Purification and physical properties of nematode mini-titins and their relation to twitchin

The myofibrillar protein, projectin, is highly conserved across insect evolution except for its PEVK domain

All striated muscles respond to stretch by a delayed increase in tension. This physiological response, known as stretch activation, is, however, predominantly found in vertebrate cardiac muscle and insect asynchronous flight muscles. Stretch activation relies on an elastic third filament system composed of giant proteins known as titin in vertebrates or kettin and projectin in insects. The projectin insect protein functions jointly as a "scaffold and ruler" system during myofibril assembly and as an elastic protein during stretch activation. An evolutionary analysis of the projectin molecule could potentially provide insight into how distinct protein regions may have evolved in response to different evolutionary constraints. We mined candidate genes in representative insect species from Hemiptera to Diptera, from published and novel genome sequence data, and carried out a detailed molecular and phylogenetic analysis. The general domain organization of projectin is highly conserved, as are the protein sequences of its two repeated regions-the immunoglobulin type C and fibronectin type III domains. The conservation in structure and sequence is consistent with the proposed function of projectin as a scaffold and ruler. In contrast, the amino acid sequences of the elastic PEVK domains are noticeably divergent, although their length and overall unusual amino acid makeup are conserved. These patterns suggest that the PEVK region working as an unstructured domain can still maintain its dynamic, and even its three-dimensional, properties, without the need for strict amino acid conservation. Phylogenetic analysis of the projectin proteins also supports a reclassification of the Hymenoptera in relation to Diptera and Coleoptera.

Invertebrate Muscles: Muscle Specific Genes and Proteins

This is the first of a projected series of canonic reviews covering all invertebrate muscle literature prior to 2005 and covers muscle genes and proteins except those involved in excitation-contraction coupling (e.g., the ryanodine receptor) and those forming ligand- and voltage-dependent channels. Two themes are of primary importance. The first is the evolutionary antiquity of muscle proteins. Actin, myosin, and tropomyosin (at least, the presence of other muscle proteins in these organisms has not been examined) exist in muscle-like cells in Radiata, and almost all muscle proteins are present across Bilateria, implying that the first Bilaterian had a complete, or near-complete, complement of present-day muscle proteins. The second is the extraordinary diversity of protein isoforms and genetic mechanisms for producing them. This rich diversity suggests that studying invertebrate muscle proteins and genes can be usefully applied to resolve phylogenetic relationships and to understand protein assembly coevolution. Fully achieving these goals, however, will require examination of a much broader range of species than has been heretofore performed.

Titin: properties and family relationships

In striated muscles, the rapid production of macroscopic levels of force and displacement stems directly from highly ordered and hierarchical protein organization, with the sarcomere as the elemental contractile unit. There is now a wealth of evidence indicating that the giant elastic protein titin has important roles in controlling the structure and extensibility of vertebrate muscle sarcomeres.

The limits of promiscuity: isoform-specific dimerization of filamins

Filamins are a family of actin cross-linking proteins that are primarily localized in the cortical cytoplasm of all mammalian cells. Until now, three major isoforms (filamins a, b, and c) have been identified, that were shown to be differentially expressed and/or localized in different tissues. An amino-terminal double CH-domain actin binding domain, and a dimerization region in the carboxy-terminal portion of the protein are the molecular basis for its actin cross-linking activity. Chemical cross-linking of bacterially expressed recombinant proteins was used to demonstrate that in all three filamin isoforms the most carboxy-terminally situated immunoglobulinlike domain is required and sufficient for dimerization. The efficiency of the dimerization was increased upon inclusion of the preceding hinge 2 region, indicating a function for this region in the regulation of dimerization. By mixing recombinant proteins derived from different filamin isoforms, we found that heterodimer formation is possible between filamins b and c but not between filamin a and the other two filamins. This selectivity of dimerization might provide a further molecular explanation for the differential intracellular sorting of filamin isoforms and their distinct properties.

