Comparison of myosin heavy chains in atria and ventricles from hyperthyroid, hypothyroid, and euthyroid rabbits

The structural similarities of the heavy chains (HC) of myosin isolated from atria and ventricles of hyper-, hypo-, and euthyroid rabbits were compared by immunological analysis, by one- and two-dimensional peptide mapping, and by electrophoresis under nondenaturing conditions. Monoclonal and polyclonal antibodies, which are specific for HC alpha of ventricular myosin, cross-reacted equally with the HCs of euthyroid atrial myosin. Our immunological analysis identified multiple epitopes common to euthyroid atrial HC and ventricular HC alpha. One- and two-dimensional gel electrophoretic analysis of peptides produced by partial proteolytic digestion of each type of HC reveal no differences between euthyroid atrial HCs and ventricular HC alpha, whereas marked differences are apparent between atrial HC and ventricular HC beta. Nondenaturing gel electrophoresis separates ventricular myosin from hyper- and hypothyroid rabbits into two forms, V1 and V3, respectively. In euthyroid atria, two isomyosins, A1 and A2, were resolved; with the slower moving A2 isomyosin having the same mobility as that of the V1 isomyosin. After cross-hybridization of light chains of ventricular myosin with euthyroid atrial HCs, only a single band having a mobility identical with that of the V1 isomyosin was seen. Furthermore, atrial myosin HCs isolated from hyper- and hypothyroid rabbits were indistinguishable from euthyroid atrial HC and from ventricular HC alpha by these procedures. We conclude that ventricular HC alpha and atrial HC are indistinguishable proteins, and that the type of HC expressed in the atria is unaffected by the thyroid state of the rabbit.     

Isolation and characterization of two isozymes of myosin heavy chain from canine atrium

To clarify the characteristics of myosin isozymes in the atrium, we fractionated two isoforms of myosin heavy chain (HC), atrial HC alpha (A-HC alpha) and HC beta (A-HC beta), from the canine heart by affinity chromatography, using monoclonal antibodies specific for HC alpha (CMA19) and HC beta (HMC50), respectively, and then compared their peptide composition and enzymatic properties with those of ventricular HC alpha (V-HC alpha) and HC beta (V-HC beta). The reactivity of these isozymes with three monoclonal antibodies revealed that there are at least three different epitopes between A-HC alpha and A-HC beta. Differences in the primary structure of A-HC alpha and A-HC beta were confirmed by one- and two-dimensional gel electrophoretic analyses of these peptides, produced by digestion with alpha-chymotrypsin and cyanogen bromide (CNBr). A-HC alpha and V-HC alpha were indistinguishable proteins, and A-HC beta was also very similar to V-HC beta. Furthermore, there were differences between A-HC alpha and A-HC beta in their Ca2+-activated ATPase activities. The ATPase activity of A-HC beta was lower than that of A-HC alpha and was similar to that of V-HC beta. We concluded that there are two different isozymes of myosin heavy chain in the atrium (A-HC alpha and A-HC beta), as well as in the ventricle (V-HC alpha and V-HC beta), and that A-HC beta is very similar to V-HC beta, the predominant form of ventricular myosin, in its molecular structure and enzymatic activity.     

Immunological and biochemical evidence for atrial-like isomyosin in thyrotoxic rabbit ventricle

