Robert K. Herman

A uniform genetic nomenclature for the nematode Caenorhabditis elegans

SummaryA uniform system of genetic nomenclature for the nematode Caenorhabditis elegans is described. Convenient ways are specified to designate genes, mutations and strains, and to attempt to avoid name duplications.

The C. elegans gene lin-44, which controls the polarity of certain asymmetric cell divisions, encodes a Wnt protein and acts cell nonautonomously

Mutations in the C. elegans gene lin-44 lead to reversals in the polarity of certain asymmetric cell divisions. We have discovered that lin-44 is a member of the Wnt family of genes, which encode secretory glycoproteins implicated in intercellular signaling. Both in situ hybridization experiments using lin-44 transcripts and experiments using reporter constructs designed to mimic patterns of lin-44 expression indicate that lin-44 is expressed in hypodermal cells at the tip of the tail and posterior to the cells with polarities affected by lin-44 mutations. Our mosaic analysis indicates that lin-44 acts cell nonautonomously. We propose that LIN-44 protein is secreted by tail hypodermal cells and affects the polarity of asymmetric cell divisions that occur more anteriorly in the tail.

The acetylcholinesterase genes of C. elegans: Identification of a third gene (ace-3) and mosaic mapping of a synthetic lethal phenotype

In C. elegans, the newly identified ace-3 is the third gene affecting acetylcholinesterase (AChE) activity. ace-3 II specifically affects class C AChE and is unlinked to ace-1 X or ace-2 I, which affect the other two AChE classes (A and B, respectively). Strains homozygous for an ace-3 mutation have no apparent behavioral or developmental defect; ace-1 ace-3 and ace-2 ace-3 double mutants are also nearly wild type. In contrast, ace-1 ace-2 ace-3 triple mutant animals are paralyzed and developmentally arrested; their embryonic development is relatively unimpaired, but they are unable to grow beyond the hatching stage. Based on the analysis of genetic mosaics, we conclude that in the absence of ace-2 and ace-3 function, the expression of ace-1(+) in muscle cells, but not in neurons, is essential for postembryonic viability.

UNC-115, a Conserved Protein with Predicted LIM and Actin-Binding Domains, Mediates Axon Guidance in C. elegans

Axon guidance receptors modulate the growth cone cytoskeleton through signaling pathways that are not well understood. Here, we describe the C. elegans unc-115 gene, which encodes a candidate cytoskeletal linker protein that acts in axon guidance. unc-115 mutants have defects in a subset of axons, particularly as the affected axons change environments during outgrowth. The unc-115 gene encodes a putative actin-binding protein that is similar to the human actin-binding protein abLIM/limatin; it has a villin headpiece domain and three LIM domains that could mediate protein interactions. unc-115 is expressed in neurons during their development and is required cell-autonomously in certain neurons for normal axon guidance. We propose that UNC-115 modulates the growth cone actin cytoskeleton in response to signals received by growth cone receptors.

The Molecular Identities of the Caenorhabditis elegans Intraflagellar Transport Genes dyf-6, daf-10 and osm-1

The Caenorhabditis elegans genes dyf-6, daf-10, and osm-1 are among the set of genes that affect chemotaxis and the ability of certain sensory neurons to take up fluorescent dyes from the environment. Some genes in this category are known to be required for intraflagellar transport (IFT), which is the bidirectional movement of raft-like particles along the axonemes of cilia and flagella. The cloning of dyf-6, daf-10, and osm-1 are described here. The daf-10 and osm-1 gene products resemble each other and contain WD and WAA repeats. DYF-6, the product of a complex locus, lacks known motifs, but orthologs are present in flies and mammals. Phenotypic analysis of dyf-6 mutants expressing an OSM-6∷GFP reporter indicates that the cilia of the amphid and phasmid dendritic endings are foreshortened. Consistent with genetic mosaic analysis, which indicates that dyf-6 functions in neurons of the amphid sensilla, DYF-6∷GFP is expressed in amphid and phasmid neurons. Movement of DYF-6∷GFP within the ciliated endings of the neurons indicates that DYF-6 is involved in IFT. In addition, IFT can be observed in dauer larvae.

