The Two Myosin Isoenzymes of Chicken Anterior Latissimus dorsi Muscle Contain Different Myosin Heavy Chains Encoded by Separate mRNAs

Abstract. The two myosin isozymes (SM1 and SM2) of the anterior latissimus dorsi muscle of the chicken change in relative concentration during development. As SM1 decreases from 13 days of embryonic growth through 1 year of adult maturation, SM2 increases. In the adult muscle SM2 accounts for over 95% of the total myosin. The myosin heavy chains of the two isozymes are distinctly different and may be separated from each other by 5% SDS polyacrylamide gel electrophoresis. The faster migrating myosin heavy chain is identified as originating from SM1 and the slower migrating myosin heavy chain from SM2 myosin isozymes. The myosin heavy chains change in relative concentration during development exactly parallel with changes in SM1 and SM2 isozyme levels. Peptide map analysis also reveals that SM1 myosin heavy chains and SM2 myosin heavy chains are distinctly different. When RNA from the ALD muscle is added to reticulocyte lysate protein synthesizing systems the translation products are shown to include both SM1 and SM2 myosin heavy chains. These comigrate exactly on 5% SDS polyacrylamide gels with authentic counterparts from ALD muscle. Finally, when peptide maps of SM1 and SM2 myosin heavy chains synthesized in the reticulocyte lysate are compared they are again found to be distinctly different and each is identical to a peptide map of respective authentic SM1 and SM2 myosin heavy chains. It is concluded that the myosin heavy chains of SM1 and SM2 myosin isozymes of ALD muscle have different primary structures and that they are encoded by two distinctly different mRNAs.     

Light chains of sea urchin kinesin identified by immunoadsorption

Previous studies with monoclonal antibodies indicate that sea urchin kinesin contains two heavy chains arranged in parallel such that their N-terminal ends fold into globular mechanochemical heads attached to a thin stalk ending in a bipartite tail [Scholey et al., 1989]. In the present, complementary study, we have used the monoclonal antikinesin, SUK4, to probe the quaternary structure of sea urchin (Strongylocentrotus purpuratus) kinesin. Kinesin prepared from sea urchin cytosol sedimented at 9.6 S on sucrose density gradients and consisted of 130-kd heavy chains plus an 84-kd/78 kd doublet (1 mol heavy chain: 1 mol doublet determined by gel densitometry). Low levels of 110-kd and 90-kd polypeptides were sometimes present as well. The 84-kd/78 kd polypeptides are thought to be light chains because they were precipitated from the kinesin preparation at a stoichiometry of one mol doublet per 1 mol heavy chain using SUK4-Sepharose immunoaffinity resins. The 110-kd and 90-kd peptides, by contrast, were removed using this immunoadsorption method. SUK4-Sepharose immunoaffinity chromatography was also used to purify the 130-kd heavy chain and 84-kd/78-kd doublet (1 mol heavy chain: 1 mol doublet) directly from sea urchin egg cytosolic extracts, and from a MAP (microtubule-associated protein) fraction eluted by ATP from microtubules prepared in the presence of AMPPNP but not from microtubules prepared in ATP. The finding that sea urchin kinesin contains equimolar quantities of heavy and light chains, together with the aforementioned data on kinesin morphology, suggests that native sea urchin kinesin is a tetramer assembled from two light chains and two heavy chains.     

Clathrin heavy chain, light chain interactions

Purified pig brain clathrin can be reversibly dissociated and separated into heavy chain trimers and light chains in the presence of non-denaturing concentrations of the chaotrope thiocyanate. The isolated heavy chain trimers reassemble into regular polygonal cage structures in the absence of light chains. The light chain fraction can be further resolved into its two components L alpha and L beta which give different one-dimensional peptide maps. Radiolabelled light chains bind with high affinity (KD < 10(-10) M) to heavy chain trimers, to heavy chain cages and to a 110,000 mol. wt. tryptic fragment of the heavy chain. Both light chains compete with each other and with light chains from other sources for the same binding sites on heavy chains and c.d. spectroscopy shows that the two pig brain light chains possess very similar structures. We conclude that light chains from different sources, despite some heterogeneity, have a highly conserved, high affinity binding site on the heavy chain but are not essential for the formation of regular cage structures.     

