Mutations affecting nerve attachment of Caenorhabditis elegans.

Using a pan-neuronal GFP marker, a morphological screen was performed to detect Caenorhabditis elegans larval lethal mutants with severely disorganized major nerve cords. We recovered and characterized 21 mutants that displayed displacement or detachment of the ventral nerve cord from the body wall (Ven: ventral cord abnormal). Six mutations defined three novel genetic loci: ven-1, ven-2, and ven-3. Fifteen mutations proved to be alleles of previously identified muscle attachment/positioning genes, mup-4, mua-1, mua-5, and mua-6. All the mutants also displayed muscle attachment/positioning defects characteristic of mua/mup mutants. The pan-neuronal GFP marker also revealed that mutants of other mua/mup loci, such as mup-1, mup-2, and mua-2, exhibited the Ven defect. The hypodermis, the excretory canal, and the gonad were morphologically abnormal in some of the mutants. The pleiotropic nature of the defects indicates that ven and mua/mup genes are required generally for the maintenance of attachment of tissues to the body wall in C. elegans.

Characterization of Ce-atl-1, an ATM-like gene from Caenorhabditis elegans.

An ATM-like gene was identified in the genome of Caenorhabditis elegans. The putative product of the gene, termed Ce-atl-1 (C. elegans ATM-like 1) consists of 2514 amino acid residues. The C-terminal sequence, which contains a PI-3 kinase-like domain, showed good homology with the products of the gene MEC1/ESR1 from budding yeast, the rad3+ gene of fission yeast and mammalian ATM (ataxia-telangiectasia and rad3+ related) genes. The results of RNA-mediated interference indicated that the major phenotype associated with repression of Ce-atl-1 was lethality (approximately 50-80%) during early embryogenesis. Among the surviving progeny, males (XO animals) arose at a high frequency (2-30%). In addition, 5% of oocyte chromosomes demonstrated aneuploidy due to a defect in pre-meiotic chromosomal segregation. Gene expression analyses indicated that Ce-atl-1 mRNA was expressed in all larval stages and that its level increased about fivefold in the adult stage. The adult expression level was decreased in the glp-4 mutant, which is defective in germ line proliferation. Ce-atl-1 was strongly expressed in both the mitotic and meiotic cells of adult gonads. In summary, Ce-atl-1 appears to be important for early embryogenesis, and loss of its function results in a defect in chromosome segregation, similar to what has been observed for AT-related proteins.

The conserved nuclear receptor Ftz-F1 is required for embryogenesis, moulting and reproduction in Caenorhabditis elegans.

BACKGROUND: Nuclear receptors are essential players in the development of all metazoans. The nematode Caenorhabditis elegans possesses more than 200 putative nuclear receptor genes, several times more than the number known in any other organism. Very few of these transcription factors are conserved with components of the steroid response pathways in vertebrates and arthropods. Ftz-F1, one of the evolutionarily oldest nuclear receptor types, is required for steroidogenesis and sexual differentiation in mice and for segmentation and metamorphosis in Drosophila. RESULTS: We employed two complementary approaches, direct mutagenesis and RNA interference, to explore the role of nhr-25, a C. elegans ortholog of Ftz-F1. Deletion mutants show that nhr-25 is essential for embryogenesis. RNA interference reveals additional requirements throughout the postembryonic life, namely in moulting and differentiation of the gonad and vulva. All these defects are consistent with the nhr-25 expression pattern, determined by in situ hybridization and GFP reporter activity. CONCLUSIONS: Our data link the C. elegans Ftz-F1 ortholog with a number of developmental processes. Significantly, its role in the periodical replacement of cuticle (moulting) appears to be evolutionarily shared with insects and thus supports the monophyletic origin of moulting.

Identification and characterization of the high-affinity choline transporter.

In cholinergic neurons, high-affinity choline uptake in presynaptic terminals is the rate-limiting step in acetylcholine synthesis. Using information provided by the Caenorhabditis elegans Genome Project, we cloned a cDNA encoding the high-affinity choline transporter from C. elegans (cho-1). We subsequently used this clone to isolate the corresponding cDNA from rat (CHT1). CHT1 is not homologous to neurotransmitter transporters, but is homologous to members of the Na+-dependent glucose transporter family. Expression of CHT1 mRNA is restricted to cholinergic neurons. The characteristics of CHT1-mediated choline uptake essentially match those of high-affinity choline uptake in rat brain synaptosomes.

UNC-4/UNC-37-dependent repression of motor neuron-specific genes controls synaptic choice in Caenorhabditis elegans.

