) and corresponding GFP fluorescence (B,D,F) images of ubc-18; lin-35(RNAi) mutant animals. White and black arrowheads indicate anterior and posterior pharyngeal boundaries, respectively. (A,B) Expression of the differentiated muscle cell marker, myo-2::GFP. (C,D) Expression of the adherens junction component and marker for epithelial cell differentiation, ajm-1::GFP. Bracket indicates the region of ajm-1 expression in the non-extended pharynx. (E,F) Neuronal marker (unc-119::GFP) expression in a pharynx that underwent partial extension. White arrows (F) indicate the positions of several GFP+ nuclei that lie within the pharyngeal borders. Scale bar: 10 µm.

 
Given that many of the affected double mutants generate normal numbers of pharyngeal cells that are capable of differentiation, we decided to look closely at early steps of pharyngeal morphogenesis to determine the precise point at which elongation may fail. Morphogenesis of the pharynx can be formally divided into three distinct steps, all of which occur over a relatively short time frame, beginning at the late comma stage of embryonic development, or ~330 minutes into embryonic development (Porteriko and Mango, 2001) (Fig. 5M). During stage I of morphogenesis, epithelial cells in the anterior region of the pharyngeal primordium reorient their long axes to align with the dorsoventral axis of the embryo. At stage II, arcade cells, which reside between the pharyngeal primordium and the buccal cavity, form a continuous epithelium with the newly reoriented pharyngeal epithelial cells. At stage III, the conjoined arcade and anterior pharyngeal cells undergo a contraction, pulling the pharynx towards the buccal cavity.

To aid in our analysis, we used a reporter strain that expresses a membrane-localized GFP-fusion protein under the control of the pha-4 promoter (kindly provided by S. Mango), which allowed us to follow changes in pharyngeal cell shape. In wild-type embryos, elongation was completed by the 1.5-fold stage of embryonic development (~400 minutes into embryonic development; Fig. 5A-D). By contrast, 17 of the 24 double-mutant embryos displayed clear defects in the ability of anterior epithelial cells to initiate or complete the reorientation step (Stage I; Fig. 5E-L). Interestingly, a substantial fraction of the orientation-defective embryos (9/17) were only partially deficient at this step, such that one or more epithelial cells appeared to correctly shift their axes, whereas others remained in their original orientation (Fig. 5I-L). Other mutant embryos (7/24) exhibited more complex and variable defects such as a general disorganization of the leading-edge cells (data not shown). Taken together, these results indicate that lin-35 and ubc-18 functionally cooperate to control a crucial and early step of pharyngeal morphogenesis during C. elegans development.

ubc-18 interactions with SynMuv genes
Previous studies on fzr-1/slr-1 demonstrated a limited set of genetic interactions with class B synthetic multivulval (SynMuv) gene family members (Fay et al., 2002Go). To determine the spectrum of ubc-18 genetic interactions, we inactivated class B SynMuv genes in ubc-18 mutants by RNAi feeding methods and assayed progeny for the appearance of the Pun phenotype (Table 2). All but one of the class B genes tested produced substantial numbers of Pun animals following inactivation by RNAi. These included lin-36 (Thomas and Horvitz, 1999Go) and lin-37 (Boxem and van den Heuvel, 2002Go), two genes of unknown function; the RbAp46/48 homolog, lin-53 (Lu and Horvitz, 1998Go); a C. elegans Mi2 homolog and NURD complex component, let-418 (Solari and Ahringer, 2000Go; von Zelewsky et al., 2000Go); and histone deactylase, hda-1 (Lu and Horvitz, 1998Go). The sole exception in the class B category was efl-1, one of two E2F homologs in C. elegans (Ceol and Horvitz, 2001Go), which failed to produce significant numbers of Pun animals either alone (data not shown) or in the ubc-18 mutant background (Table 2). In addition, we saw no effect following inactivation of the class A SynMuv gene lin-15a (Clark et al., 1994Go; Huang et al., 1994Go). In several cases, these experiments were complicated by non-synthetic RNAi effects as the genes that were being inactivated were themselves essential for viability (Table 2). Nevertheless, in such cases we were still able to observe a marked enrichment in the number of animals displaying the Pun phenotype, demonstrating that inactivation of these genes is interchangeable with lin-35 for the production of this phenotype.


