Immunochemical localization of myosin heavy chain isoforms and paramyosin in developmentally and structurally diverse muscle cell types of the nematode Caenorhabditis elegans.

The nematode Caenorhabditis elegans contains two major groups of muscle cells that exhibit organized sarcomeres: the body wall and pharyngeal muscles. Several additional groups of muscle cells of more limited mass and spatial distribution include the vulval muscles of hermaphrodites, the male sex muscles, the anal-intestinal muscles, and the gonadal sheath of the hermaphrodite. These muscle groups do not exhibit sarcomeres and therefore may be considered smooth. Each muscle cell has been shown to have a specific origin in embryonic cell lineages and differentiation, either embryonically or postembryonically (Sulston, J. E., and H. R. Horvitz. 1977. Dev. Biol. 56:110-156; Sulston, J. E., E. Schierenberg, J. White, and J. N. Thomson. 1983. Dev. Biol. 100:64-119). Each muscle type exhibits a unique combination of lineage and onset of differentiation at the cellular level. Biochemically characterized monoclonal antibodies to myosin heavy chains A, B, C, and D and to paramyosin have been used in immunochemical localization experiments. Paramyosin is detected by immunofluorescence in all muscle cells. Myosin heavy chains C and D are limited to the pharyngeal muscle cells, whereas myosin heavy chains A and B are localized not only within the sarcomeres of body wall muscle cells, as reported previously, but to the smooth muscle cells of the minor groups as well. Myosin heavy chains A and B and paramyosin proteins appear to be compatible with functionally and structurally distinct muscle cell types that arise by multiple developmental pathways.

The alteration of myosin isoform compartmentation in specific mutants of Caenorhabditis elegans.

Myosin isoforms A and B are located at the surface of the central and polar regions, respectively, of thick filaments in body muscle cells of Caenorhabditis elegans, whereas paramyosin and a distinct core structure comprise the backbones of these filaments. Thick filaments and related structures were isolated from nematode mutants that have altered thick filament protein compositions. These mutant filaments and their complexes with specific antibodies were studied by electron microscopy to determine the distribution of the two myosins. The compartmentation of the two myosin isoforms in body wall muscle thick filaments depends not only upon the intrinsic properties of the myosins but their interactions with other components such as paramyosin and their relative quantities determined by synthesis.

Myosin and paramyosin of Caenorhabditis elegans embryos assemble into nascent structures distinct from thick filaments and multi-filament assemblages.

The organization of myosin heavy chains (mhc) A and B and paramyosin (pm) which are the major proteins of thick filaments in adult wild-type Caenorhabditis elegans were studied during embryonic development. As a probe of myosin-paramyosin interaction, the unc-15 mutation e73 which produces a glu342lys charge change in pm and leads to the formation of large paracrystalline multi-filament assemblages was compared to wild type. These three proteins colocalized in wild-type embryos from 300 to 550 min of development after first cleavage at 20 degrees C on the basis of immunofluorescence microscopy using specific monoclonal antibodies. Linear structures which were diversely oriented around the muscle cell peripheries appeared at 360 min and became progressively more aligned parallel to the embryonic long axis until distinct myofibrils were formed at 550 min. In the mutant, mhc A and pm were colocalized in the linear structures, but became progressively separated until they showed no spatial overlap at the myofibril stage. These results indicate that the linear structures represent nascent assemblies containing myosin and pm in which the proteins interact differently than in wild-type thick filaments of myofibrils. In e73, these nascent structures were distinct from the multi-filament assemblages. The overlapping of actin and mhc A in the nascent linear structures suggests their possible structural and functional relationship to the "stress fiber-like structures" of cultured vertebrate muscle cells.

Thick filament substructures in Caenorhabditis elegans: evidence for two populations of paramyosin.

The thick filaments of the nematode Caenorhabditis elegans contain two myosin heavy chain isoforms A and B and paramyosin, the products of the myo-3, unc-54, and unc-15 genes, respectively. Dissociation of paramyosin from native thick filaments at pH 6.36 shows a biphasic function with respect to NaCl concentration. Electron microscopy of the remaining structures shows 15-nm core structures that label with monoclonal anti-paramyosin antibody at 72.5-nm intervals. Purified core structures also show 72.5 nm repeats by negative staining. Structural analysis of native thick filaments and dissociated structures suggests that the more dissociable paramyosin is removed radially as well as processively from the filament ends. Minor proteins with masses of 20, 28, and 30 kD cosediment stoichiometrically with paramyosin in purified core structures.