Using a heavy chain-loss hybridoma 26.4.1LL for studying the structural basis of immunoglobulin chain association

One of the mechanisms contributing to antibody diversity is created by the association of different heavy and light chains. The combinability of heavy and light chains has been studied previously in two systems: in vitro chain recombination and hybrid hybridoma. Here, a novel in vivo chain combination assay system involving a heavy chain-loss variant, 26.4.1LL, producing two kappa light chains (L(DEX) and L(MPC)) different in size is described. In conjunction with DNA transfection, immunoprecipitation and SDS-PAGE, the structural basis of noncovalent interaction between heavy and light chains can be elucidated systematically by examining the relative association tendency of a heavy chain with two light chains. To demonstrate the usefulness of this system, three stably transfected 26.4.1LL cell lines expressing gamma2b heavy chains, designated as H(DEX), H(CHI) and H(ARS), respectively, with structural interrelated variable regions were generated: H(DEX) differs from H(CHI) only in framework regions whereas H(CHI) differs from H(ARS) in complementarity-determining regions. The relative amounts (R values) of L(DEX) and L(MPC) associated with the heavy chains H(DEX), H(CHI) and H(ARS) in the assembled immunoglobulin molecules were found to be 1.02, 0.64 and 0.05, respectively, suggesting that the complementarity-determining regions and framework regions contribute equally to the V(L)-V(H) interaction. This conclusion is consistent with previous observations based on calculation of the buried area in the V(L)-V(H) interface, thus demonstrating the usefulness of this system.     

Assembly and secretion of heavy chains that do not associate posttranslationally with immunoglobulin heavy chain-binding protein

Heavy chain-binding protein (BiP) associates posttranslationally with nascent Ig heavy chains in the endoplasmic reticulum (ER) and remains associated with these heavy chains until they assemble with light chains. The heavy chain-BiP complex can be precipitated by antibody reagents against either component. To identify sites on heavy chain molecules that are important for association with BiP, we have examined 30 mouse myelomas and hybridomas that synthesize Ig heavy chains with well characterized deletions. Mutant Ig heavy chains that lack the CH1 domain could not be demonstrated to associate with BiP, whereas mutant Ig heavy chains with deletions of the CH2 or CH3 domain were still able to associate with BiP. In two light chain negative cell lines that produced heavy chains with deletions of the CH1 domain, free heavy chains were secreted. When Ig assembly and secretion were examined in mutants that did not associate with BiP, and were compared with normal parental lines, it was found that the rate of Ig secretion was increased in the mutant lines and that the Ig molecules were secreted in various stages of assembly. In one mutant line (CH1-) approximately one-third of the secreted Ig molecules were incompletely assembled, whereas the Ig molecules secreted by the parental line were completely assembled. Our data show the CH1 domain to be important for association with BiP and that when this association does not occur, incompletely assembled heavy chains can be secreted. This implies a role for BiP in preventing the transport of unassembled Ig molecules from the ER.     

Does a monospecific hybridoma always secrete homogeneous immunoglobulins?

The fusion of splenocytes (from mice immunized with the beta 2 subunit of E. coli tryptophan synthase) with myeloma cells which do not produce immunoglobulins gave rise to a clone secreting immunoglobulins with two distinct isotypes : gamma 1 and gamma 2b (Djavadi-Ohaniance et al. (1984) Biochemistry, 23, 97-104). Analysis of the immunoglobulins secreted by this clone indicates that these two isotypes are carried by two distinct heavy chains which are able to randomly associate to form hybrid molecules. In addition, two classes of light chains are able to randomly and to form heterologous associations with both the gamma 1 and gamma 2b heavy chains. Only the association between the gamma 2b heavy chains with one of the two classes of light chains leads to a combining site specific for the binding of the antigen beta 2.     