The UNC-4 homeoprotein and the Groucho-like corepressor UNC-37 specify synaptic choice in the Caenorhabditis elegans motor neuron circuit. In unc-4 mutants, VA motor neurons are miswired with inputs from interneurons normally reserved for their lineal sisters, the VB motor neurons. Here we show that UNC-4 and UNC-37 function together in VA motor neurons to repress VB-specific genes and that this activity depends on physical contact between UNC-37 and a conserved Engrailed-like repressor domain (eh1) in UNC-4. Missense mutations in the UNC-4 eh1 domain disrupt interactions between UNC-4 and UNC-37 and result in the loss of UNC-4-dependent repressor activity in vivo. A compensatory amino acid substitution in UNC-37 suppresses specific unc-4 alleles by restoring physical interactions with UNC-4 as well as UNC-4-dependent repression of VB-specific genes. We propose that repression of VB-specific genes by UNC-4 and UNC-37 is necessary for the creation of wild-type inputs to VA motor neurons. The existence of mammalian homologs of UNC-4 and UNC-37 indicates that a similar mechanism could regulate synaptic choice in the vertebrate spinal cord.

A novel WD40 protein, CHE-2, acts cell-autonomously in the formation of C. elegans sensory cilia.

To elucidate the mechanism of sensory cilium formation, we analyzed mutants in the Caenorhabditis elegans che-2 gene. These mutants have extremely short cilia with an abnormal posterior projection, and show defects in behaviors that are mediated by ciliated sensory neurons. The che-2 gene encodes a new member of the WD40 protein family, suggesting that it acts in protein-protein interaction. Analysis of mutation sites showed that both the amino-terminal WD40 repeats and the carboxyl-terminal non-WD40 domain are necessary for the CHE-2 function. CHE-2-tagged green fluorescent protein is localized at the cilia of almost all the ciliated sensory neurons. Expression of che-2 in a subset of sensory neurons of a che-2 mutant by using a heterologous promoter resulted in restoration of the functions and cilium morphology of only the che-2-expressing neurons. Thus, che-2 acts cell-autonomously. This technique can be used in the future for determining the function of each type of che-2-expressing sensory neuron. Using green fluorescent protein, we found that the extension of cilia in wild-type animals took place at the late embryonic stage, whereas the cilia of che-2 mutant animals remained always short during development. Hence, the abnormal posterior projection is due to the inability of cilia to extend, rather than degeneration of cilia once correctly formed. Expression of che-2 in a che-2 mutant under a heat shock promoter showed that the extension of cilia, surprisingly, can occur even at the adult stage, and that such cilia can function apparently normally in behavior.

An ion channel of the degenerin/epithelial sodium channel superfamily controls the defecation rhythm in Caenorhabditis elegans.

Ultradian rhythms are widespread phenomena found in various biological organisms. A typical example is the defecation behavior of the nematode Caenorhabditis elegans, which repeats at about 45-sec intervals. To elucidate the mechanism, we studied flr-1 mutants, which show very short defecation cycle periods. The mutations also affect some food-related functions, including growth rate, the expulsion step of defecation behavior, and the regulation of the dauer larva (a nonfeeding, special third-stage larva) formation in the unc-3 (Olf-1/EBF homolog) background. The flr-1 gene encodes a novel ion channel belonging to the DEG/ENaC (C. elegans degenerin and mammalian epithelial sodium channel) superfamily. A flr-1::GFP (green fluorescent protein) fusion gene that can rescue the flr-1 mutant phenotypes is expressed only in the intestine from embryos to adults. These results suggest that FLR-1 may be a component of an intestinal regulatory system that controls the defecation rhythm as well as other functions.

Characterization of a Caenorhabditis elegans recA-like gene Ce-rdh-1 involved in meiotic recombination.

A recA-like gene was identified in the Caenorhabditis elegans genome project database. The putative product of the gene, termed Ce-rdh-1 (C. elegans RAD51 and DMC1/LIM15 homolog 1), consists of 357 amino acid residues. The predicted amino acid sequence of Ce-rdh-1 showed 46-60% identity to both RAD51 type and DMC1/LIM15 type genes in several eukaryote species. The results of RNAi (RNA-mediated interference) indicated that repression of Ce-rdh-1 blocked chromosome condensation of six bivalents and dissociation of chiasmata in oocytes of F1 progeny. Oogenesis did not proceed to the diakinesis stage. Accordingly, all the eggs produced (F2) died in early stages. These results suggest that Ce-rdh-1 participates in meiotic recombination.

hch-1, a gene required for normal hatching and normal migration of a neuroblast in C. elegans, encodes a protein related to TOLLOID and BMP-1.