Purified thick filaments from the nematode Caenorhabditis elegans: evidence for multiple proteins associated with core structures.

The thick filaments of the nematode, Caenorhabditis elegans, arising predominantly from the body-wall muscles, contain two myosin isoforms and paramyosin as their major proteins. The two myosins are located in distinct regions of the surfaces, while paramyosin is located within the backbones of the filaments. Tubular structures constitute the cores of the polar regions, and electron-dense material is present in the cores of the central regions (Epstein, H.F., D.M. Miller, I. Ortiz, and G.C. Berliner. 1985. J. Cell Biol. 100:904-915). Biochemical, genetic, and immunological experiments indicate that the two myosins and paramyosin are not necessary core components (Epstein, H.F., I. Ortiz, and L.A. Traeger Mackinnon. 1986. J. Cell Biol. 103:985-993). The existence of the core structures suggests, therefore, that additional proteins may be associated with thick filaments in C. elegans. To biochemically detect minor associated proteins, a new procedure for the isolation of thick filaments of high purity and structural preservation has been developed. The final step, glycerol gradient centrifugation, yielded fractions that are contaminated by, at most, 1-2% with actin, tropomyosin, or ribosome-associated proteins on the basis of Coomassie Blue staining and electron microscopy. Silver staining and radioautography of gel electrophoretograms of unlabeled and 35S-labeled proteins, respectively, revealed at least 10 additional bands that cosedimented with thick filaments in glycerol gradients. Core structures prepared from wild-type thick filaments contained at least six of these thick filament-associated protein bands. The six proteins also cosedimented with thick filaments purified by gradient centrifugation from CB190 mutants lacking myosin heavy chain B and from CB1214 mutants lacking paramyosin. For these reasons, we propose that the six associated proteins are potential candidates for putative components of core structures in the thick filaments of body-wall muscles of C. elegans.

Unc-45 mutations in Caenorhabditis elegans implicate a CRO1/She4p-like domain in myosin assembly.

The Caenorhabditis elegans unc-45 locus has been proposed to encode a protein machine for myosin assembly. The UNC-45 protein is predicted to contain an NH2-terminal domain with three tetratricopeptide repeat motifs, a unique central region, and a COOH-terminal domain homologous to CRO1 and She4p. CRO1 and She4p are fungal proteins required for the segregation of other molecules in budding, endocytosis, and septation. Three mutations that lead to temperature-sensitive (ts) alleles have been localized to conserved residues within the CRO1/She4p-like domain, and two lethal alleles were found to result from stop codon mutations in the central region that would prevent translation of the COOH-terminal domain. Electron microscopy shows that thick filament accumulation in vivo is decreased by approximately 50% in the CB286 ts mutant grown at the restrictive temperature. The thick filaments that assemble have abnormal structure. Immunofluorescence and immunoelectron microscopy show that myosins A and B are scrambled, in contrast to their assembly into distinct regions at the permissive temperature and in wild type. This abnormal structure correlates with the high degree of instability of the filaments in vitro as reflected by their extremely low yields and shortened lengths upon isolation. These results implicate the UNC-45 CRO1/She4p-like region in the assembly of myosin isoforms in C. elegans and suggest a possible common mechanism for the function of this UCS (UNC-45/CRO1/She4p) protein family.

Myosin and paramyosin are organized about a newly identified core structure.

Myosin isoforms A and B are differentially localized to the central and polar regions, respectively, of thick filaments in body wall muscle cells of Caenorhabditis elegans (Miller, D. M. III, I. Ortiz, G. C. Berliner, and H. F. Epstein, 1983, Cell, 34:477-490). Biochemical and electron microscope studies of KCl-dissociated filaments show that the myosin isoforms occupy a surface domain, paramyosin constitutes an intermediate domain, and a newly identified core structure exists. The diameters of the thick filaments vary significantly from 33.4 nm centrally to 14.0 nm near the ends. The latter value is comparable to the 15.2 nm diameter of the core structures. The internal density of the filament core appears solid medially and hollow at the poles. The differentiation of thick filament structure into supramolecular domains possessing specific substructures of characteristic stabilities suggests a sequential mode for thick filament assembly. In this model, the two myosin isoforms have distinct roles in assembly. The behavior of the myosins, including nucleation of assembly and determination of filament length, depend upon paramyosin and the core structure as well as their intrinsic molecular properties.

beta-Filagenin, a newly identified protein coassembling with myosin and paramyosin in Caenorhabditis elegans.