Smitin, a novel smooth muscle titin-like protein, interacts with myosin filaments in vivo and in vitro

Smooth muscle cells use an actin-myosin II-based contractile apparatus to produce force for a variety of physiological functions, including blood pressure regulation and gut peristalsis. The organization of the smooth muscle contractile apparatus resembles that of striated skeletal and cardiac muscle, but remains much more poorly understood. We have found that avian vascular and visceral smooth muscles contain a novel, megadalton protein, smitin, that is similar to striated muscle titin in molecular morphology, localization in a contractile apparatus, and ability to interact with myosin filaments. Smitin, like titin, is a long fibrous molecule with a globular domain on one end. Specific reactivities of an anti-smitin polyclonal antibody and an anti-titin monoclonal antibody suggest that smitin and titin are distinct proteins rather than differentially spliced isoforms encoded by the same gene. Smitin immunofluorescently colocalizes with myosin in chicken gizzard smooth muscle, and interacts with two configurations of smooth muscle myosin filaments in vitro. In physiological ionic strength conditions, smitin and smooth muscle myosin coassemble into irregular aggregates containing large sidepolar myosin filaments. In low ionic strength conditions, smitin and smooth muscle myosin form highly ordered structures containing linear and polygonal end-to-end and side-by-side arrays of small bipolar myosin filaments. We have used immunogold localization and sucrose density gradient cosedimentation analyses to confirm association of smitin with both the sidepolar and bipolar smooth muscle myosin filaments. These findings suggest that the titin-like protein smitin may play a central role in organizing myosin filaments in the contractile apparatus and perhaps in other structures in smooth muscle cells.

Immunohistochemical study and western blotting analysis of titin-like proteins in the striated muscle of Drosophila melanogaster and in the striated and smooth muscle of the oligochaete Eisenia foetida

The presence and distribution of titin-like proteins have been examined in transversely striated muscle of Drosophila melanogaster, in obliquely striated muscles (body wall and inner muscular layer of the pseudoheart) and smooth muscle (outer muscular layer of the pseudoheart) from the earthworm Eisenia foetida by means of Western blotting analysis, light microscopy immunohistochemistry, and electron microscopy immunogold labeling, using antibodies anti vertebrate (chicken) titin (3,000 kDa) and arthropod (D. melanogaster) mini-titin (twitchin or projectin) (700 kDa). To determine whether these antibodies immunoreact non-specifically against vertebrate titin, mouse skeletal muscle was also studied. As negative control, mouse smooth muscle was used. Immunoreaction to mini-titin was found in all the invertebrate muscles studied. For each of these muscles, Western blotting analysis of mini-titin showed a single band, at approximately 700 kDa. Electron microscopy immunolabeling to this protein was observed along the whole sarcomere length (A bands and I bands) in both transversely striated muscles of the insect and obliquely striated muscles of the earthworm, although the number of immunogold particles was more abundant in the insect muscles. Mini-titin immunolabeling was also observed in the smooth muscle cells that formed the outer layer of the earthworm pseudoheart although in lower amounts than in the obliquely striated muscle. The absence of true sarcomeres in the smooth muscle cells did not permit to determine the extension of mini-titin immunolabeling. No immunoreaction to this protein was found in the striated and smooth muscles of the mouse. Immunoreaction to titin was only observed in the mouse skeletal muscle, in which both A bands and I bands appeared immunolabeled. Present results show that mini-titin in the invertebrate muscles studied differs immunohistochemically from vertebrate titin and, in contrast with titin, mini-titin is also present in invertebrate smooth muscles.

Calcium-dependent inhibition of in vitro thin-filament motility by native titin

Titin ( also known as connectin) is a giant filamentous protein that spans the distance between the Z- and M-lines of the vertebrate muscle sarcomere and plays a fundamental role in the generation of passive tension. Titin has been shown to bind strongly to myosin, making it tightly associated to the thick filament in the sarcomere. Recent observations have suggested the possibility that titin also interacts with actin, implying further functions of titin in muscle contraction. We show -- using in vitro motility and binding assays -- that native titin interacts with both filamentous actin and reconstituted thin filaments. The interaction results in the inhibition of the filaments' in vitro motility. Furthermore, the titin-thin filament interaction occurs in a calcium-dependent manner: increased calcium results in enhanced binding of thin filaments to titin and greater suppression of in vitro motility.