Immunological, structural and enzymatic characteristics of atrial and ventricular myosin from euthyroid rabbits were analyzed and compared with ventricular myosin from hyperthyroid animals. (1) Specific antibodies against bovine atrial myosin were found to react selectively in double-immunodiffusion and enzyme immunoassay with both rabbit atrial myosin and ventricular myosin from thyroxine-treated animals. These specific anti-bovine atrial myosin antibodies reacted with the heavy chains of thyrotoxic ventricular myosin when examined by enzyme immunoassay combined with SDS-polyacrylamide gel electrophoresis. (2) In one-dimensional SDS-polyacrylamide gel electrophoresis, no difference could be demonstrated in the light chain pattern of ventricular myosin from euthyroid and hyperthyroid rabbit hearts. One-dimensional analysis of myosin heavy chains after chymotryptic digestion in the presence of SDS showed significant differences between the two ventricular myosins. Also, the peptide maps from atrial myosin resembled the pattern of peptides found with ventricular heavy chains from hyperthyroid rabbits. The steady state rate, the alkali stability and the pH sensitivity of Ca2+-ATPase activity of thyrotoxic ventricular myosin were very similar to those of atrial myosin. (3) These results provide direct immunochemical and biochemical evidence for the existence of an atrial-like isomyosin in thyrotoxic rabbit ventricles.     

Amino acid sequence of a segment of the Acanthamoeba myosin II heavy chain containing all three regulatory phosphorylation sites

The actin-activated Mg2+-ATPase activity of myosin II from the soil amoeba Acanthamoeba castellanii is regulated by phosphorylation of 3 serine residues on the myosin II heavy chain. Partial chymotryptic digestion of 32P-labeled myosin II cleaves from the tail end of the myosin II heavy chain a small peptide which contains all three phosphorylation sites. During purification the phosphorylated peptide is resolved into several different species as a result of heterogeneity both in phosphate content and in size (probably due to chymotryptic cleavage at the carboxyl terminus). However, all forms of the peptide have an identical amino terminus. The sequence of the first 58 residues of the peptide is: N-S-A-L-E-S-D-K-Q-I10-L-E-D-E-I-G-D-L-H- E20-K-N-K-Q-L-Q-A-K-I-A30-Q-L-Q-D-E-I-D-G-T- P40-S-S-R-G-G-S-T-R-G-A50-S-A-R-G-A-S-V-R. The phosphorylated serines are at positions 46, 51, and 56. The first 36 residues of the sequence display a repeating 3-4-3-4 pattern of hydrophobic residues suggesting that this section of the peptide forms an alpha-helical coiled-coil structure. A -Gly-Thr-Pro sequence at residues 38-40 disrupts the alpha-helix and, at the same point, the repeating pattern of non-polar residues is lost. It is likely that the residues extending from Gly-38 to the end of the myosin II tail, which include the 3 phosphorylatable serines, form a randomly coiled or small globular structure. This is the first report of the sequence around the regulatory phosphorylation sites on any myosin heavy chain.     

Analysis of cloned mRNA sequences encoding subfragment 2 and part of subfragment 1 of alpha- and beta-myosin heavy chains of rabbit heart

Two cardiac myosin heavy chain cDNA clones, pMHC alpha 252 and pMHC beta 174, were constructed using rabbit ventricular mRNA isolated from adult thyrotoxic and normal hearts, respectively. The complete DNA sequences of the 2.2- and 1.4-kilobase inserts of pMHC beta 174 and pMHC alpha 252, respectively, were obtained. The 736 amino acids specified by pMHC beta 174 begin 439 (1.3 kilobases) residues from the heavy chain NH2 terminus and include a 400-amino acid segment of subfragment 1 and the entire subfragment 2 region. Clone pMHC alpha 252 encodes 465 amino acids encompassing all of subfragment 2 and a portion of light meromyosin. Comparison of these two clones revealed extensive sequence overlap which included 1107 nucleotides specifying a 369-amino acid segment corresponding to subfragment 2. Within this region 78 (7%) base and 32 (8.7%) amino acid mismatches were noted. These differences were clustered within discrete regions, with the subfragment 1/subfragment 2 junctional region being particularly divergent. Structural differences between pMHC alpha 252 and pMHC beta 174 indicate that these two clones represent two similar but distinct myosin heavy chain genes whose expression is responsible for ventricular myosin heavy chain isoforms alpha and beta, respectively. The derived amino acid sequences of both clones exhibit extensive homology (greater than 81%) with sequences obtained by direct analysis of adult rabbit skeletal muscle myosin heavy chain protein. The sequences corresponding to the subfragment 2 region are consistent with an alpha-helical conformation with a characteristic 7-residue periodicity in the linear distribution of nonpolar amino acids. Conversely, subfragment 1 sequences specified by pMHC beta 174 suggest a folded highly irregular structure.     