Muscle thick filaments are stable assemblies of myosin and associated proteins whose dimensions are precisely regulated. The mechanisms underlying the stability and regulation of the assembly are not understood. As an approach to these problems, we have studied the core proteins that, together with paramyosin, form the core structure of the thick filament backbone in the nematode Caenorhabditis elegans. We obtained partial peptide sequences from one of the core proteins, beta-filagenin, and then identified a gene that encodes a novel protein of 201-amino acid residues from databases using these sequences. beta-Filagenin has a calculated isoelectric point at 10.61 and a high percentage of aromatic amino acids. Secondary structure algorithms predict that it consists of four beta-strands but no alpha-helices. Western blotting using an affinity-purified antibody showed that beta-filagenin was associated with the cores. beta-Filagenin was localized by immunofluorescence microscopy to the A bands of body-wall muscles, but not the pharynx. beta-filagenin assembled with the myosin homologue paramyosin into the tubular cores of wild-type nematodes at a periodicity matching the 72-nm repeats of paramyosin, as revealed by immunoelectron microscopy. In CB1214 mutants where paramyosin is absent, beta-filagenin assembled with myosin to form abnormal tubular filaments with a periodicity identical to wild type. These results verify that beta-filagenin is a core protein that coassembles with either myosin or paramyosin in C. elegans to form tubular filaments.

Molecular analysis of protein assembly in muscle development.

The challenge presented by myofibril assembly in striated muscle is to understand the molecular mechanisms by which its protein components are arranged at each level of organization. Recent advances in the genetics and cell biology of muscle development have shown that in vivo assembly of the myofilaments requires a complex array of structural and associated proteins and that organization of whole sarcomeres occurs initially at the cell membrane. These studies have been complemented by in vitro analyses of the renaturation, polymerization, and three-dimensional structure of the purified proteins.

Actin from the nematode, Caenorhabditis elegans, is a single electrofocusing species.

We have prepared actin from wild type Caenorhabditis elegans animals by three procedures: a purification dependent on the ability of actin to form F-actin, affinity chromatography which preferentially binds G-actin, and co-precipitation of an actin-myosin complex by antimyosin antibodies. Each preparation yields a single electrofucsing species of actin. Comparison of actin from C. elegans embryos and animals reveals that embryos also have the same single electrofocusing species of actin.

The moderately repetitive DNA sequences of Caenorhabditis elegans do not show short-period interspersion.

In these studies we show that the moderately repetitive DNA sequences of Caenorhabditis elegans are not arranged in the characteristic short-period interspersion pattern of most eukaryotes. Rather, the moderately repetitive sequences are arranged in long arrays as in Drosophila and Apis. These findings indicate that this type of arrangement is more phylogenetically diverse and hence less exceptional than previously believed.

Molecular cloning of a splice variant of Caenorhabditis elegans YNK1, a putative element in signal transduction.

YNK1 is a 98.3-kDa protein whose sequence was originally deduced from a genomic sequence in Caenorhabditis elegans. It was recently found that YNK1 is homologous to three different proteins implicated in signal transduction, suggesting that YNK1 is a signal transduction protein. In this report we describe the isolation of a full-length cDNA that encodes a splice variant of YNK1, designated YNK1a. We also present evidence that both YNK1 and YNK1a transcripts exist in vivo. Furthermore, using an antibody raised against a YNK1a recombinant protein, we demonstrate that the YNK1 protein is expressed in vivo throughout development.

STEM Analysis of Caenorhabditis elegans muscle thick filaments: evidence for microdifferentiated substructures.