Purification and biochemical characterization of myomesin, a myosin-binding and titin-binding protein, from bovine skeletal muscle

We report a method for isolating homogeneous myomesin from mammalian skeletal muscle. The identity of the purified bovine protein was confirmed by its reactivity with myomesin-specific monoclonal antibodies and with polyclonal antibodies raised against peptides derived from the amino-terminal and carboxy-terminal ends of the sequence predicted by the human myomesin cDNA. All partial sequences obtained from bovine myomesin can be aligned along the human sequence predicted by its cloned cDNA. Electron microscopy of myomesin revealed short flexible rods with a molecular length of about 50 nm. Circular dichroism spectra showed a high degree of beta structure as expected for a member of the immunoglobulin superfamily of proteins. Alignment of the sequences of the class I and II domains of myomesin with the sequences of domains of known three-dimensional structure provides a more detailed model of myomesin. In agreement with this view, the cleavage sites observed by limited proteolysis locate primarily between individual domains. In a solid-phase overlay assay myomesin specifically bound to the myosin rod and to light meromyosin (LMM), but not to the carboxy-terminal 30-kDa fragment of LMM. The myosin-binding site seemed to be confined to the amino-terminal 240 residues of the molecule. The cross-reactivity of myomesin with the phosphorylation-dependent monoclonal neurofilament antibody NE14 [Shaw, G.E., Debus, E. & Weber, K. (1984) Eur. J. Cell Biol. 34, 130-136] was analyzed. NE14 reactivity of myomesin was abolished by alkaline phosphatase. Reactivity of the antibody on stable proteolytic fragments of myomesin showed that the phosphorylation site must reside within the carboxy-terminal 60 residues.

Characterization of connectin-like proteins of obliquely striated muscle of a polychaete (Annelida)

In obliquely striated muscle of polychaete, Neanthes sp., three kinds of connectin (titin)-like high molecular weight proteins, approximately 4000 kDa, approximately 1200 kDa and approximately 700 kDa, were detected by SDS gel electrophoresis and immunoblots using antibodies to vertebrate skeletal muscle connectin and antiserum to the protein in question. The 700 kDa protein was isolated and characterized as a beta sheet-rich filament 170 nm long and 4 nm wide. Using polyclonal antibodies to the 700 kDa protein, the binding of the immunogold to the thick filament was only demonstrated in high ionic strength relaxing solution which solubilized some myosin. This observation suggested that the 700 kDa protein was localized below the layers of myosin in the thick filament and this localization is different from that of twitchin of C elegans bodywall muscle that is on the surface of thick filament. The 4000 kDa protein was identified as a very thin filament linking the thick filament to the dense body. The very thin filaments were visualized in gelsolin-treated actin filament-free fibres. The 1200 kDa protein was located in the periphery of the dense body. A model of the elastic filament in polychaete bodywall muscle is presented.

Titin-related proteins in invertebrate muscles

The localization of filaments connecting the Z-line and the A-band in insect flight muscles and the identification of very large proteins as their components is reviewed. The characterization of twitchin in the obliquely striated muscles of Caenorhabditis elegans is reported and the deductions made from its amino acid sequence are considered. The characterization of mini-titins in obliquely striated molluscan muscles is compared. The identification of projectin in the muscles of Drosophila melanogaster by anti-twitchin-antibodies, its sequence analysis and the characterization of mini-titins in arthropod and mollusc fast-striated muscles are summarized. The possible biological functions of the different proteins in various invertebrate muscles are discussed.

Connectin, an elastic protein of striated muscle

Connectin, also called titin, a giant elastic protein of striated muscle (approximately 3000 kDa) mainly consists of fibronectin type III and immunoglobulin C2 globular domains, the beta-sheets of which are parallel to the main axis of the molecule. One connectin molecule runs through the I band and binds onto the myosin filament up to the M line starting from the Z line. It positions the myosin filament at the center of a sarcomere. Connectin is also responsible for resting tension generation. Biodiversity of the connectin family exists in invertebrate muscle.