Expression of myosin heavy chains during thyroid hormone-induced cardiac growth

The expression of mRNAs for two cardiac myosins has been studied in the ventricles of hypo- and hyperthyroid rabbits by using cloned cDNA sequences corresponding to the mRNAs of the alpha- and beta-myosin heavy chains (HCs). The temporal change in relative levels of the alpha and beta HC mRNAs after triiodothyronine (T3) treatment of hypothyroid rabbits was determined by nuclease S1 mapping. In the hypothyroid state, only NC beta-mRNA was expressed in the ventricles. The HC alpha-mRNA was first detectable 4 h after administration of T3 (200 micrograms/kg) to hypothyroid animals. By 12, 24, and 72 h, HC alpha-mRNA represented 20, 50, and 90% of total myosin mRNA. The relationship between the relative mRNA levels and relative synthesis rates of myosin HCs was evaluated in 5- to 6-wk-old normal and thyrotoxic rabbits. Myosin synthesis rates were determined by labeling of protein in vivo with [2H]leucine. The V1 (HC alpha) and V3 (HC beta) isomyosins were separated by immune affinity chromatography and the HCs were isolated electrophoretically. In a normal euthyroid group of animals and in animals 12 and 24 h after administration of 200 micrograms of thyroxine, the relative mRNA levels and relative synthesis rates of the alpha and beta HCs were not significantly different. Our results show that, first, thyroid hormone causes a rapid accumulation of HC alpha-mRNA and loss of HC alpha-mRNA, and second, in normal and thyrotoxic rabbits, the relative synthesis rates of HC alpha and HC beta reflect the relative abundance of their respective mRNAs. These data are consistent with the thyroid hormones regulating synthesis of ventricular myosin at steps that precede translation of its message.     

Construction of a human ventricular cDNA library and characterization of a beta myosin heavy chain cDNA clone

Summary We have constructed and characterized for the first time a complementary DNA (cDNA) clone, pHMC3, which codes for a cardiac myosin heavy chain mRNA from human heart. This clone contains a 1.7 kb DNA segment and specifies 543 amino acids of the carboxyl portion of the myosin heavy chain. The DNA sequence and encoded amino acid sequence were compared to the hamster alpha (pVHC1) and beta (pVHC2/pVHC3) cardiac myosin heavy chain cDNA and amino acid sequences and the rat cardiac myosin heavy chain sequences as well. The myosin heavy chain mRNAs are highly conserved and this is reflected in our cDNA clone. The pHMC3 clone is 87.9% homologous to the hamster alpha cDNA and 92.2% homologous to the hamster beta cDNA clones. The 3 untranslated region of pHMC3 is 64.1% homologous to the hamster beta clone while the hamster alpha myosin heavy chain shows only 25% homology to pHMC3 and exhibits extensive diversity. Similar results rere obtained when pHMC3 was compared to the rat cardiac myosin heavy chain cDNA sequences. The comparisons showed that pHMC3 is a beta cardiac myosin heavy chain cDNA clone.     