In the thick filaments of body muscle in Caenorhabditis elegans, myosin A and myosin B isoforms and a subpopulation of paramyosin, a homologue of myosin heavy chain rods, are organized about a tubular core. As determined by scanning transmission electron microscopy, the thick filaments show a continuous decrease in mass-per-length (MPL) from their central zones to their polar regions. This is consistent with previously reported morphological studies and suggests that both their content and structural organization are microdifferentiated as a function of position. The cores are composed of a second distinct subpopulation of paramyosin in association with the alpha, beta, and gamma-filagenins. MPL measurements suggest that cores are formed from seven subfilaments containing four strands of paramyosin molecules, rather than the two originally proposed. The periodic locations of the filagenins within different regions and the presence of a central zone where myosin A is located, implies that the cores are also microdifferentiated with respect to molecular content and structure. This differentiation may result from a novel "induced strain" assembly mechanism based upon the interaction of the filagenins, paramyosin and myosin A. The cores may then serve as "differentiated templates" for the assembly of myosin B and paramyosin in the tapering, microdifferentiated polar regions of the thick filaments.

Genetic analysis of myosin assembly in Caenorhabditis elegans.

The established observations and unresolved questions in the assembly of myosin are outlined in this article. Much of the background information has been obtained in classical experiments using the myosin and thick filaments from vertebrate skeletal muscle. Current research is concerned with problems of myosin assembly and structure in smooth muscle, a broad spectrum of invertebrate muscles, and eukaryotic cells in general. Many of the general questions concerning myosin assembly have been addressed by a combination of genetic, molecular, and structural approaches in the nematode Caenorhabditis elegans. Detailed analysis of multiple myosin isoforms has been a prominent aspect of the nematode work. The molecular cloning and determination of the complete sequences of the genes encoding the four isoforms of myosin heavy chain and of the myosin-associated protein paramyosin have been a major landmark. The sequences have permitted a theoretical analysis of myosin rod structure and the interactions of myosin in thick filaments. The development of specific monoclonal antibodies to the individual myosins has led to the delineation of the different locations of the myosins and to their special roles in thick filament structure and assembly. In nematode body-wall muscles, two isoforms, myosins A and B, are located in different regions of each thick filament. Myosin A is located in the central biopolar zones, whereas myosin B is restricted to the flanking polar regions. This specific localization directly implies differential behavior of the two myosins during assembly. Genetic and structural experiments demonstrate that paramyosin and the levels of expression of the two forms are required for the differential assembly. Additional genetic experiments indicate that several other gene products are involved in the assembly of myosin. Structural studies of mutants have uncovered two new structures. A core structure separate from myosin and paramyosin appears to be an integral part of thick filaments. Multifilament assemblages exhibit multiple nascent thick filament-like structures extending from central paramyosin regions. Dominant mutants of myosin that disrupt thick filament assembly are located in the ATP and actin binding sites of the heavy chain. A model for a cycle of reactions in the assembly of myosin into thick filaments is presented. Specific reactions of the two myosin isoforms, paramyosin, and core proteins with multifilament assemblages as possible intermediates in assembly are proposed.

Rac-1 and Raf-1 kinases, components of distinct signaling pathways, activate myotonic dystrophy protein kinase.

Myotonic dystrophy protein kinase (DMPK) is a serine-threonine protein kinase encoded by the myotonic dystrophy (DM) locus on human chromosome 19q13.3. It is a close relative of other kinases that interact with members of the Rho family of small GTPases. We show here that the actin cytoskeleton-linked GTPase Rac-1 binds to DMPK, and coexpression of Rac-1 and DMPK activates its transphosphorylation activity in a GTP-sensitive manner. DMPK can also bind Raf-1 kinase, the Ras-activated molecule of the MAP kinase pathway. Purified Raf-1 kinase phosphorylates and activates DMPK. The interaction of DMPK with these distinct signals suggests that it may play a role as a nexus for cross-talk between their respective pathways and may partially explain the remarkable pleiotropy of DM.

Myotonic dystrophy protein kinase phosphorylates the myosin phosphatase targeting subunit and inhibits myosin phosphatase activity.

Myotonic dystrophy protein kinase (DMPK) and Rho-kinase are related. An important function of Rho-kinase is to phosphorylate the myosin-binding subunit of myosin phosphatase (MYPT1) and inhibit phosphatase activity. Experiments were carried out to determine if DMPK could function similarly. MYPT1 was phosphorylated by DMPK. The phosphorylation site(s) was in the C-terminal part of the molecule. DMPK was not inhibited by the Rho-kinase inhibitors, Y-27632 and HA-1077. Several approaches were taken to determine that a major site of phosphorylation was T654. Phosphorylation at T654 inhibited phosphatase activity. Thus both DMPK and Rho-kinase may regulate myosin II phosphorylation.