Mini-titins in striated and smooth molluscan muscles: structure, location and immunological crossreactivity

Invertebrate mini-titins are members of a class of myosin-binding proteins belonging to the immunoglobulin superfamily that may have structural and/or regulatory properties. We have isolated mini-titins from three molluscan sources: the striated and smooth adductor muscles of the scallop, and the smooth catch muscles of the mussel. Electron microscopy reveals flexible rod-like molecules about 0.2 micron long and 30 A wide with a distinctive polarity. Antibodies to scallop mini-titin label the A-band and especially the A/I junction of scallop striated muscle myofibrils by indirect immunofluorescence and immuno-electron microscopy. This antibody crossreacts with mini-titins in scallop smooth and Mytilus catch muscles, as well as with proteins in striated muscles from Limulus, Lethocerus (asynchronous flight muscle), and crayfish. It labels the A/I junction (I-region in Lethocerus) in these striated muscles as well as in chicken skeletal muscle. Antibodies to the repetitive immunoglobulin-like regions and also to the kinase domain of nematode twitchin crossreact with scallop mini-titin and label the A-band of scallop myofibrils. Electron microscopy of single molecules shows that antibodies to twitchin kinase bind to scallop mini-titin near one end of the molecule, suggesting how the scallop structure might be aligned with the sequence of nematode twitchin.

The globular head domain of titin extends into the center of the sarcomeric M band. cDNA cloning, epitope mapping and immunoelectron microscopy of two titin-associated proteins

Immunoelectron microscopical results have shown that the Z and M bands of the sarcomere are interconnected by the long titin molecules. Here we have characterized by monoclonal antibodies, cDNA cloning and immunoelectron microscopy the two titin-associated proteins (190 and 165 kDa proteins), which seem responsible for the formation of a head structure on one end of the 0.9 micron long titin string. The human 165 kDa (1465 residues) and 190 kDa (1451 residues) proteins have unique N-terminal domains some 110 residues in length. Both proteins show 12 repeat domains with strong homology to either fibronectin type III (motif I) or immunoglobulin C2 (motif II) domains, which are arranged in the order II-II-I-I-I-I-I-II-II-II-II-II. Over these repeat domains the two proteins share 50% sequence identity (70% similarity). Epitopes situated in the C-terminal 138 or in the preceding 206 residues of the 165 kDa protein locate in immunoelectron microscopy to stripes situated 18 or 15 nm from the center of the M band. An epitope situated 277 to 129 residues prior to the C-terminus of the 190 kDa protein (i.e. repeats 10 and 11) locates to the center of the M band. Thus the head structure of the titin molecule extends into the center of the M band. Microsequence data on peptides from the titin-associated bovine 165 kDa protein and from conventionally purified bovine M-protein argue together with the reactivity of the antibodies that 165 kDa protein and M-protein are identical. The integrating structure of the sarcomere, which is based on titin and its side-on (C-protein and 86 kDa protein) or end-on (190 kDa protein and 165 kDa protein) associated proteins arises from muscle-specific members of the superfamily of immunoglobulin-like proteins.

Complete sequence of human fast-type and slow-type muscle myosin-binding-protein C (MyBP-C). Differential expression, conserved domain structure and chromosome assignment

Myosin-binding-protein C (MyBP-C) is a myosin-associated protein of unknown function found in the cross-bridge-bearing zone (C region) of A bands in striated muscle. Using a cDNA clone encoding the fast-type isoform of chicken MyBP-C, we screened a human fetal muscle cDNA library and isolated clones encoding the full-length human fast-type isoform of MyBP-C. cDNA clones encoding the slow-type isoform of human MyBP-C, were also isolated and fully sequenced. Northern-blot analysis demonstrated skeletal muscle-specific expression of these gene products. Using human/hamster somatic-cell hybrids, we were able to map the slow-type MyBP-C to human chromosome 12, and the fast-type MyBP-C to chromosome 19. The cDNA for human fast-type MyBP-C encodes a polypeptide of 1142 amino acids with an expected molecular mass of 128.1 kDa. Comparison of this cDNA with other members of the MyBP family reveals extensive primary-sequence conservation. Each MyBP-C contains seven immunoglobulin C2 motifs and three fibronectin type-III repeats in the arrangement C2-C2-C2-C2-C2-III-III-C2-III-C2. Regions of high identity shared by the chicken and the two human proteins are not restricted to the immunoglobulin and fibronectin motifs. Sequence comparison of all three proteins has allowed us to map a highly conserved region between the first and second C2 motifs, the only large spacer sequence present between motifs in these proteins.

