Further characterization of a conserved actin-binding 27-kDa fragment of actinogelin and alpha-actinins and mapping of their binding sites on the actin molecule by chemical cross-linking

A conserved actin-binding domain (Mr = 27,000) of rat hepatic actinogelin, rat skeletal muscle, and chicken gizzard alpha-actinins (Mimura, N., and Asano, A. (1986) J. Biol. Chem. 261, 10680-10687) was separated into two components having different isoelectric points (peptides A and B) by chromatofocusing. Thermolysin digestion of peptide A generated peptide B with concomitant loss of peptide A. Amino acid compositions and tryptic maps of peptides A and B also demonstrated that peptide A is a precursor of peptide B upon thermolysin digestion. All of peptides A and B retained the activity to bind with F-actin competitively to each other. By the gel-filtration method, it was also shown that the native actin-binding 27-kDa fragments are monomeric and globular. The non-actin-binding 50- or 53.5-kDa fragment of actinogelin/alpha-actinins was, however, found to be asymmetric and dimeric in the native state. Chemical cross-linking of the 27-kDa fragment with F-actin with a water-soluble carbodiimide produced at least four different complexes (I-IV). Chemical cleaving analysis of the cross-linked products (complexes I and II) indicated that the 27-kDa fragment possesses two possible binding sites on actin at the NH2-terminal residues 1-12 (for complex I) and at residues spanning 86-119 or 123 (for complex II).     

Molecular properties and functions in vitro of chicken smooth-muscle alpha-actinin in comparison with those of striated-muscle alpha-actinins

alpha-Actinin purified from chicken gizzard smooth muscle was characterized in comparison with alpha-actinins from chicken striated muscles, or fast-skeletal muscle, slow-skeletal muscle, and cardiac muscle. The gizzard alpha-actinin molecule consisted of two apparently identical subunits with a molecular weight of 100,000 on SDS-polyacrylamide gel electrophoresis, as do striated-muscle alpha-actinins. Its isoelectric points in the presence of urea were similar to the striated-muscle counterparts. Despite these similarities, distinctive amino acid sequences between smooth-muscle alpha-actinin and striated-muscle alpha-actinins were revealed by peptide mapping using limited proteolysis in SDS. Gizzard alpha-actinin was immunologically distinguished from striated-muscle alpha-actinins. Gizzard alpha-actinin formed bundles of gizzard F-actin as well as of skeletal-muscle F-actin, but could not form any cross-bridges between adjacent actin filaments under conditions where skeletal-muscle alpha-actinin could. Temperature-dependent competition between gizzard alpha-actinin and tropomyosin on binding to gizzard thin filaments was demonstrated by electron microscopic observations. Gizzard alpha-actinin promoted Mg2+-ATPase activity of reconstituted skeletal actomyosin, gizzard acto-skeletal myosin, and gizzard actomyosin. This promoting effect was depressed by the addition of gizzard tropomyosin. These findings imply that, despite structural differences between gizzard and striated-muscle alpha-actinin molecules, they function similarly in vitro, and that gizzard alpha-actinin can interact not only with smooth-muscle actin (gamma- and beta-actin) but also with skeletal-muscle actin (alpha-actin).     

Purification and characterization of an alpha-actinin-like protein from porcine kidney

An alpha-actinin-like protein was partially purified from the Triton-insoluble cytoskeleton of porcine kidney by 0.6 M MgCl2 treatment, ammonium sulfate fractionation, DEAE-cellulose chromatography and hydroxyapatite chromatography. Apparent purity of the kidney protein was approximately 90% by quantitative densitometry of Coomassie-stained polyacrylamide gels. The kidney alpha-actinin-like protein is very similar to muscle alpha-actinins by the following criteria: (1) both kidney protein and muscle alpha-actinins bind to F-actin at a similar ratio; (2) both proteins demonstrate no difference in the actomyosin turbidity assay and the ATPase assay for alpha-actinin activity; (3) both native proteins contain a large core of identical molecular weight resistant to trypsin; (4) on two-dimensional gels, both kidney protein and muscle alpha-actinins have similar isoelectric points of 5.9-6.1. However, kidney alpha-actinin-like protein is not identical in every respect with muscle alpha-actinins. Electrophoretic mobility of the kidney protein is slightly greater than that of chicken gizzard alpha-actinin and is identical to that of a component of chicken skeletal muscle alpha-actinin. One-dimensional peptide mappings of the kidney protein and muscle alpha-actinins were significantly different from each other. The interaction between kidney alpha-actinin-like protein and F-actin is sensitive to Ca2+. Similar Ca2+-sensitivity was observed with other non-muscle cell alpha-actinins.     

A novel nonmuscle alpha-actinin. Purification and characterization of chicken lung alpha-actinin.

Two distinct alpha-actinin-like proteins were detected in chicken lung extract by immunoblot analysis with monoclonal antibodies against alpha-actinin. The mobilities of these proteins on SDS-polyacrylamide gel electrophoresis are very close (approximately 100 kDa). On SDS-polyacrylamide gel electrophoresis in the presence of 6 M urea, however, one of the proteins migrates at 115 kDa and is clearly separated from the other protein (105 kDa). The 115-kDa protein was purified and shown to have at least three unique amino acid sequences which were not detected in other kinds of alpha-actinins: one locates at the extreme NH2-terminal region, and the others locate at the COOH-terminal half region. Immunoblot and proteolytic cleavage analyses revealed that the 115-kDa protein has structural divergence at the COOH-terminal region that includes Ca(2+)-binding EF-hand motifs. Falling-ball viscometric studies showed that although the 115-kDa protein-induced gelation of F-actin is sensitive to Ca2+, the gelation activity of the 115-kDa protein is much higher than that of Ca(2+)-insensitive gizzard alpha-actinin regardless of Ca2+. This indicates that the 115-kDa protein is distinct from other nonmuscle alpha-actinins by its Ca2+ sensitivity.     

