The Complete Amino Acid Sequence of Actins from Bovine Aorta, Bovine Heart, Bovine Fast Skeletal Muscle, and Rabbit, Slow Skeletal Muscle

Complete amino acid sequences for four mammalian muscle actins are reported: bovine skeletal muscle actin, bovine cardiac actin, the major component of bovine aorta actin, and rabbit slow skeletal muscle actin. The number of different actins in a higher mammal for which full amino acid sequences are now available is therefore increased from two to five. Screening of different smooth muscle tissues revealed in addition to the aorta type actin a second smooth muscle actin, which appears very similar if not identical to chicken gizzard actin. Since the sequence of chicken gizzard actin is known, six different actins are presently characterized in a higher mammal.
The two smooth muscle actins—bovine aorta actin and chicken gizzard actin—differ by only three amino acid substitutions, all located in the amino-terminal end. In the rest of their sequences both smooth muscle actins share the same four amino acid substitutions, which distinguish them from skeletal muscle actin. Cardiac muscle actin differs from skeletal muscle actin by only four amino acid exchanges. No amino acid substitutions were found when actins from rabbit fast and slow skeletal muscle were compared.
In addition we summarize the amino acid substitution patterns of the six different mammalian actins and discuss their tissue specificity. The results show a very close relationship between the four muscle actins in comparison to the nonmuscle actins. The amino substitution patterns indicate that skeletal muscle actin is the highest differentiated actin form, whereas smooth muscle actins show a noticeably closer relation to nonmuscle actins. By these criteria cardiac muscle actin lies between skeletal muscle actin and smooth muscle actins.     

Identification of amino acid substitutions differentiating actin isoforms in their interaction with myosin

Various aspects of actin--myosin interaction were studied with actin preparations from two types of smooth muscle: bovine aorta and chicken gizzard, and from two types of sarcomeric muscle: bovine cardiac and rabbit skeletal. All four preparations activated the Mg2+-ATPase activity of skeletal muscle myosin to the same Vmax, but the Kapp for the smooth muscle preparations was higher. At low KCl, pH 8.0 and millimolar substrate concentrations the Kapp values differed by a factor of 2.5. This differential behaviour of the four actin preparations correlates with amino acid substitutions at positions 17 and 89 of actin polypeptide chain, differentiating the smooth-muscle-specific gamma and alpha isomers from cardiac and skeletal-muscle-specific alpha isomers. This correlation provides evidence for involvement of the NH2-terminal portion of the actin polypeptide chain in the interaction with myosin. The differences in the activation of myosin ATPase by various actins were sensitive to changes in the substrate and KCl concentration and pH of the assay medium. Addition of myosin subfragment-1 or heavy meromyosin in the absence of nucleotide produced similar changes in the fluorescence of a fluorescent reagent N-(1-pyrenyl)-iodoacetamide, attached at Cys-374, or 1,N6-ethenoadenosine 5'-diphosphate substituted for the bound ADP in actin protomers in gizzard and skeletal muscle F-actin. The results are consistent with an influence of the amino acid substitutions on ionic interactions leading to complex formation between actin and myosin intermediates in the ATPase cycle but not on the associated states.     