Gel electrophoresis of giant proteins: solubilization and silver-staining of titin and nebulin from single muscle fiber segments

Giant proteins in the megadalton range (> 0.5 MDa) appear to play important structural and functional roles in striated muscle. Titin (approximately 3 MDa) is involved in the generation of resting tension and the assembly and stability of the sarcomere in skeletal and cardiac muscle tissues, while nebulin (approximately 0.7 MDa) is thought to regulate thin filament length in skeletal muscle. Sodium dodecyl sulfate (SDS)-gel electrophoresis is an important tool in revealing the size, quantity and integrity of these giant proteins in muscle tissues. We report here a method for solubilizing, detecting and quantifying titin and nebulin from short segments of single fibers of the rabbit psoas muscle. Muscle proteins ranging from 15 kDa to 3 MDa were resolved on 3.3-12% gradient polyacrylamide gels that were silver-stained and quantitated by densitometry. Presoaking fiber segments in a low ionic strength pH 8.4 buffer enhances the amount of solubilized titin and nebulin. Solubilizing the presoaked fiber segments with SDS at 60 degrees C for 60 s maximizes the amount of intact titin; solubilizing at higher temperatures causes extensive degradation of titin. Detection sensitivity is sufficient to study titin and nebulin in fiber segments as short as 120 microns.

A survey of interactions made by the giant protein titin

A simple solid-phase binding assay was used to screen for interactions that the giant myofibrillar protein titin makes with other sarcomeric proteins. The titin used in the tests was purified by a modified procedure that results in isolation of approximately 20 mg relatively undegraded protein in < 24 h. In addition to the approximately 3 MDa polypeptide, bands at approximately 160 kDa and approximately 100 kDa were also consistently seen on gels. Binding of titin to myosin, C-protein, X-protein and AMP-deaminase was observed. The interaction with myosin appears to be with the light meromyosin part of the molecule.

Towards a molecular understanding of titin

Titin is at present the largest known protein (M(r) 3000 kDa) and its expression is restricted to vertebrate striated muscle. Single molecules span from M- to Z-lines and therefore over 1 micron. We have isolated cDNAs encoding five distant titin A-band epitopes, extended their sequences and determined 30 kb (1000 kDa) of the primary structure of titin. Sequences near the M-line encode a kinase domain and are closely related to the C-terminus of twitchin from Caenorhabditis elegans. This suggests that the function of this region in the titin/twitchin family is conserved throughout the animal kingdom. All other A-band sequences consist of 100 amino acid (aa) repeats predicting immunoglobulin-C2 and fibronectin type III globular domains. These domains are arranged into highly ordered 11 domain super-repeat patterns likely to match the myosin helix repeat in the thick filament. Expressed titin fragments bind to the LMM part of myosin and C-protein. Binding strength increases with the number of domains involved, indicating a cumulative effect of multiple binding sites for myosin along the titin molecule. We conclude that A-band titin is likely to be involved in the ordered assembly of the vertebrate thick filament.

Autophosphorylating protein kinase activity in titin-like arthropod projectin

The function of the high molecular weight structural proteins from muscle, namely vertebrate titin, arthropod projectin and nematode twitchin, remains to be established. Using a simple method for the purification of projectin from crayfish and Drosophila melanogaster, a polyclonal antibody has been raised against crayfish projectin, and shown to immunocrossreact with Drosophila projectin but not with rat titin. In this study, evidence is presented that projectin and twitchin may share functional protein kinase domains, indicating a possible relationship between them. Projectin has a serine/threonine protein kinase activity. This supports the relationship with twitchin since, in sequence analysis of the latter, a protein-kinase-like domain has been found. Moreover, projectin is capable of autophosphorylation in vitro. These kinase activities imply regulatory functions for this group of proteins, extending its previously assumed structural role in the sarcomere. We also show here that projectin is phosphorylated in vivo at serine residues, as described for titin.