ACT-5 is an essential Caenorhabditis elegans actin required for intestinal microvilli formation.

Investigation of Caenorhabditis elegans act-5 gene function revealed that intestinal microvillus formation requires a specific actin isoform. ACT-5 is the most diverged of the five C. elegans actins, sharing only 93% identity with the other four. Green fluorescent protein reporter and immunofluorescence analysis indicated that act-5 gene expression is limited to microvillus-containing cells within the intestine and excretory systems and that ACT-5 is apically localized within intestinal cells. Animals heterozygous for a dominant act-5 mutation looked clear and thin and grew slowly. Animals homozygous for either the dominant act-5 mutation, or a recessive loss of function mutant, exhibited normal morphology and intestinal cell polarity, but died during the first larval stage. Ultrastructural analysis revealed a complete loss of intestinal microvilli in homozygous act-5 mutants. Forced expression of ACT-1 under the control of the act-5 promoter did not rescue the lethality of the act-5 mutant. Together with immuno-electron microscopy experiments that indicated ACT-5 is enriched within microvilli themselves, these results suggest a microvillus-specific function for act-5, and further, they raise the possibility that specific actins may be specialized for building microvilli and related structures.

Identifying muscle regulatory elements and genes in the nematode Caenorhabditis elegans.

We report the identification of several putative muscle-specific regulatory elements, and genes which are expressed preferentially in the muscle of the nematode Caenorhabditis elegans. We used computational pattern finding methods to identify cis-regulatory motifs from promoter regions of a set of genes known to express preferentially in muscle; each motif describes the potential binding sites for an unknown regulatory factor. The significance and specificity of the identified motifs were evaluated using several different control sequence sets. Using the motifs, we searched the entire C. elegans genome for genes whose promoter regions have a high probability of being bound by the putative regulatory factors. Genes that met this criterion and were not included in our initial set were predicted to be good candidates for muscle expression. Some of these candidates are additional, known muscle expressed genes and several others are shown here to be preferentially expressed in muscle cells by using GFP (green fluorescent protein) constructs. The methods described here can be used to predict the spatial expression pattern of many uncharacterized genes.

Purification and polymerization properties of two lethal yeast actin mutants.

The budding yeast Saccharomyces cerevisiae contains a single actin gene and the gene product, actin, is essential for growth. Two mutants of yeast actin that do not support yeast growth were prepared from yeast by coexpressing the mutant and a 6-histidine-tagged wild-type actin followed by separation of the wild-type and mutant actin using Ni-NTA chromatography as described elsewhere [Buzan, J., Du, J., Karpova, T., and Frieden, C. (1999) Proc. Natl. Acad. Sci. USA 96, 2823-2827]. The mutations, in muscle actin numbering, were at positions 334 (Glu334Lys) and 168 (Gly168Arg) and were chosen based on phenotypic changes observed in the behavior of actin mutants of Caenorhabditis elegans. Glu334 is located on the surface of actin between subdomains 1 and 3 while Gly168 is located in a region near actin-actin contacts in the actin filament. The Glu334Lys mutant polymerized slightly faster than wild-type yeast actin, suggesting that loss of interactions with some actin binding protein, rather than loss of actin-actin contacts, was responsible for its inability to support yeast growth. The Gly168Arg mutant polymerized at a rate similar to wild-type but the extent was considerably less, kinetic characteristics suggesting a high critical concentration (ca. 4 microM) without a large change in the ability to form nuclei for the nucleation-elongation process.

Myotactin, a novel hypodermal protein involved in muscle-cell adhesion in Caenorhabditis elegans.

In C. elegans, assembly of hypodermal hemidesmosome-like structures called fibrous organelles is temporally and spatially coordinated with the assembly of the muscle contractile apparatus, suggesting that signals are exchanged between these cell types to position fibrous organelles correctly. Myotactin, a protein recognized by monoclonal antibody MH46, is a candidate for such a signaling molecule. The antigen, although expressed by hypodermis, first reflects the pattern of muscle elements and only later reflects the pattern of fibrous organelles. Confocal microscopy shows that in adult worms myotactin and fibrous organelles show coincident localization. Further, cell ablation studies show the bodywall muscle cells are necessary for normal myotactin distribution. To investigate myotactin's role in muscle-hypodermal signaling, we characterized the myotactin locus molecularly and genetically. Myotactin is a novel transmembrane protein of approximately 500 kd. The extracellular domain contains at least 32 fibronectin type III repeats and the cytoplasmic domain contains unique sequence. In mutants lacking myotactin, muscle cells detach when embryonic muscle contraction begins. Later in development, fibrous organelles become delocalized and are not restricted to regions of the hypodermis previously contacted by muscle. These results suggest myotactin helps maintain the association between the muscle contractile apparatus and hypodermal fibrous organelles.