Vascular smooth muscle caldesmon

Caldesmon, a major actin- and calmodulin-binding protein, has been identified in diverse bovine tissues, including smooth and striated muscles and various nonmuscle tissues, by denaturing polyacrylamide gel electrophoresis of tissue homogenates and immunoblotting using rabbit anti-chicken gizzard caldesmon. Caldesmon was purified from vascular smooth muscle (bovine aorta) by heat treatment of a tissue homogenate, ion-exchange chromatography, and affinity chromatography on a column of immobilized calmodulin. The isolated protein shared many properties in common with chicken gizzard caldesmon: immunological cross-reactivity, Ca2+-dependent interaction with calmodulin, Ca2+-independent interaction with F-actin, competition between actin and calmodulin for caldesmon binding only in the presence of Ca2+, and inhibition of the actin-activated Mg2+-ATPase activity of smooth muscle myosin without affecting the phosphorylation state of myosin. Maximal binding of aorta caldesmon to actin occurred at 1 mol of caldesmon: 9-10 mol of actin, and binding was unaffected by tropomyosin. Half-maximal inhibition of the actin-activated myosin Mg2+-ATPase occurred at approximately 1 mol of caldesmon: 12 mol of actin. This inhibition was also unaffected by tropomyosin. Caldesmon had no effect on the Mg2+-ATPase activity of smooth muscle myosin in the absence of actin. Bovine aorta and chicken gizzard caldesmons differed in several respects: Mr (149,000 for bovine aorta caldesmon and 141,000 for chicken gizzard caldesmon), extinction coefficient (E1%280nm = 19.5 and 5.0 for bovine aorta and chicken gizzard caldesmon, respectively), amino acid composition, and one-dimensional peptide maps obtained by limited chymotryptic and Staphylococcus aureus V8 protease digestion. In a competitive enzyme-linked immunosorbent assay, using anti-chicken gizzard caldesmon, a 174-fold molar excess of bovine aorta caldesmon relative to chicken gizzard caldesmon was required for half-maximal inhibition. These studies establish the widespread tissue and species distribution of caldesmon and indicate that vascular smooth muscle caldesmon exhibits physicochemical differences yet structural and functional similarities to caldesmon isolated from chicken gizzard.     

Subcellular sorting of isoactins: selective association of gamma actin with skeletal muscle mitochondria

We describe two subpopulations of actin antibodies isolated by affinity chromatography from a polyclonal antibody to chicken gizzard actin. One subpopulation recognizes gamma actins from smooth muscle and nonmuscle cells, but does not recognize alpha actin from skeletal muscle. The other subpopulation recognizes determinants that are common to alpha actin from skeletal muscle and the two gamma actin isotypes. Neither antibody recognizes cytoplasmic beta actin. Both antibodies recognize only actins or molecules with determinants that are also present in actins. By immunofluorescence we found that the anti-gamma actin colocalizes with mitochondria in fibers of mouse diaphragm, and that it does not bind detectably to the 1 bands of sarcomeres. The antibody that recognizes both alpha and gamma actins stains 1 bands intensely, as expected. We interpret these observations as preliminary evidence for selective association of gamma actin with skeletal muscle mitochondria and, more broadly, as evidence for subcellular sorting of isoactins.     

Effects of various amino acid replacements on the conformational stability of G-actin

Circular dichroic spectra of native, EDTA-treated and heat-denatured G-actin from chicken gizzard smooth muscle are virtually the same as those of rabbit skeletal muscle actin. The rates of changes produced by EDTA or heat in the secondary structure are, however, higher in the case of gizzard actin. Similar differences were found in the rates of inactivation as measured by loss of polymerizability during incubation with EDTA or Dowex 50. The results are explicable in terms of local differences in the conformation at specific site(s) important for maintaining the native state of actin monomer. Involvement of the ATP binding site was shown by measuring the equilibrium constant for the binding of ATP to the two actins. Difference in the conformation of some additional site(s) is indicated by a higher rate constant of inactivation of nucleotide-free actin observed for gizzard actin. No significant difference was found in the equilibrium constant for the binding of Ca2+ at the single high-affinity site in gizzard and skeletal muscle actin. Comparison of inactivation kinetics of actin from chicken gizzard, rabbit skeletal, bovine aorta, and bovine cardiac muscle suggests that the amino acid replacements Val-17----Cys-17 and/or Thr-89----Ser-89 have a destabilizing effect on the native conformation of G-actin. The results indicate that deletion of the acidic residue at position 1 of the amino acid sequence has no effect on the conformation of the ATP binding site and the high-affinity site for divalent cation as well.     

