Interaction of myosin and paramyosin

The interaction of myosin and paramyosin was investigated by enzymological and ultrastructural techniques. The actin-activated Mg⁺² ATPase of rabbit skeletal muscle myosin can be inhibited by clam adductor paramyosin. Both proteins must be rapidly coprecipitated to form filaments for this inhibition. Slowly formed cofilaments are fully activatable by F-actin. In both cases, the cofilaments possess unique structural characteristics when compared to homofilaments. The mode of inhibition appears to be competitive when different concentrations of paramyosin and F-actin are compared. The apparent affinity of the myosin heads for actin is reduced by the presence of paramyosin within rapidly reconstituted thick filaments. These results suggest that paramyosin may serve as part of a relaxing mechanism within invertebrate muscles. It is unlikely that paramyosin plays a role in the initiation and maintenance of catch within specialized molluscan muscles.     

Phosphorylation of paramyosin

1. Myofibrils isolated from Mercenaria mercenaria were phosphorylated by endogenous kinase. Over a range of ionic strengths only paramyosin was phosphorylated. 2. Thiophosphorylation of paramyosin caused an inhibition of steady-state actin-activated ATPase activity of the myofibrils. 3. It is proposed that the endogenous kinase is the catalytic subunit of the cAMP-dependent protein kinase. 4. The sequence around the phosphorylation site was determined. 5. The phosphorylation site probably is close to the C-terminus of the paramyosin molecule.     

5-HT induced accumulation of 3',5'-AMP and the phosphorylation of paramyosin in the ABRM of Mytilus edulis.

In Mytilus edulis 5-Ht induced relaxation of a muscle in catch is preceded by an increase in 3',5'-AMP content. In vitro two proteins of the contractile apparatus are phosphorylated by 3',5'-AMP dependent protein kinases. The 295000 dalton protein cannot be identified, the other one is paramyosin. Phosphorylated paramyosin inhibits actomyosin ATPase of smooth mollusc muscles at low and high Ca++ concentrations.     

Mutants affecting paramyosin in Caenorhabditis elegans

Four mutants of Caenorhabditis elegans with abnormal muscle structure are described which are alleles of a single locus unc-15. In one of the mutants, E1214, paramyosin is completely absent from both body-wall and pharyngeal musculature. In the other three mutants paramyosin is present but does not assemble into thick filaments. Instead paramyosin paracrystals are formed in the body-wall muscle cells. Myosin filaments lacking paramyosin cores are present in all four mutants, but these filaments fail to integrate stably into the myofilament lattice. One mutant is temperature-sensitive; all four are semi-dominant in their effect on muscle structure. The hypothesis that unc-15 is the structural gene for paramyosin is discussed.     

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.     

Update on paramyosin in parasitic worms

Paramyosin was first identified as a structural component of invertebrate muscle. Analysis of crude, native, adult schistosome worm preparations identified a highly immunogenic protein which was later identified as paramyosin. Early vaccination/challenge studies with native paramyosin produced encouraging levels of protective efficacy against schistosomes, which led to the question as to how a sub-tegumental (muscular) protein could provide a target for vaccine-mediated immunological attack. Immunolocalisation studies of schistosomes confirmed the presence of paramyosin within the post-acetabular glands of cercariae and on the tegumental surface of lung schistosomula. Here we present an update on the more recent research on paramyosin in parasitic worms that has focused primarily in two directions: (i) further testing of the vaccine potency of paramyosin against schistosomes and other parasitic worms; and (ii) characterisation of the protein at the molecular and biochemical levels.     

Subunit structure of oyster paramyosin

Paramyosin from the oyster Crassostrea commercialis was studied by equilibrium sedimentation. In non-denaturing solvents the minimum molecular weight is 208000. Dissociation into subunits requires complete disruption of the alpha-helix. This occurs at pH7 in guanidine hydrochloride solutions of concentration greater than 7m in the presence of a disulphide-bond-reducing agent. Solutions of the protein in concentrated guanidine hydrochloride are polydisperse and contain species of low molecular weight (approx. 25000) comprising approx. 5% to 10% of the protein. The molecular weight of the main component is estimated to be 97000 and the paramyosin molecule contains two of these subunits. From the present observations no decision can be made as to whether or not the small component (or components) represents part of the paramyosin molecule. Preferential binding of guanidine hydrochloride to the extent of 0.13g./g. of protein was shown in solutions of paramyosin in 7.85m-guanidine hydrochloride.     

Drosophila paramyosin is important for myoblast fusion and essential for myofibril formation

Paramyosin is a major structural protein of thick filaments in invertebrate muscles. Coiled-coil dimers of paramyosin form a paracrystalline core of these filaments, and the motor protein myosin is arranged on the core surface. To investigate the function of paramyosin in myofibril assembly and muscle contraction, we functionally disrupted the Drosophila melanogaster paramyosin gene by mobilizing a P element located in its promoter region. Homozygous paramyosin mutants die at the late embryo stage. Mutants display defects in both myoblast fusion and in myofibril assembly in embryonic body wall muscles. Mutant embryos have an abnormal body wall muscle fiber pattern arising from defects in myoblast fusion. In addition, sarcomeric units do not assemble properly and muscle contractility is impaired. We confirmed that these defects are paramyosin-specific by rescuing the homozygous paramyosin mutant to adulthood with a paramyosin transgene. Antibody analysis of normal embryos demonstrated that paramyosin accumulates as a cytoplasmic protein in early embryo development before assembling into thick filaments. We conclude that paramyosin plays an unexpected role in myoblast fusion and is important for myofibril assembly and muscle contraction.     