Ubiquitinylation of the cytosolic domain of a type I membrane protein is not required to initiate its dislocation from the endoplasmic reticulum

Human cytomegalovirus US2 and US11 target newly synthesized class I major histocompatibility complex (MHC) heavy chains for rapid degradation by the proteasome through a process termed dislocation. The presence of US2 induces the formation of class I MHC heavy chain conjugates of increased molecular weight that are recognized by a conformation-specific monoclonal antibody, W6/32, suggesting that these class I MHC molecules retain their proper tertiary structure. These conjugates are properly folded glycosylated heavy chains modified by attachment of an estimated one, two, and three ubiquitin molecules. The folded ubiquitinated class I MHC heavy chains are not observed in control cells or in cells transfected with US11, suggesting that US2 targets class I MHC heavy chains for dislocation in a manner distinct from that used by US11. This is further supported by the fact that US2 and US11 show different requirements in terms of the conformation of the heavy chain molecule. Although ubiquitin conjugation may occur on the cytosolic tail of the class I MHC molecule, replacement of lysines in the cytosolic tail of heavy chains with arginine does not prevent their degradation by US2. In an in vitro system that recapitulates US2-mediated dislocation, heavy chains that lack these lysines still occur in an ubiquitin-modified form, but in the soluble (cytoplasmic) fraction. Such ubiquitin conjugation can only occur on the class I MHC lumenal domain and is likely to take place once class I MHC heavy chains have been discharged from the endoplasmic reticulum. We conclude that ubiquitinylation of class I MHC heavy chain is not required during the initial step of the US2-mediated dislocation reaction.     

Conformationally altered aortic myosin light chains

Aorta smooth myosin contains two types of light chain, LC20 and LC17, which fold together with the N-terminal region of each heavy chain to form the globular head region of myosin. We demonstrate an altered conformation of LC20 after its separation from heavy chain by high concentrations of urea, on the basis of the following evidende: 1) A polyclonal antibody against LC20 was not able to recognize this conformationally altered form; 2) Myosin reconstituted from heavy chains and urea-dissociated light chains exhibited extremely low ATPase activity. Circular dichroism unfolding profiles showed that light chains dissociated from heavy chains by SDS appeared to be more stable than those generated by urea dissociation.     

Separation of two different heavy meromyosins. Evidence for the presence of myosin isozymes in rabbit skeletal muscle.

Heavy meromyosin prepared from rabbit skeletal myosin by chymotryptic digestion was separated into two different heavy meromyosins by Sepharose 4B-6 aminohexyl PPi column chromatography. SDS-gel electrophoresis of one fraction of heavy meromyosin, which was eluted with 75 mM ammonium acetate, showed that it contained the small polypeptide chains, g3 and g2, as well as the large chains. The other fraction of heavy meromyosin, which was eluted with 85 mM ammonium acetate, contained g1 and g2. We concluded that the two heavy meromyosins arose from two different populations (isozymes) of myosin. No significant difference in Ca2+-ATPase activity was detected between the two heavy meromyosins.     

Separation, purification, partial characterization and comparison of the heavy and light chains of botulinum neurotoxin types A, B, and E

Clostridium botulinum produces botulinum neurotoxin (NT) in antigenically distinct forms. When isolated from bacterial cultures type E is a single chain, type B is a mixture of single and two-chain molecules, and type A is essentially a two-chain molecule (Mr approximately 150,000). Protease(s) in the cultures or trypsin nick single-chain NT to the two-chain form. The heavy (Mr approximately 100,000) and light (Mr approximately 50,000) chains of the two-chain molecule remain held together by -S-S-bond(s). The two chains are presumed to have different functions. NT binds to nerve cells via the heavy chain and then light chain enters the cell and blocks release of acetylcholine (Simpson, L. L. (1981) Pharmacol. Rev. 33, 155-188). We nicked single-chain NT to form the two-chain form with trypsin, minimizing secondary cleavages, then separated and purified the heavy and light chains using ion-exchange chromatography. The technique, with minor modifications, is a generalized method for types A, B, and E. These subunit chains (each a single band in sodium dodecyl sulfatepolyacrylamide gel electrophoresis) were analyzed for their complete amino acid compositions. The amino acid contents of the heavy and light chains agreed well with the parent two-chain molecule. This affirms that NT is composed of two chains. The two subunit chains are now usable for amino acid sequence and other studies. Comparison of the amino acid contents indicates more similarity among the light chains than the heavy chains of the three NT types, a similarity that agrees with our published partial amino acid sequences (first 13-18 residues) of these chains. Several (up to 9) different amino acid residues of the heavy chain (which is twice the size of the light chain) are present in double the number of corresponding residues in the light chain.     