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Table 2. Genetic interactions of ubc-18 with SynMuv genes

 
Recently, Boxem and van den Heuvel (Boxem and van den Heuvel, 2002Go) have shown an involvement of several SynMuv genes, including lin-35, lin-36, efl-1 and lin-15a, in the regulation of the G1- to S-phase transition (also see Boxem and van den Heuvel, 2001Go). Consistent with this, we had previously observed genetic interactions between fzr-1 and lin-35, lin-36 and efl-1 in the production of a synthetic hyperproliferation phenotype (Fay et al., 2002Go). By contrast, lin-37, let-418, lin and hda-1 did not appear to function in cell cycle control (Boxem and van den Heuvel, 2002Go). Thus, the ability of these genes to interact with ubc-18 suggests that the synthetic Pun phenotype does not result from perturbations in cell cycle control per se, and that the role of lin-35 in pharyngeal development is probably not related to its role in regulating cell cycle progression.


    DISCUSSION
 TOP
 SUMMARY
 INTRODUCTION
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Isolation of a mutation in an E2 ubiquitin-conjugating enzyme
Using a screen for mutations that are synthetically lethal with pRB, we have identified a mutation in ubc-18, a gene encoding a putative E2 ubiquitin-conjugating enzyme. The nature of the molecular lesion identified in ubc-18(ku354) mutants, as well as our RNAi analysis, suggests that ku354 may represent a strong loss-of-function allele. The alteration in chemical charge resulting from the E10K mutation occurs in a region that is required for association with E1 activating enzymes (Haas and Siepmann, 1997Go; Tong et al., 1997Go). Several conserved basic residues in this region (equivalent to amino acids R5, R6, and K9 in UBC-18) have been identified as biochemically important for interactions with E1 enzymes (A. Haas, personal communication). Furthermore, the glutamic acid at position ten is highly conserved among many UBCs, including those of the UbcH7 family (Fig. 2; data not shown). Thus, it is likely that the E10K mutation would greatly reduce or abolish interactions between UBC-18 and the upstream E1 activating enzyme, preventing the conjugation of UBC-18 to ubiquitin.

A recent global analysis of gene expression using microarrays in C. elegans indicates that the ubc-18 transcript is present at significant levels in both oocytes and embryos, as well as in late stages of larval development and into adulthood (Hill et al., 2000Go). In addition, using antibodies, LIN-35 has been shown to be expressed throughout development in most or all cell types (Lu and Horvitz, 1998Go). We were unsuccessful in our attempts to generate transgenic animals that express GFP under the control of the ubc-18 promoter using several different reporter constructs (data not shown). Given that transgenic arrays are typically silenced in the C. elegans germline, our results may indicate that ubc-18 expression is germline specific. Consistent with this, data available on the C. elegans expression database (http:://nematode.lab.nig.ac.jp/db/index.html; kindly provided by Y. Kohara) suggest that ubc-18 expression may be largely or completely restricted to germline cells. Germline expression of UBC-18 is also consistent with our observation that maternal ubc-18 function markedly reduced larval lethality in lin-35; ubc-18/+ animals (Table 1).

A genetic interaction between lin-35/Rb and a ubiquitin pathway component
ubc-18 is the second gene that we have identified as a lin-35-synthetic mutation. Simultaneous inactivation of lin-35 and ubc-18 led to growth arrest, infertility and defects in pharyngeal morphogenesis. Based on known roles of these proteins, we believe that LIN-35 and UBC-18 share a set of common targets for transcriptional repression and ubiquitin-mediated degradation, respectively. We hypothesize that the abnormal expression of one or more mutual targets is probably responsible for the pleiotropic defects observed in the double mutants. Thus, in the absence of LIN-35 function, UBC-18 can promote the degradation of some subset of derepressed LIN-35 transcriptional targets. Conversely, UBC-18 function is not essential if LIN-35 is present and actively repressing the expression of its target genes. It is only when both lin-35 and ubc-18 are absent, that one or more proteins can accumulate to levels sufficient to produce the observed developmental defects.

It is also conceivable that the phenotype observed in the double mutants may not be due solely to defects resulting from an increase in the abundance of target proteins. It has become clear in recent years that ubiquitylation can affect protein function by mechanisms unrelated to protein stability. These functions include roles in protein trafficking (reviewed by Pickart, 2001Go), transcription (reviewed by Conaway et al., 2002Go) and signal transduction (Wang et al., 2001Go; Ulrich, 2003Go). Nevertheless, we currently favor a model whereby lin-35 and ubc-18 act coordinately to downregulate the activity of proteins whose presence would be deleterious to specific developmental processes or basic life functions.