Localization and topography of antigenic domains within the heavy chain of smooth muscle myosin

We have produced and characterized monoclonal antibodies that label antigenic determinants distributed among three distinct, nonoverlapping peptide domains of the 200-kD heavy chain of avian smooth muscle myosin. Mice were immunized with a partially phosphorylated chymotryptic digest of adult turkey gizzard myosin. Hybridoma antibody specificities were determined by solid-phase indirect radioimmunoassay and immunoreplica techniques. Electron microscopy of rotary-shadowed samples was used to directly visualize the topography of individual [antibody.antigen] complexes. Antibody TGM-1 bound to a 50-kD peptide of subfragment-1 (S-1) previously found to be associated with actin binding and was localized by immunoelectron microscopy to the distal aspect of the myosin head. However, there was no antibody-dependent inhibition of the actin-activated heavy meromyosin ATPase, nor was antibody TGM-1 binding to actin-S-1 complexes inhibited. Antibody TGM-2 detected an epitope of the subfragment-2 (S-2) domain of heavy meromyosin but not the S-2 domain of intact myosin or rod, consistent with recognition of a site exposed by chymotryptic cleavage of the S-2:light meromyosin junction. Localization of TGM-2 to the carboxy-terminus of S-2 was substantiated by immunoelectron microscopy. Antibody TGM-3 recognized an epitope found in the light meromyosin portion of myosin. All three antibodies were specific for avian smooth muscle myosin. Of particular interest is that antibody TGM-1, unlike TGM-3, bound poorly to homogenates of 19-d embryonic smooth muscles. This indicates the expression of different myosin heavy chain epitopes during smooth muscle development.     

Amino acid sequence of the active site of Acanthamoeba myosin II

We have used the substrate [5,6-3H]UTP for direct photoaffinity labeling of the active site of the heavy chain of myosin II from Acanthamoeba castellanii. The only labeled peptide in a total tryptic digest had the sequence of Thr-Glu-Asn-Thr-Me2Lys-Lys (where Me2Lys represents dimethyllysine) with the substrate covalently bound to the Glu residue. This sequence differs at only one position from the sequence of residues 184-189 of nematode myosin heavy chain (Me2Lys----Lys), a post-translational modification, and at two additional positions from residues 185-190 of rabbit skeletal muscle myosin (Glu----Val and Lys----Arg). The partial sequence of a larger labeled peptide derived from total chymotryptic digestion was compatible with and extended this sequence. A 20-residue sequence that contains the active site, tryptic hexapeptide is otherwise identical in Acanthamoeba and rabbit skeletal muscle myosins and has only one more difference in nematode myosin. Because UTP is a substrate for myosin II and a "zero-length" probe, we believe that it identifies amino acid residues that are very close to the substrate during the catalytic cycle.     

Thyroid hormone stimulates synthesis of a cardiac myosin isozyme. Comparison of the two-two-dimensional electrophoretic patterns of the cyanogen bromide peptides of cardiac myosin heavy chains from euthyroid and thyrotoxic rabbits.

The CNBr peptides of [14C]carboxymethylated cardiac myosin heavy chains from euthyroid and thyrotoxic rabbits have been compared using a two-dimensional electrophoretic system. The results indicated that there were extensive differences in the peptide "maps" of these heavy chains, which included differences in the distribution of radiolabeled thiol peptides. Also, the patterns of heavy chain peptides from the cardiac myosins have been compared with those produced by the heavy chain myosin isozymes from skeletal muscles. Peptide maps of heavy chains from red skeletal muscle myosin closely resembled the pattern of peptides found with cardiac myosin heavy chains from euthyroid rabbits. However, peptide maps of heavy chains from white skeletal muscle myosin were dissimilar to those of the cardiac myosin isozymes. We conclude that thyroxine administration stimulates the synthesis of a cardiac myosin isozyme with a heavy chain primary structure which is different from either of the skeletal muscle myosin isozymes.     