Developmental changes in expression of myotonic dystrophy protein kinase in the rat central nervous system.

Myotonic dystrophy protein kinase (DMPK) is the protein product of the genetic locus associated with myotonic dystrophy, in which alterations of muscle excitability, cardiac conduction defects, mental retardation, and cognitive deficiencies are inherited as an autosomal dominant trait. DMPK belongs to a novel protein serine/threonine kinase family, but its regulation and physiological functions have not been specified. In a first step toward understanding the functions of DMPK in the central nervous system, we have characterized its localization and developmental pattern of expression in rat brain and spinal cord by using a monospecific rabbit antiserum produced against bacterially expressed DMPK. Expression of DMPK begins after birth and increases gradually to peak at postnatal day 21 with antibody labeling of neuronal cell types in many regions. After postnatal day 21 and proceeding to the adult, the pattern of expression becomes more restricted, with localization to certain regions or cell groups in the central nervous system. Electron microscopy reveals localization within adult spinal motor neurons to the endoplasmic reticulum and dendritic microtubules. The adult localizations suggest that DMPK may function in membrane trafficking and secretion within neurons associated with cognition, memory, and motor control.

Phenotypic expression of the myotonic dystrophy gene in monozygotic twins.

Phenotypic expression of the myotonic dystrophy (DM) gene is highly variable even within the same family. To investigate the importance of genetic and nongenetic factors on phenotypic variability, we studied phenotypic expression in two DM twin sets with monozygosity confirmed by DNA polymorphism analysis. Our observations suggest that genetic factors are primarily responsible for modulating pleiotropic expression of the DM gene.

Anticipation in myotonic dystrophy. I. Statistical verification based on clinical and haplotype findings.

To determine whether anticipation in myotonic dystrophy (DM) is a true biologic phenomenon or an artifact of ascertainment bias, we studied 201 members of nine DM kindreds, including 67 individuals with the clinical diagnosis of DM. Of 49 parent-child pairs in which both the parents and the children were clinically affected, the onset of DM occurred in an earlier decade of life in the child than the parent in 44 pairs and in the same decade in five pairs (p < 0.001). To eliminate direct ascertainment bias, we excluded nine pairs involving the index patients. Indirect ascertainment bias due to incomplete penetrance was unlikely, since 55% of the children of DM parents had DM. However, by haplotype analysis of restriction fragment length polymorphisms, we diagnosed DM in one of the 42 asymptomatic children of affected parents and excluded DM in twenty-eight. We estimated that patients with early-onset DM would have produced an additional 25 DM children if they had normal fertility and nuptiality. Assuming that the expected age-of-onset distribution occurs without anticipation in these 25, only seven would have had the onset of DM earlier than their parents. With the corrected result, the child would have been affected earlier than the parent in 53 pairs, and the parent would have been affected at the same age as or earlier than the child in 13 pairs (p < 0.001). Thus, the observed anticipation is unlikely to be totally attributable to ascertainment bias, suggesting the potential importance of biologic mechanisms.

Anticipation in myotonic dystrophy. II. Complex relationships between clinical findings and structure of the GCT repeat.

We studied the expansion of the GCT repeats within the myotonic dystrophy protein kinase gene in nine myotonic dystrophy (DM) kindreds. Southern blot and polymerase chain reaction analyses of the repeat region demonstrated the expansion in all 62 patients with the diagnosis of DM. Among 43 DM parent-child pairs, age of onset in the child was earlier than in the parent in 36 pairs, in the same decade as the parent in five, and undetermined in two. The clinical anticipation observed in the 36 pairs accompanied an increase in the fragment size in 32, a decrease in two, and no apparent change in two pairs. In the remaining pairs without documented clinical anticipation, the fragment size increased in four, decreased in two, and was apparently unchanged in one. Overall, the size of expansion showed an inverse correlation with the age of onset (p < 0.001). In all seven pairs in which the fragment did not increase in size, the affected parent was male. Two congenital DM children born to affected mothers had expanded DNA greater than 4.5 kb. The differences between parent and child in age of onset significantly correlated with the differences in the expansion size among father-child pairs (p < 0.001) but not mother-child pairs (p > 0.5). Our data suggest that the expansion of the GCT repeats plays an important role in anticipation although other factors, including the sex of the affected parent, may have significant effects on molecular mechanisms of anticipation.