Some physical properties of paramyosin from earthworms

Paramyosin was prepared from earthworms (Lumbricus terrestris) by two different methods that have been used in the past. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate shows that the older method yields slightly degraded material (mostly β- and γ-paramyosin) while the newer method yields essentially intact, i.e., α-, paramyosin. Physical studies, particularly circular dichroism, light scattering, and sedimentation velocity show that the native molecule is a double α-helical coiled coil of molecular weight 200,000, length 1200 Å, and diameter 20 Å. These properties are the same as reported previously for molluscan paramyosin. Also like clam paramyosin, the worm protein molecule loses its helix content and dissociates into its two constituent polypeptide chains upon exposure to sufficient concentration of Gdn-HCl. Furthermore, the same partially denatured states can be reached from either native or completely denatured proteins, indicating that they are all equilibrium states. However, the Gdn · HCl-induced denaturation profile for the worm paramyosin is quite different from the clam. The helix content of worm paramyosin diminishes monophasically with increasing concentration of Gdn-HCl, showing that the molecule does not possess a region of special stability such as its clam analog boasts. This conclusion is supported by experiments on papain digestion of worm paramyosin, wherein no resistent core is seen.     

Identification and characterization of Drosophila melanogaster paramyosin

Paramyosin, a major structural component of thick filaments in invertebrates has been isolated, purified and characterized from whole adult Drosophila melanogaster extracts and a specific polyclonal antibody against it has been prepared. Paramyosin has been identified on the basis of several criteria, including molecular weight, alpha-helicity, species distribution, capability of fiber formation in vitro and sequence. We have used the immunopurified polyclonal antibody to isolate eight clones from a lambda gt11 expression library of Drosophila 1 to 22 h embryo cDNA. The largest clone (pJV9) has been sequenced and encodes the coiled-coil region of D. melanogaster paramyosin that is 47% identical to Caenorhabditis elegans paramyosin. Indirect immunofluorescence in semi-thin sections of adult flies show fluorescence mainly in tubular muscle. Freshly prepared tubular myofibrils decorated with the immunoabsorbed antibody show the A region in the sarcomere as the specific localization of paramyosin. The amount of paramyosin in tubular synchronous muscles of insects appears to be five times higher than in fibrillar insect muscles. There are at least three paramyosin isoforms as shown by isoelectrofocusing separation. The more acidic and less abundant form is phosphorylated as shown by 32P in vivo labeling experiments in adult flies. The developmental pattern of expression of Drosophila paramyosin is presented. This mesoderm-specific protein, immunologically undetectable during gastrulation and early phases of germ band formation, progressively increases during organogenesis to the adult stage. Interestingly, it is also expressed as a major maternal product in the insoluble cytoskeletal fraction of the mature oocyte.     

Structure and paramyosin content of tarantula thick filaments

Muscle fibers of the tarantula femur exhibit structural and biochemical characteristics similar to those of other long-sarcomere invertebrate muscles, having long A-bands and long thick filaments. 9-12 thin filaments surround each thick filament. Tarantula muscle has a paramyosin:myosin heavy chain molecular ratio of 0.31 +/- 0.079 SD. We studied the myosin cross-bridge arrangement on the surface of tarantula thick filaments on isolated, negatively stained, and unidirectionally metal-shadowed specimens by electron microscopy and optical diffraction and filtering and found it to be similar to that previously described for the thick filaments of muscle of the closely related chelicerate arthropod, Limulus. Cross-bridges are disposed in a four-stranded right-handed helical arrangement, with 14.5-nm axial spacing between successive levels of four bridges, and a helical repeat period every 43.5 nm. The orientation of cross-bridges on the surface of tarantula filaments is also likely to be very similar to that on Limulus filaments as suggested by the similarity between filtered images of the two types of filaments and the radial distance of the centers of mass of the cross-bridges from the surfaces of both types of filaments. Tarantula filaments, however, have smaller diameters than Limulus filaments, contain less paramyosin, and display structure that probably reflects the organization of the filament backbone which is not as apparent in images of Limulus filaments. We suggest that the similarities between Limulus and tarantula thick filaments may be governed, in part, by the close evolutionary relationship of the two species.     