Conformational transitions in the myosin head induced by temperature, nucleotide and actin. Studies on subfragment-1 of myosins from rabbit and frog fast skeletal muscle with a limited proteolysis method

Tryptic digestion patterns reveal a close similarity of the substructure of frog subfragment-1 (S1) to that established for rabbit S1. The 97-kDa heavy chain of chymotryptic S1 of frog myosin is preferentially cleaved into three fragments with apparent molecular masses of 29 kDa, 49 kDa and 20 kDa. These fragments correspond to the 27-kDa, 50-kDa and 20-kDa fragments of rabbit S1, respectively; this is indicated by the sequence of their appearance during digestion, by the suppression by actin of the generation of the 49-kDa and 20-kDa peptides, and by a nucleotide-promoted cleavage of the 29-kDa peptide to a 24-kDa fragment and the 49-kDa peptide to a 44-kDa fragment, analogous to the nucleotide-promoted cleavage of the 27-kDa and 50-kDa fragments of rabbit S1 to the 22-kDa and 45-kDa peptides. The same changes in the digestion patterns as those produced by the presence of nucleotide (ATP or its beta,gamma-imido analog AdoP P[NH]P) at 25 degrees C were observed when the digestion was carried out at 0 degrees C in the absence of nucleotide. The low-temperature-induced changes were particularly well seen in the preparations from frog myosin. The presence of ATP or AdoP P[NH]P at 0 degrees C enhanced, whereas the complex formation with actin prevented, the low-temperature-induced changes. The results are consistent with there being two fundamental conformational states of the myosin head in an equilibrium that is dependent on the temperature, the nucleotide bound at the active site, and the presence or absence of actin.     

Purification of messenger ribonucleic acids for fast and slow myosin heavy chains by indirect immunoprecipitation of polysomes from embryonic chick skeletal muscle

Fast and slow myosin heavy chain mRNAs were isolated by indirect immunoprecipitation of polysomes from 14-day-old embryonic chick leg muscle. The antibodies were prepared against myosin heavy chains purified by NaDod-SO4-polyacrylamide gel electrophoresis and were shown to be specific for fast and slow myosin heavy chains. The RNA fractions directed the synthesis of myosin heavy chains in a cell-free translation system from wheat germ. Several smaller peptides were also synthesized in lower concentrations. These probably are partial products of myosin heavy chains, since they are immunoprecipitated with antibodies to myosin heavy chains. Immunoprecipitation of the translation products with the antibodies to fast and slow myosin heavy chains showed the RNA preparations to be approximately 94% enriched for fast myosin heavy chain mRNA and approximately 84% enriched for slow myosin heavy chain mRNA with respect to myosin HC type. Peptides having slightly different mobilities on NaDodSO4-polyacrylamide gels were immunoprecipitated by antibodies to fast and slow myosin heavy chains.     

Human cardiac myosin heavy chain genes and their linkage in the genome.

Human myosin heavy chains are encoded by a multigene family consisting of at least 10 members. A gene-specific oligonucleotide has been used to isolate the human beta myosin heavy chain gene from a group of twelve nonoverlapping genomic clones. We have shown that this gene (which is expressed in both cardiac and skeletal muscle) is located 3.6kb upstream of the alpha cardiac myosin gene. We find that DNA sequences located upstream of rat and human alpha cardiac myosin heavy chain genes are very homologous over a 300bp region. Analogous regions of two other myosin genes expressed in different muscles (cardiac and skeletal) show no such homology to each other. While a human skeletal muscle myosin heavy chain gene cluster is located on chromosome 17, we show that the beta and alpha human cardiac myosin heavy chain genes are located on chromosome 14.     

Effect of cardiac and skeletal tropomyosin on Mg2+-actomyosin ATPase.

Tropomyosin, one of the proteins regulating the sarcomere, was prepared from pig heart and rabbit skeletal muscles. The effect of these two different tropomyosins was studied between 0.5 and 10 mM of Mg2+ at a constant ATP concentration (1 mM) on reconstituted actomyosin prepared from pig heart myosin and rabbit skeletal actin. Cardiac and skeletal tropomyosin both activated the ATPase at low Mg2+ concentrations and inhibited it above 3 mM. The pig heart and rabbit skeletal tropomyosins which contain two isomers, alpha alpha and alpha beta, respectively has very similar effects on actomyosin ATPase.     