Actin amino-acid sequences. Comparison of actins from calf thymus, bovine brain, and SV40-transformed mouse 3T3 cells with rabbit skeletal muscle actin.

Actin was purified from calf thymus, bovine brain and SV40-transformed mouse 3T3 cells grown in tissue culture. Isoelectric focusing analysis showed the presence of the two actin polypeptides beta and gamma typical for non-muscle actins in all three actins. Tryptic and thermolytic peptides accounting for the complete amino-acid sequence of the cytoplasmic actins were separated and isolated by preparative fingerprint techniques. All peptides were characterized by amino-acid analysis and compared with the corresponding peptides from rabbit skeletal muscle actin. Peptides which differed in amino-acid composition from the corresponding skeletal muscle actin peptides were subjected to sequence analysis in order to localize the amino-acid replacement. The results obtained show that all three mammalian cytoplasmic actins studied contain the same amino-acid exchanges indicating that mammalian cytoplasmic actins are very similar if not identical in amino-acid sequence. The presence of two different isoelectric species beta and gamma in cytoplasmic actins from higher vertebrates is acccounted for by the isolation of two very similar but not identical amino-terminal peptides in all three actin preparations. The nature of the amino-acid replacements in these two peptides not only accounts for the different isoelectric forms but also shows that beta and gamma cytoplasmic actins are the products of two different structural genes expressed in the same cell. The total number of amino-acid replacements so far detected in the comparison of these cytoplasmic actins and skeletal muscle actin is 25 for the beta chain and 24 for the gamma chain. With the exception of the amino-terminal three or four residues, which are responsible for the isoelectric differences, the replacements do not involve charged amino acids. The exchanges are not randomly distributed. No replacements were detected in regions 18--75 and 299--356 while the regions between residues 2--17 and 259--298 show a high number of replacements. In addition documentation for a few minor revisions of the amino acid sequence of rabbit skeletal muscle actin is provided.     

Chicken-gizzard actin. Interaction with skeletal-muscle myosin

Interaction of actin from chicken gizzard and from rabbit skeletal muscle with rabbit skeletal muscle myosin was compared by measuring the rate of superprecipitation, the activation of the Mg-ATPase and inhibition of K-ATPase activity of myosin and heavy meromyosin, and determination of binding of heavy meromyosin in the absence of ATP. Both the rate of superprecipitation of the hybrid actomyosin and the activation of myosin ATPase by gizzard actin are lower than those obtained with skeletal muscle actin. The activation of myosin Mg-ATPase by the two actin species also shows different dependence on substrate concentration: with gizzard actin the substrate inhibition starts at lower ATP concentration. The double-reciprocal plots of the Mg-ATPase activity of heavy meromyosin versus actin concentration yield the same value of the extrapolated ATPase activity at infinite actin concentration (V) for the two actins and nearly double the actin concentration needed to produce half-maximal activation (Kapp) in the case of gizzard actin. A corresponding difference in the abilities of the two actin species to inhibit the K-ATPase activity of heavy meromyosin in the absence of divalent cations was also observed. The results are discussed in terms of the effect of substitutions in the amino acid sequence of gizzard and skeletal muscle actins on their interaction with myosin.     

At least six different actins are expressed in a higher mammal: An analysis based on the amino acid sequence of the amino-terminal tryptic peptide