The paramyosin of insect flight muscle

Paramyosin has been extracted and purified from the flight muscle of the insects Lethocerus cordofanus, Lethocerus maximus (water bugs), Heliocopris japetus (dung beetle) and Pachnoda ephippiata (rosechafer beetle). The subunit molecular weight, estimated by sodium dodecyl sulphate electrophoresis, is 107,000 ± 6000. The intrinsic sedimentation constant is 3.17 S and circular dichroism measurements give about 87 % helix, showing that the molecule is likely to be a two-chain rod.The amino acid composition of insect paramyosins resembles that of molluscan and annelid paramyosins except that the Glu/Asp ratio is higher. The amino acid analysis of insect tropomyosin is also given. Electron microscopy of tactoids shows an axial periodicity of 732 ± 8 Å or 146 Å with fine structure differing from that of molluscan tactoids.The proportion of paramyosin in the myofibrils, estimated by densitometry of stained gels, is 6.3% in L. cordofanus and 9.5% in rosechafer, and the ratio of myosin to paramyosin in L. cordofanus is 8.2. The possibility that paramyosin is a core protein of the myosin filaments is discussed.     

B cell responses to paramyosin. Isotypic analysis and epitope mapping of filarial paramyosin in patients with onchocerciasis.

To examine the fine specificity of the human immune response to filarial paramyosin, the antigenicity of an expressed rcDNA (2.55 kb) of Dirofilaria immitis paramyosin was detailed by ELISA. Using sera from patients infected with Onchocerca volvulus, we analyzed both the entire paramyosin molecule and six subcloned fragments for their IgG, IgG subclasses, and IgE responses. Patients from both Guatemala (64% positive) and Ghana (100% positive) reacted to paramyosin with specific IgG levels above normal controls. Although there was no anti-paramyosin subclass restriction common to all patients, the IgG3 response in the Ghananians was significantly greater than that of Guatemalans (p less than 0.001). IgE anti-paramyosin responses showed positive correlations with IgG2 (p less than 0.001), IgG4 (p less than 0.002), and IgG1 (p less than 0.04) responses. Epitope mapping using the IgG response to the six subclones demonstrated preferential recognition of the amino terminal end of the molecule (nucleotides 1 to 360). IgG2 reactivity was clearly localized to the most amino-terminal 120 amino acids, and the IgG4 antibodies recognized amino acids immediately adjacent to this fragment. These studies examining the fine specificity of anti-filarial immune reactions should provide a method for understanding how parasites either evade or induce host immune responses.     

The paramyosin function in glycerinated muscle fibers during blocking with antibodies of its contacts with structural proteins

Antibodies to paramyosin (APM) induce a partial decrease of the isometric tension in glycerinated fibres of the Anodonta cygnea catch muscle in the presence of ATP and Ca2+; the myofibrillar Mg2+ ATPase increases concomitantly. Assumedly paramyosin inhibits the cross-bridges unlocking, retaining them mechanically in a locked state. The fibres of barnacle giant muscle in an ATP deficient solution respond to APM by transient isometric tension development. A model for the participation of paramyosin in the contractile process is proposed. In both muscle types paramyosin hinders the functioning of certain elements of the contractile machinery.     

Inhibitory effect of squid (Todarodes pacificus) paramyosin on actomyosin ATPase and on superprecipitation

1. Paramyosin from squid mantle muscle inhibited the Mg-ATPase and the superprecipitation activities of actomyosin. 2. The inhibition was detected only when paramyosin forms a cofilament with myosin. 3. ATP-induced changes in the morphology of the cofilament of myosin and paramyosin are involved in the inhibition by paramyosin.     

Isolation of Aulacomya paramyosin

Tropomyosin A or paramyosin has been isolated from the adductor muscle of Aulacomya magellanica. It has in common with other tropomyosins A the method used for extracting it from adductor muscle, its solubility, facility of crystallization, ammonium sulphate range of precipitation, amino acid composition and behaviour when digested with trypsin. As a particular feature it exhibits an unusual low viscosity for this type of tropomyosin. Its molecular weight, determined by the Archibald approach-to-sedimentation-equilibrium method, is 258000+/-16000.     

UNC-98 and UNC-96 interact with paramyosin to promote its incorporation into thick filaments of Caenorhabditis elegans

Mutations in unc-96 or -98 cause reduced motility and a characteristic defect in muscle structure: by polarized light microscopy birefringent needles are found at the ends of muscle cells. Anti-paramyosin stains the needles in unc-96 and -98 mutant muscle. However there is no difference in the overall level of paramyosin in wild-type, unc-96, and -98 animals. Anti-UNC-98 and anti-paramyosin colocalize in the paramyosin accumulations of missense alleles of unc-15 (encodes paramyosin). Anti-UNC-96 and anti-UNC-98 have diffuse localization within muscles of unc-15 null mutants. By immunoblot, in the absence of paramyosin, UNC-98 is diminished, whereas in paramyosin missense mutants, UNC-98 is increased. unc-98 and -15 or unc-96 and -15 interact genetically either as double heterozygotes or as double homozygotes. By yeast two-hybrid assay and ELISAs using purified proteins, UNC-98 interacts with paramyosin residues 31-693, whereas UNC-96 interacts with a separate region of paramyosin, residues 699-798. The importance of surface charge of this 99 residue region for UNC-96 binding was shown. Paramyosin lacking the C-terminal UNC-96 binding region fails to localize throughout A-bands. We propose a model in which UNC-98 and -96 may act as chaperones to promote the incorporation of paramyosin into thick filaments.     

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.