Full-length rat alpha and beta cardiac myosin heavy chain sequences. Comparisons suggest a molecular basis for functional differences

The two cardiac myosin heavy chain isoforms, alpha and beta, differ functionally, alpha Myosin exhibits higher actin-activated ATPase than does beta myosin, and hearts expressing alpha myosin exhibit increased contractility relative to hearts expressing beta myosin. To understand the molecular basis for this functional difference, we determined the complete nucleotide sequence of full-length rat alpha and beta myosin heavy chain cDNAs. This study represents the first opportunity to compare full-length fast ATPase and slow ATPase muscle myosin sequences. The alpha and beta myosin heavy chain amino acid sequences are more related to each other than to other sarcomeric myosin heavy chain sequences. Of the 1938 amino acid residues in alpha and beta myosin heavy chain, 131 are non-identical with 37 non-conservative changes. Two-thirds of these non-identical residues are clustered, and several of these clusters map to regions that have been implicated as functionally important. Some of the regions identified by the clusters of non-identical amino acid residues may affect actin binding, ATP hydrolysis and force production.     

Knockdown of embryonic myosin heavy chain reveals an essential role in the morphology and function of the developing heart

The expression and function of embryonic myosin heavy chain (eMYH) has not been investigated within the early developing heart. This is despite the knowledge that other structural proteins, such as alpha and beta myosin heavy chains and cardiac alpha actin, play crucial roles in atrial septal development and cardiac function. Most cases of atrial septal defects and cardiomyopathy are not associated with a known causative gene, suggesting that further analysis into candidate genes is required. Expression studies localised eMYH in the developing chick heart. eMYH knockdown was achieved using morpholinos in a temporal manner and functional studies were carried out using electrical and calcium signalling methodologies. Knockdown in the early embryo led to abnormal atrial septal development and heart enlargement. Intriguingly, action potentials of the eMYH knockdown hearts were abnormal in comparison with the alpha and beta myosin heavy chain knockdowns and controls. Although myofibrillogenesis appeared normal, in knockdown hearts the tissue integrity was affected owing to apparent focal points of myocyte loss and an increase in cell death. An expression profile of human skeletal myosin heavy chain genes suggests that human myosin heavy chain 3 is the functional homologue of the chick eMYH gene. These data provide compelling evidence that eMYH plays a crucial role in important processes in the early developing heart and, hence, is a candidate causative gene for atrial septal defects and cardiomyopathy.     

Phosphorylation of myosin light chain by protease activated kinase I

Protease activated kinase I from rabbit reticulocytes has been shown to phosphorylate the P-light chain of myosin light chains isolated from rabbit skeletal muscle. The enzyme is not activated by Ca²⁺ and calmodulin or phospholipids. Protease activated kinase I is not inhibited by trifluoperazine at concentrations up to 200 μM or by the antibody to the Ca²⁺, calmodulin-dependent myosin light chain kinase from rabbit skeletal muscle. Two-dimensional peptide mapping of chymotryptic digests of myosin P-light chain show the site phosphorylated by the protease activated kinase is different from that phosphorylated by the Ca²⁺, calmodulin-dependent myosin light chain kinase.     

Relation of fast and slow skeletal, and atrial and ventricular myosin in various mammals

Myosin was isolated from adult mouse, rat, rabbit and cat atrial and ventricular myocardium and fast and slow skeletal muscles and examined by measuring Ca2+-ATPase activity and by electrophoretic fractionation of chymotryptic peptides and MLCs. The myosin from mouse atrial and ventricular myocardium were very similar. The properties of cat soleus muscle myosin and ventricular myocardium were also very similar (ATPase activity and electrophoretic pattern of chymotryptic peptides of myosin). The electrophoretic pattern of MLCs, however, was distinct when comparing mouse and feline muscles. These observations are consistent with the idea that atrial and ventricular alpha MHCs are closely related and that beta MHCs from ventricular myocardium and slow skeletal muscle fibres are also closely related.