Two heavy chains of 21S dynein from sea urchin sperm flagella

The biochemical properties of 21S dynein derived from sea urchin sperm flagella and of its components dissociated by low salt treatment were studied. SDS-urea gel electrophoresis and two-dimensional gel electrophoresis showed that the 21S dynein preparation contains two distinct heavy chains. These two heavy chains, termed A alpha and A beta, had apparently the same molecular weight of 500,000 but showed different mobilities on SDS-urea gels. The isoelectric points of A alpha and A beta heavy chains were 5.7 and 5.2, respectively, in the presence of urea. Proteolytic digestion patterns of these two heavy chains were clearly different, but the amino acid compositions were similar. Low salt treatment and sucrose density gradient centrifugation could partially separate the components of 21S dynein into two fractions: the one with larger sedimentation coefficient contained the A alpha heavy chain, and the other with smaller sedimentation coefficient contained the A beta heavy chain and three intermediate chains. These two fractions showed distinctly different kinetic properties, and thus may play different roles in dynein-microtubule interaction.     

The complete sequence of the human beta-myosin heavy chain gene and a comparative analysis of its product

We have isolated and sequenced the gene and the cDNA coding for the human cardiac beta-myosin heavy chain (designated MYH7). The gene is 22,883 bp long. The 1935 amino acids of this protein (Mr223,111) are encoded by 38 exons. The 5' untranslated region (86 bp) is split by two introns. The 3' untranslated region is 114 bp long. Three Alu repeats were identified within the gene and a fourth one in the 3' flanking intergenic region. The molecular organization of this gene reflects the conservative pattern with respect to size, coding ratio, and number or position of introns characteristic of vertebrate sarcomeric myosin heavy chain genes. The protein sequence of the human beta-heavy chain was compared with corresponding (homologous) sequences of rabbit, rat, and hamster as well as with the (heterologous) embryonic heavy chain sequences of rat, chicken, and man. The results show that protein subregions responsible for basic functions of myosin heavy chains (nucleotide binding and actin binding) are very similar in homologous and heterologous heavy chains. Regions that differ in their primary sequences in heterologous heavy chains appear to be highly conserved within mammalian beta-myosin heavy chains. Constant and variable subregions of heavy chains are discussed in terms of functional significance and evolutionary relatedness.     

Interconversion of conformational isomers of light chains in the Mcg immunoglobulins.

Previous crystallographic studies in this laboratory demonstrated that immunoglobulin light chains with the same amino acid sequence can have at least two and probably three or more conformations, depending on whether the second member of an interacting pair is a light or heavy chain. If a heavy chain is not available in the assembly medium, a second light chain plays the structural role of the heavy chain in the formation of a dimer. In the present work, the lambda-type light chains were dissociated from the heavy chains of a serum IgG1 immunoglobulin from the patient Mcg and reassembled noncovalently into a dimer. The reassembly process was completed by allowing the penultimate half-cystine residues to form an interchain disulfide bond. The covalently linked dimer was compared with the Mcg urinary Bence-Jones dimer, for which an atomic model has been fitted to a 2.3-A electron density map. The assembled dimer and the native Bence-Jones protein were indistinguishable in their chromatographic and electrophoretic properties, as well as in their activity in the binding of bis(dinitrophenyl)lysine. These results indicate that the light chains can be converted into the two types of Bence-Jones conformational isomers. The procedure was also reversed: the two Bence-Jones isomers were dissociated and reassembled as the single type of isomer associating with each of two heavy chains in the IgG1 protein. The change in activity occurring when a light chain associates with a heavy chain instead of a second light chain is illustrated by the fact that the Mcg IgG1 immunoglobulin does not bind dis(dinitrophenyl)lysine in measurable amounts.     