The protein chemical characterization of the amino-terminal tryptic peptide of actin from different bovine tissues shows that at least six different actin structural genes are expressed in this mammal.Unique amirio acid sequences are found for actin from skeletal muscle, for actin from heart muscle, for two different actin species from smooth muscle, and for two different actin species typical of non-muscle tissues such as brain and thymus. The presence of more than one actin species in the same tissue (e.g. nonmuscle tissues and smooth muscles) is demonstrated by different amino-terminal peptides which, however, are closely related. The actins from the sarcomeric muscles (e.g. skeletal muscle and heart muscle) show unique but extremely similar amino-terminal peptides. A limited comparison of bovine and avian actins involving smooth and skeletal muscles emphasizes that among higher vertebrates actin divergence involves tissue rather than species specificity.For the lower eukaryotic organism Physarum polycephalum a single actin amino-terminal peptide is found, indicating that only one actin species is present during the plasmodial stage. The amino acid sequence of this peptide although unique reveals a high degree of homology with the corresponding mammalian cytoplasmic actin peptides.Different actin extraction and purification procedures have been compared by the relative yields of the different amino-terminal peptides. The results indicate that the various actin species obtained by the current purification procedures are a true reflection of the actual actins present in the tissue. In addition we compare the resolution provided by either isoelectric focusing analysis of different actins or by the protein chemical characterization of the amino-terminal peptides of different actins. We show that the latter procedure is more suitable for recording changes in actin expression during evolution and differentiation.     

Characterization of chicken skeletal muscle myosin light chain kinase. Evidence for muscle-specific isozymes

Myosin light chain kinase purified from chicken white skeletal muscle (Mr = 150,000) was significantly larger than both rabbit skeletal (Mr = 87,000) and chicken gizzard smooth (Mr = 130,000) muscle myosin light chain kinases, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Km and Vmax values with rabbit or chicken skeletal, bovine cardiac, and chicken gizzard smooth muscle myosin P-light chains were very similar for the chicken and rabbit skeletal muscle myosin light chain kinases. In contrast, comparable Km and Vmax data for the chicken gizzard smooth muscle myosin light chain kinase showed that this enzyme was catalytically very different from the two skeletal muscle kinases. Affinity-purified antibodies to rabbit skeletal muscle myosin light chain kinase cross-reacted with chicken skeletal muscle myosin light chain kinase, but the titer of cross-reacting antibodies was approximately 20-fold less than the anti-rabbit skeletal muscle myosin light chain kinase titer. There was no detectable antibody cross-reactivity against chicken gizzard myosin light chain kinase. Proteolytic digestion followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis or high performance liquid chromatography showed that these enzymes are structurally very different with few, if any, overlapping peptides. These data suggest that, although chicken skeletal muscle myosin light chain kinase is catalytically very similar to rabbit skeletal muscle myosin light chain kinase, the two enzymes have different primary sequences. The two skeletal muscle myosin light chain kinases appear to be more similar to each other than either is to chicken gizzard smooth muscle myosin light chain kinase.     

Two distinct nonmuscle myosin-heavy-chain mRNAs are differentially expressed in various chicken tissues. Identification of a novel gene family of vertebrate non-sarcomeric myosin heavy chains

Two distinct cDNA clones for nonmuscle myosin heavy chain (MHC) were isolated from a chicken fibroblast cDNA library by cross-hydridization under a moderate stringency with chicken gizzard smooth muscle MHC cDNA. These two fibroblast MHC and the gizzard MHC are each encoded in different genes in the chicken genome. Northern blot analysis showed that both of the nonmuscle MHC mRNAs were expressed not only in fibroblasts but also in a variety of tissues including brain, lung, kidney, spleen, and skeletal, cardiac and smooth muscles. However, the relative contents of the two nonmuscle MHC mRNAs varied greatly among tissues. The encoded amino acid sequences of the nonmuscle MHCs were highly similar to each other (81% identity) and to the smooth muscle MHC (81-84%), but much less similar to vertebrate skeletal muscle MHCs (38-41%) or to protista nonmuscle MHCs (35-36%). A phylogenic tree of MHC isoforms was constructed by calculating the similarity scores between these MHC sequences. An examination of the tree showed that the vertebrate sarcomeric (skeletal and cardiac) MHC isoforms are encoded in a very closely related multigene family, and that the vertebrate non-sarcomeric (smooth muscle and nonmuscle) MHC isoforms define a distinct, less conserved MHC gene family.