Our analysis of the double-mutant animals identified a predominant defect affecting stage I of pharyngeal morphogenesis. This phenotype differs substantially from defects reported for two previously described pharyngeal mutants in C. elegans: pha-1 and pha-4. pha-4 mutants fail to specify any pharyngeal cells, which instead adopt alternative cell fates (Mango et al., 1994Go). In the case of pha-1 mutants, the correct number of pharyngeal cells are initially specified; however, these cells then fail to undergo terminal differentiation (Schnabel and Schnabel, 1990Go; Granato et al., 1994Go). pha-4 and pha-1 encode transcription factors of the FoxA/HNF3 and bZIP families, respectively. pha-4 directly activates the transcription of most or all genes required for pharyngeal identity (Gaudet and Mango, 2002Go). It is possible that lin-35 and ubc-18 act to downregulate one of the early pha-4 target genes in order for morphogenesis to proceed. Alternatively, lin-35 and ubc-18 may negatively regulate genes that are not normally expressed in this tissue but whose expression is deleterious to the development of the organ.

A novel role for lin-35/Rb in morphogenesis and development
At present, relatively little is known about the targets of pRb (particularly those unrelated to cell cycle progression) and even less is known about the substrates of most E2 and E3 enzymes. Given the genetic interactions that we observed between ubc-18 and a number of the SynMuv genes tested (Table 2), it is unlikely that the targets of pRB that are involved in pharyngeal development also function in cell cycle control. Interestingly, we have isolated a second mutation, slr-9(fd1), that produces a synthetic Pun phenotype in conjunction with lin-35. slr-9 has been mapped to a small interval on LGIII that does not contain any predicted proteins with a known involvement in the protein degradation pathway (E.L. and D.S.F., unpublished). Thus, we may be poised to identify either novel components involved in ubiquitin pathway targeting or, possibly, specific effectors of pharyngeal development.

Extensive studies have defined a central and clear role for pRb in regulating entry and progression through the S-phase of the cell cycle. Genetic studies carried out in Drosophila have further suggested that pRb may act exclusively through E2F, as LOF mutations in e2f1, one of two Drosophila E2F homologs, can largely suppress the lethal phenotype of mutations in rbf, one of two known Drosophila Rb-family genes (Du, 2000Go). A separate role for pRb in differentiation, which is independent of its interactions with E2F, is, however, suggested by the observation that certain pRb mutants that are defective at E2F binding can nevertheless induce tissue-specific gene expression and promote differentiation (Sellers et al., 1998Go). In addition, using a cell line that overexpresses a non-regulatable form of pRb, Markey and colleagues (Markey et al., 2002Go) recently identified a large set of putative pRb transcriptional targets that are not known or predicted to be regulated by E2F family members. Finally, E2F family members themselves have been shown through microarray experiments to control the expression of a diverse set of targets including a number of genes associated with differentiation and development (Ishida et al., 2001Go; Muller et al., 2001Go).

Thus, our synthetic lethal screen has uncovered a function for lin-35/Rb that is distinct from those previously described for pRB in higher eukaryotes. Additional developmental functions of lin-35 should be revealed by the further analysis of lin-35 synthetic mutants and by looking directly for interactions between lin-35 and other putative E2 and E3 enzymes using an RNAi approach. Furthermore, by identifying specific phenotypes for putative E2 and E3 enzymes, it may also be possible to make predictions regarding the functional and biochemical associations between the many E2 and E3 enzymes present in the C. elegans genome.


    ACKNOWLEDGMENTS
 
We thank the C. elegans Genetics Consortium, Susan Mango, Jeff Hardin, Peter Candido, Andy Fire and David Pilgrim for strains and constructs. We thank Alan Coulson for cosmids. We also thank Susan Mango, Peter Candido, Eric Lambie and Arthur Hass for helpful discussions. We thank Yuji Kohara for his expression and EST database. We thank Amy Fluet, Mike Krause and John Yochem for a critical reading of this manuscript. This work was supported by a research grant from the American Cancer Society, the University of Wyoming, and by NIH grant GM47869.


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