Proteins of the tolloid/bone morphogenetic protein (BMP)-1 family play important roles in the differentiation of cell fates. Among those proteins are BMP-1, which plays a role in cartilage and bone formation in mammals, the TOLLOID protein, which is required for the establishment of the dorsoventral axis of Drosophila embryos and BP10/SpAN, which are thought to act in the morphogenesis of sea urchins. These proteins have some properties in common. First, they contain the astacin metalloprotease domain, the CUB domain and the epidermal growth factor-like domain. Second, they are expressed in embryos at stages expected for their role in cell differentiation. Third, at least BMP-1 and TOLLOID are thought to interact with proteins of the transforming growth factor-beta family. We report that the hch-1 gene of the nematode Caenorhabditis elegans encodes a tolloid/BMP-1 family protein. The protein has the characteristic domains common to the tolloid/ BMP-1 family. Like other members of the family, it is expressed in embryos. However, the phenotype of hch-1 mutants shows that it is required for normal hatching and normal migration of a post-embryonic neuroblast. Furthermore, in spite of its expression in embryogenesis, it is not required for the viability of embryos. These results show new functions of the tolloid/BMP-1 family proteins and give insight into their evolution.

Isolation, characterization and epistasis of fluoride-resistant mutants of Caenorhabditis elegans.

We have isolated 13 fluoride-resistant mutants of the nematode Caenorhabditis elegans. All the mutations are recessive and mapped to five genes. Mutants in three of the genes (class 1 genes: flr-1 X, flr-3 IV, and flr-4 X) are resistant to 400 micrograms/ml NaF. Furthermore, they grow twice as slowly as and have smaller brood size than wild-type worms even in the absence of fluoride ion. In contrast, mutants in the other two genes (class 2 genes: flr-2 V and flr-5 V) are only partially resistant to 400 micrograms/ml NaF, and they have almost normal growth rates and brood sizes in the absence of fluoride ion. Studies on the phenotypes of double mutants showed that class 2 mutations are epistatic to class 1 mutations concerning growth rate and brood size but hypostatic with respect to fluoride resistance. We propose two models that can explain the epistasis. Since fluoride ion depletes calcium ion, inhibits some protein phosphatases and activates trimeric G-proteins, studies on these mutants may lead to discovery of a new signal transduction system that controls the growth of C. elegans.

In search of new mutants in cell-signaling systems of the nematode Caenorhabditis elegans. Review.

Development of multicellular organisms is controlled mainly by cell-signaling systems. In this review I first discuss methods of genetic analysis and properties of mutants of cell-signaling systems in general and in the nematode C. elegans. Then, I describe two of our approaches to isolating new mutants in cell-signaling of C. elegans. The first approach is to select for mutants that have the same visible phenotype as those in known cell-signaling genes. In a survey of larval lethal mutations we found that there are quite a few mutants in which the inner surface of the body wall is detached from the outer surface of the intestine. Some of them map in genes that are known to act in cell-signaling systems in vulval induction or sex myoblast migration, which are not essential to the growth and survival of C. elegans. Therefore, we think many of the mutations of the above phenotype disrupt cell-signaling in an unidentified essential function, and also cell-signaling in the non-essential functions. The second approach is to isolate mutants resistant to a drug expected to disturb cell-signaling. As the drug we have chosen sodium fluoride, which depletes calcium ion, activates G-proteins and inactivates some phosphatases. The mutants are grouped into two classes (three and two genes, respectively) according to degree of fluoride-resistance and growth rate of larvae. Although there is so far no direct evidence that these mutants are related to cell-signaling, they show complex epistasis that can be explained by a model consisting of a cell-signaling pathway.

Structure and inherent properties of the bacteriophage lambda head shell. VII. Molecular design of the form-determining major capsid protein.

Some mutations in the major capsid protein (gpE) of lambda phage can alter the size and shape of the head shell or block the pathway of head maturation. Previous studies on the classification of such mutants showed that there are at least five functional sites on the gpE molecule. In this study, we determined the amino acid exchanges by DNA sequencing to elucidate the molecular design of the form-determining multifunctional protein gpE. In addition, we characterized the mutated gpE molecules by two-dimensional gel electrophoresis and studied suppression patterns of amber mutants at 43 amino acid residues. Those mutations map at 19 amino acid residues at 22 bases, which are located in three regions, 40 to 91, 222 to 246, and 284 to 324 of the 341 amino acid residues of gpE. These regions seem to be important in the activity of gpE, since amber mutations in these regions are suppressed on the average by less species of suppressors than those outside these regions. The mutations having different phenotypes are not segregated from each other, while some mutations having the same phenotype are separated far apart in the primary structure. This suggests that the functional sites were formed during evolution after the folding pattern of the ancestral gpE polypeptide chain had been established. Many of the mutations are located at serine, glycine and proline residues in predicted beta-turns.

Mechanism of length determination in bacteriophage lambda tails.