BiP and Immunoglobulin Light Chain Cooperate to Control the Folding of Heavy Chain and Ensure the Fidelity of Immunoglobulin Assembly

The immunoglobulin (Ig) molecule is composed of two identical heavy chains and two identical light chains (H2L2). Transport of this heteromeric complex is dependent on the correct assembly of the component parts, which is controlled, in part, by the association of incompletely assembled Ig heavy chains with the endoplasmic reticulum (ER) chaperone, BiP. Although other heavy chain-constant domains interact transiently with BiP, in the absence of light chain synthesis, BiP binds stably to the first constant domain (CH1) of the heavy chain, causing it to be retained in the ER. Using a simplified two-domain Ig heavy chain (VH-CH1), we have determined why BiP remains bound to free heavy chains and how light chains facilitate their transport. We found that in the absence of light chain expression, the CH1 domain neither folds nor forms its intradomain disulfide bond and therefore remains a substrate for BiP. In vivo, light chains are required to facilitate both the folding of the CH1 domain and the release of BiP. In contrast, the addition of ATP to isolated BiP-heavy chain complexes in vitro causes the release of BiP and allows the CH1 domain to fold in the absence of light chains. Therefore, light chains are not intrinsically essential for CH1 domain folding, but play a critical role in removing BiP from the CH1 domain, thereby allowing it to fold and Ig assembly to proceed. These data suggest that the assembly of multimeric protein complexes in the ER is not strictly dependent on the proper folding of individual subunits; rather, assembly can drive the complete folding of protein subunits.     

Factor X activator from Vipera lebetina venom is synthesized from different genes

Vipera lebetina venom contains specific coagulant Factor X activator (VLFXA) that cleaves the Arg52-Ile53 bond in the heavy chain of human factor X. VLFXA is a glycoprotein that is composed of a heavy chain (HC) and two light chains (LC) linked by disulfide bonds. The complete amino acid sequences of the three chains of the factor X activator from V. lebetina snake venom are deduced from the nucleotide sequences of cDNAs encoding these chains. The full-length cDNA (2347 bp) sequence of the HC encodes an open reading frame (ORF) of 612 amino acids that includes signal peptide, propeptide and mature metalloproteinase with disintegrin-like and cysteine-rich domains. The light chain LC1 contains 123 and LC2 135 amino acid residues. Both light chains belong to the class of C-type lectin-like proteins. The N-termini of VLFXA chains and inner sequences of peptide fragments detected by liquid chromatography-electrospray ionization tandem mass spectrometry (LC MS/MS) from protein sequence are 100% identical to the sequences deduced from the cDNA. The molecular masses of tryptic fragments of VLFXA chains analyzed by matrix-assisted laser desorption ionization time of flight mass spectrometry (MALDI-TOF MS) also confirm the protein sequences deduced from the cDNAs. These are the first cloned factor X activator heavy and light chains. We demonstrate that the heavy and light chains are synthesized from different genes.     

Biosynthesis and structure of membrane and secretory immunoglobulins

Summary Almost all of the body's extracellular immunoglobulin (Ig) is derived from Ig-secreting plasma cells of lymphoid tissues. The secreted material is a heterogeneous mixture of different classes and specificities. Lymphoid tissues also contain a large number of essentially non-secretory cells — B lymphocytes — which bear Ig firmly associated with their plasma membranes. Ig molecules thus exist in two functionally different forms, as membrane-bound antigen receptors on the surface of B lymphocytes on the one hand, and as humoral secreted Ig antibodies on the other. On B cells, membrane-bound heavy chains have an apparent mol. wt. slightly larger than that of secreted heavy chains from plasma cells. Membrane-bound but not secreted heavy chains bind detergents, thus suggesting the presence of a hydrophobic region in membrane-bound heavy chains, which is absent in secreted heavy chains. Most investigations have dealt with immunoglobulin M. The two types of IgM heavy chains differ at their carboxy termini. Recent investigations at the nucleic acid level demonstrate that membrane-associated µ chains contain a 41-residue hydrophobic tail adjacent to the last constant domain, whereas secretory µ chains contain a 20-residue hydrophilic tail. At the present time, evidence is accumulating that all membrane-bound Ig heavy chain classes may contain similar hydrophobic structures necessary for anchorage of the molecules into the lipid bilayer.     

Neonatal and adult myosin heavy chains form homodimers during avian skeletal muscle development

Myosin isoforms contribute to the heterogeneity and adaptability of skeletal muscle fibers. Besides the well-characterized slow and fast muscle myosins, there are those isoforms that appear transiently during the course of muscle development. At a stage of development when two different myosins are coexpressed, the possibility arises for the existence of heterodimers, molecules containing two different heavy chains, or homodimers, molecules with two identical heavy chains. The question of whether neonatal and adult myosin isoforms can associate to form a stable heterodimer was addressed by using stage-specific monoclonal antibodies in conjunction with immunological and electron microscopic techniques. We find that independent of the ratio of adult to neonatal myosin, depending on the age of the animal, the myosin heavy chains form predominantly homodimeric molecules. The small amount of hybrid species present suggests that either the rod portion of the two heavy chain isoforms differs too much in sequence to form a stable alpha-helical coiled coil, or that the biosynthesis of the heavy chains precludes the formation of heterodimeric molecules.     