Phosphorylation of the N-terminal region of Caenorhabditis elegans paramyosin.

Paramyosin from Caenorhabditis elegans was examined for post-translational modification by phosphorylation. Paramyosin purified from populations of mixed-age animals contained 0.7 to 2.0 moles of phosphate per mole of paramyosin. Paramyosin was also phosphorylated in vitro by an endogenous kinase in the particulate fraction. Analysis of the in vitro phosphorylated paramyosin in comparison with the DNA sequence of the unc-15 paramyosin gene of C. elegans shows that serine residues in the non-alpha-helical N-terminal region are the targets of the kinase. The N-terminal region of paramyosin has significant similarity to the non-helical C-terminal region of the two body wall myosin heavy chains of C. elegans. All three regions contain three copies of a Ser-*-Ser-*-Ala motif, the most likely target for phosphorylation in paramyosin, suggesting that these regions may be modified by the same kinase.

Transposon-induced deletions in unc-22 of C. elegans associated with almost normal gene activity.

The unc-22 gene of Caenorhabolitis elegans encodes a protein which is a component of the myosin-containing A-band of the worm's striated body-wall muscle. Among 51 revertants of a transposon-induced mutant, we have identified four which retain a barely detectable mutant phenotype. Molecular analysis shows that three of these have in-frame deletions of 1.0, 1.3 and 2.0 kilobases, whereas the fourth partial revertant and two other apparently complete revertants have small insertions. All these rearrangements involve coding sequence and, in the case of the deletions, result in polypeptides that are shorter than the wild-type protein. The region of the gene containing these rearrangements contains 10 copies of a motif recognized in other regions of the gene (our unpublished data). We suggest that one explanation for the minimally mutant phenotype associated with the deletions is that the size and the repeated nature of the unc-22 protein structure make it relatively tolerant of substitutions or deletions involving one or a small number of repeated motifs. These results could explain why in some human genetic diseases, such as Duchenne's muscular dystrophy, deletions can be associated with only mild forms of the disease.

Identification and intracellular localization of the unc-22 gene product of Caenorhabditis elegans.

The unc-22 gene is one of a set of genes identified using classical genetics that affect muscle structure and function in the free-living nematode Caenorhabditis elegans. Since cloning the unc-22 gene by transposon tagging, we have used conventional techniques combined with a set of Tc1 transposon insertion alleles to characterize the gene and its products. The gene extends over more than 20 kb of genomic sequence and produces a transcript of approximately 14 kb. A polyclonal antibody raised against an Escherichia coli beta-galactosidase-unc-22 fusion protein recognizes a polypeptide in nematode extracts that is between 500,000 and 600,000 daltons and labels the muscle A-band in indirect immunofluorescent microscopy. The Tc1-induced alleles have been used at every stage to verify these conclusions. The Tc1 insertions are spread over much of the region that contributes to the mature transcript; in most alleles, Tc1 sequences are incorporated into a composite unc-22-Tc1 transcript. The large protein is either absent or severely reduced in amounts in the mutants. In one case, a truncated polypeptide was also identified. The location of the protein in the A-band, along with earlier genetic data, suggests that the unc-22 product may interact with myosin to regulate its function.

An inexpensive computerized enzyme kinetics system based on a Gilford spectrophotometer and an Apple IIe microcomputer.

A microcomputer-controlled data acquisition system for spectrophotometric enzyme kinetics measurements has been assembled. The system uses an Apple IIe computer which is interfaced to the binary coded decimal output of a Gilford spectrophotometer. No analog-to-digital converter had to be purchased. A BASIC program which collects timed absorbance readings every 500 ms, plots the data in real time, performs a linear regression of the data to measure the reaction rate, and calculates the enzyme activity concentration is given in full. Details describing the interfacing of the computer to the spectrophotometer are presented which will permit other laboratories to readily assemble their own systems using this hardware. Kinetic data acquired by the system are highly reproducible and agree well with data processed much more slowly by manual techniques from strip chart recordings.