The mechanism of length determination in bacteriophage lambda tails is discussed as a model for regulation in protein assembly systems. The lambda tail is a long flexible tube ending in a conical part and a single tail fiber. Its length is exactly determined in the sense that the number of major tail protein (gpV) molecules, which comprise more than 80% of the mass of the tail, is exactly the same in all tails. Assembly of gpV is regulated by the initiator complex, which contains the tail fiber and the conical part, and by the terminator protein gpU. There are two key points in the assembly of gpV with respect to length determination. (1) Assembly of gpV on the initiator pauses at the correct tail length. Binding of gpU to the tail only fixes the pause firmly. (2) When the tail length is too short, binding of gpU to tails is inhibited. Deletions and a duplication (both in frame) in gene H, which codes for one of the proteins in the initiator, result in production of phage particles with altered tail length. Moreover, the tail length is roughly proportional to the length of the mutated versions of gene H. This shows that the tail length is measured by the length of gene H protein (gpH), which seems to be approximately as long as the tail tube, if extended like a thread, according to secondary structure prediction (alpha-helices connected by other structures). Various pieces of evidence show that about six molecules of gpH are attached to the remaining portion of the initiator by the C-terminal part and folded into a somewhat compact form, while they are elongated as they are enclosed in the tail tube during assembly of gpV. Unlike interaction between the length-measuring genome RNA and the coat protein of tobacco mosaic virus, the major tail protein gpV does not bind specifically to the ruler protein gpH. Rather, gpH determines the tail length by inhibiting the binding of gpU to short tails and by signalling the pause when the correct tail length is attained.

Primary structure and transcriptional regulation of rat pepsinogen C gene.

The entire rat pepsinogen C gene has been isolated from a rat genomic library, using the rat pepsinogen C cDNA as a probe. Southern blot analysis showed that there exists at least two rat pepsinogen C genes. The nucleotide sequences of the coding regions and the 5'- and 3'-flanking regions of one of the rat pepsinogen C genes have been determined. This gene is split into 9 exons interrupted by eight intervening sequences. The 5'-flanking region is similar to that of the human pepsinogen C gene, but only the former has the core sequence of the Sp1 binding site. The amount of transcripts of the rat pepsinogen C genes was found to increase during development, and a similar increase was shown to be induced by injection of hydrocortisone. As a candidate of a factor which regulates the transcription, we found a 25-kDa protein by Southwestern blotting. It binds to a specific site in the 5'-flanking region of the gene only in the presence of Mg2+ ion, and it is present in the nuclear fraction of the gastric mucosa but not of the liver.

Structure and inherent properties of the bacteriophage lambda head shell. VI. DNA-packaging-defective mutants in the major capsid protein.

Some amino acid substitutions in the major capsid protein (gene E product) of lambda phage are found to cause a defect in DNA packaging. These substitutions permit initiation of DNA packaging and expansion of the prohead. However, cleavage of the concatemer DNA at the cos site takes place only to a very small extent, and the capsid eventually becomes empty. Interestingly, the mutations are suppressed by a decrease of the DNA length between the cos sites by 8000 to 10,000 bases. These properties are similar to those of amber mutants in gene D, which codes for the capsid outer-surface protein. Studies on the E missense.D amber double mutant show that the E protein and the D protein contribute additively to the stabilization of the condensed form of the DNA molecule in phage heads.

DNA methylation and expression of the rat pepsinogen gene in embryonic, adult, and neoplastic tissues.

The relationship between methylation and expression of rat pepsinogen 1 (Pg1) genes was investigated in various tissues. On Northern blotting with a Pg1 complementary DNA probe, Pg1 mRNA was detected only in the glandular stomach of normal rats. Methylation analysis with Msp1/HpaII and Hha1 revealed tissue specific methylation patterns of Pg1 genes with less methylated in the stomach than in other normal tissues not expressing the genes. During stomach development, there was a progressive increase in the Pg1 mRNA level that almost coincided with change in the mucosal pepsinogen level and progressive demethylation after the onset of transcription. Thus, there was an inverse correlation between methylation and expression of Pg1 genes, suggesting a role of DNA methylation in Pg1 gene regulation during normal differentiation, although not its primary role in gene activation. There was no detectable Pg1 mRNA in either primary or transplanted stomach cancers induced by N-methyl-N'-nitro-N-nitrosoguanidine. The methylation patterns of Pg1 genes were different from those of normal tissues that expressed the gene and of those that did not and no simple correlation was observed between methylation and expression of Pg1 genes. This result is consistent with a previous finding that DNA methylation is deranged in tumor cells.

Determination of bacteriophage lambda tail length by a protein ruler.

How the size and shape of living structures are determined by genetic information is one of the fundamental problems in biology. Here I describe a study in which the size of a biological supramolecular structure was changed in a predictable way by in vitro genetics, with the size both before and after manipulation being exactly determined. I have studied the tail of bacteriophage lambda, whose length is determined by the length of the 'ruler protein', the product of gene H. The length of the tail can be decreased or increased by deleting the middle part of gene H or by forming a small duplication there, and the length of the tail is proportional to the size of the protein. These results can be regarded as a special case of protein engineering, namely supramolecular protein engineering.