Changes in the molecular topography of the light and heavy chains of type A botulinum neurotoxin following their separation

Botulinum neurotoxin serotype A, an approx. 150 kDa protein, is composed of two subunits, the light and heavy chains (approximately 50 and approximately 100 kDa, respectively). The neurotoxin's mode of action is believed to depend on coordinated but independent actions of the two subunit chains. The molecular environments of the aromatic amino acid residues of the dichain neurotoxin and the two isolated subunit chains were analyzed using near-ultraviolet circular dichroism (CD) (between 250 and 320 nm) and second-derivative ultraviolet absorption spectroscopy (between 240 and 320 nm) to investigate the conformational variations of the subunit chains in separated and conjugated forms. The mean residue weight ellipticities showed virtually no change (i.e., 1.7%) in the vicinities of Phe (268 nm), and only a small change (11%) around Tyr (279 nm) residues following dissociation of the subunit chains. However, significant changes (23-26%) at 286 nm as well as at 292 nm were noted, suggesting considerable alteration in the conformation of the subunits. Second-derivative ultraviolet absorption spectra indicated the degree of Tyr exposure in the dichain neurotoxin, isolated heavy and light chains at 70.7, 81.5 and 46.4%, respectively. A weighted mean of the degree of exposed Tyr residues in the separated heavy and light chains was 69.6%, virtually same as the 70.7% exposed Tyr residues observed in the intact dichain neurotoxin, indicating no difference in their Tyr exposure upon separation of the two chains. This was corroborated by the CD data which revealed only small changes in the CD signals of Tyr residues, and no alteration in those of the Phe residues following separation of the subunit chains. However, a change in the CD signal at 292 nm suggested that the conformations of Trp-containing segments of the two chains were significantly influenced upon their separation. The heavy and light chains of the neurotoxin therefore appear to exist as two semi-independent domains, in spite of being linked by disulfide and noncovalent bonds, and at least part of their conformations depends on interactions between them.     

Two homogeneous myosins in body-wall muscle of Caenorhabditis elegans

Myosin purified from the body-wall muscle-defective mutant E675 of the nematode. Caenorhabditis elegans, has heavy chain polypeptides which can be distinguished on the basis of molecular weight. On SDS-polyacrylamide gels, bands are found at 210,000 and 203,000 daltons. This is in contrast to myosin from the wild-type, N2, which has a single heavy chain band at 210,000 daltons. Both heavy chains of E675 are found in body-wall muscle (Epstein, Waterston and Brenner, 1974).When native myosin from E675 is fractionated on hydroxyapatite, it is separated into myosin containing predominantly one or the other molecular weight heavy chain and myosin containing a mixture of the heavy chains. Comparison of the CNBr fragments of myosin that contains predominantly 210,000 dalton heavy chains with those of myosin that contains predominantly 203,000 dalton heavy chains reveals multiple differences. These differences are not explained by the difference in molecular weight of the heavy chains, but may be explained if each type of heavy chain is the product of a different structural gene. Furthermore, because there are fractions which exhibit >80% 210,000 or >80% 203,000 dalton heavy chain, there is myosin which is homogeneous for each of the heavy chains.Although N2 myosin has only a single molecular weight heavy chain, it too is fractionated by hydroxyapatite. By comparing the CNBr fragments of different myosin fractions, we show that N2, like E675, has two kinds of heavy chains.E190, a body-wall muscle-defective mutant in the same complementation group as E675, is lacking the myosin heavy chain affected by the e675 mutation. This property has allowed us to determine by co-purification of labeled E190 myosin in the presence of excess, unlabeled E675 myosin that most, if not all, of the myosin that contains two different molecular weight heavy chains is due to the formation of complexes between homogeneous myosins and not to a heterogeneous myosin.