SMU-2 and SMU-1, Caenorhabditis elegans Homologs of Mammalian Spliceosome-Associated Proteins RED and fSAP57, Work Together To Affect Splice Site Choice

ABSTRACT Mutations in the Caenorhabditis elegans gene smu-2 suppress mec-8 and unc-52 mutations. It has been proposed that MEC-8 regulates the alternative splicing of unc-52 transcripts, which encode the core protein of perlecan, a basement membrane proteoglycan. We show that mutation in smu-2 leads to enhanced accumulation of transcripts that skip exon 17, but not exon 18, of unc-52, which explains our finding that smu-2 mutations suppress the uncoordination conferred by nonsense mutations in exon 17, but not in exon 18, of unc-52. We conclude that smu-2 encodes a ubiquitously expressed nuclear protein that is 40% identical to the human RED protein, a component of purified spliceosomes. The effects of smu-2 mutation on both unc-52 pre-mRNA splicing and the suppression of mec-8 and unc-52 mutant phenotypes are indistinguishable from the effects of mutation in smu-1, a gene that encodes a protein that is 62% identical to human spliceosome-associated protein fSAP57. We provide evidence that SMU-2 protects SMU-1 from degradation in vivo. In vitro and in vivo coimmunoprecipitation experiments indicate that SMU-2 and SMU-1 bind to each other. We propose that SMU-2 and SMU-1 function together to regulate splice site choice in the pre-mRNAs of unc-52 and other genes.

Analysis of smu-1, a gene that regulates the alternative splicing of unc-52 pre-mRNA in Caenorhabditis elegans.

ABSTRACT Mutations in the smu-1 gene of Caenorhabditis elegans were previously shown to suppress mutations in the genes mec-8 and unc-52.mec-8 encodes a putative RNA binding protein that affects the accumulation of specific alternatively spliced mRNA isoforms produced by unc-52 and other genes.unc-52 encodes a set of basement membrane proteins, homologs of mammalian perlecan, that are important for body wall muscle assembly and attachment to basement membrane, hypodermis, and cuticle. We show that a presumptive null mutation in smu-1suppresses nonsense mutations in exon 17 but not exon 18 ofunc-52 and enhances the phenotype conferred by anunc-52 splice site mutation in intron 16. We have used reverse transcription-PCR and RNase protection to show that loss-of-function smu-1 mutations enhance accumulation in larvae of an alternatively spliced isoform that skips exon 17 but not exon 18 of unc-52. We have identified smu-1 molecularly; it encodes a nuclearly localized protein that contains five WD motifs and is ubiquitously expressed. The SMU-1 amino acid sequence is more than 60% identical to a predicted human protein of unknown function. We propose that smu-1 encodes a trans-acting factor that regulates the alternative splicing of the pre-mRNA ofunc-52 and other genes.

Investigating C. elegans development through mosaic analysis

The analysis of genetically mosaic worms, in which some cells carry a wild-type gene and others are homozygous mutant, can reveal where in the animal a gene acts to prevent the appearance of a mutant phenotype. In this primer article, we describe how Caenorhabditis elegans genetic mosaics are generated, identified and analyzed, and we discuss examples in which the analysis of mosaic worms has provided important information about the development of this organism.

Muscle-specific expression of a gene affecting acetylcholinesterase in the nematode caenorhabditis elegans

We have generated C. elegans animals that carry a duplication as a free chromosome fragment bearing an ace-1+ gene in an otherwise homozygous ace-1 ace-2 genetic background. The single ace-1+ gene in these animals is responsible for coordinated animal movement and acetylcholinesterase activity in the regions of the nerve ring and ventral and dorsal nerve cords, as judged by histochemical assay. We have used other genes on the free duplication whose cell-specific expressions have already been elucidated to identify particular genetic mosaics produced by spontaneous somatic loss of the duplication. The analysis of these mosaics has led us to conclude that the synthesis of acetylcholinesterase by muscle cells is primarily responsible for the coordinated movement conferred by the ace-1+ gene.

Changing styles in C. elegans genetics

The past 30 years have taken the nematode Caenorhabditis elegans from obscurity, as a nondescript member of a large but unglamorous invertebrate phylum, to a position as one of the major model organisms. This year, it will acquire a particular celeberity as the owner of the first animal genome to be sequenced in its entirety. In this review we consider the ways in which genetical investigations of this species have begun to change and what some of the consequences of the completion of the sequence are likely to be.