Purification and characterization of actinogelin, a calcium-sensitive actin-accessory protein, from rat liver

Although cell-free extracts prepared from several types of free-living cells, including Ehrlich tumor cells, macrophages and sea-urchin eggs, readily form gels under low Ca2+ conditions, no such ability to induce actin-related gel has been detected in tissue-cell extracts. Ca2+ -insensitive gelation activity was discovered, however, in several tissue-cell extracts, including liver and brain, provided that the extracts were supplemented with skeletal muscle actin. Based on sodium dodecylsulfate/polyacrylamide gel electrophoretic analysis of the gel, these extracts seem to contain both a Ca2+ -insensitive gelation factor and Ca2+ -sensitive one, actinogelin. A procedure for purification of actinogelin from rat liver was developed, and the properties of actinogelin thus purified were compared with those of Ehrlich tumor cell actinogelin. No appreciable difference was found in these two proteins, and Ca2+ sensitivity (50% inhibition of gelation at 1 microM) was very similar. Some of the molecular characteristics are described, and the importance of the presence of actinogelin in tissue cells is discussed.     

Purification, biological properties and partial sequence analysis of 67-kDa calcimedin and its 34-kDa fragment from chicken gizzard

Calcimedin is a group of proteins, originally isolated from chicken gizzard, which are able to bind to several hydrophobic matrices in the presence of Ca2+. Although the molecular properties have been partially discovered, the physiological functions of calcimedins have not yet been clearly defined. In this study, we describe the isolation and characterization of 67-kDa calcimedin and its 34-kDa fragment from chicken gizzard. Both structural and functional studies establish that 67-kDa calcimedin is a member of the calpactin/lipocortin family: it displays phospholipase A2 inhibitory activity, Ca2(+)-dependent F-actin binding and phospholipid binding activity similar to those of calpactins (lipocortins). By comparing the sequence of 67-kDa calcimedin with the predicted sequence of 67-kDa calelectrin, we concluded that the primary structure of these 67-kDa proteins is highly conserved. In particular, the sequences GLGTDEGAIIXVLTQR and EGAGTDESTLIEIMATR conform with the annexin consensus sequence which is characteristic of the calpactin/lipocortin family. A 34-kDa fragment of 67-kDa calcimedin was also purified and their relatedness has been confirmed by antibody cross-reactivity. The sequence data further support that the 34-kDa fragment is derived from the C-terminal portion of 67-kDa calcimedin by limited proteolysis. The 34-kDa fragment, which contains the annexin consensus sequence, preserves the phospholipase A2 inhibitory activity, and binds F-actin and phospholipids.     

Isolation, characterization and immunocytochemical localization of caldesmon-like protein from molluscan striated muscle

A 140-kDa polypeptide present in the striated muscle of Pecten maximus and Sepia officinalis was purified to homogeneity and its main properties were investigated using biochemical and cytochemical approaches. The protein was found to be similar to chicken gizzard caldesmon. It is a heat-stable protein. It cross-reacts immunologically with anti-(gizzard caldesmon) antibody, binds to calmodulin-Sepharose in a Ca2+-dependent manner, cosediments with F-actin filaments and acts in the absence and presence of tropomyosin as a potent inhibitor of rabbit skeletal actomyosin Mg2+-ATPase. The immunocytochemistry of ultrathin sections revealed, at the light microscopy resolution level, that caldesmon-like protein is present in all types of muscles hitherto examined from invertebrates and vertebrates. However, according to the distribution and the intensity of the fluorescent reaction, we concluded that, under our experimental conditions, caldesmon is not homogeneously distributed and not located in the myofibrillar bands of striated muscles but rather in the sarcoplasmic elements, at the periphery of the fibres.     

Interaction of actinogelin with actin. No nucleation but high gelation activity

Nucleation activity of actin polymerization of actinogelin, a calcium-sensitive F-actin cross-linking protein from rat liver, was measured by a fluorescence enhancement method using pyrenyl-actin and by high shear viscometry. No stimulation of nucleation by the addition of actinogelin was observed under several ionic conditions using the fluorescent method. Similar results were also obtained by viscometry. Therefore, it can be concluded that actinogelin has no nucleation activity for actin polymerization. By electron microscopy, it was found that actinogelin molecule has a dumbbell shape, binds to side of F-actin through its end(s), and cross-links actin filaments by binding with its two ends. It was also found that meshwork formation occurred in low Ca2+ conditions from F-actin and actinogelin. Under non-gelling high Ca2+ conditions, binding of actinogelin along the side of F-actin with its one end was still detected in accordance with the binding assay using ultracentrifugation and protein determination. Under low Ca2+ conditions, the critical gelling concentration of actinogelin measured by low shear viscometry at 20 degrees C was 6 micrograms/ml for 250 micrograms/ml of actin. Comparing this value with those of the other actin cross-linking proteins, it was found that actinogelin was one of proteins with the highest gelation activity. On the other hand, gelation activity of actinogelin in high Ca2+ conditions was one order of magnitude lower; more than 50 micrograms/ml of the protein was required for gelation. At 37 degrees C, gelation activity of actinogelin at low Ca2+ concentration was decreased to about a quarter of that at 20 degrees C, but this was still higher than that of gizzard alpha-actinin at 20 degrees C. Thus, role of actinogelin as an efficient and Ca2+-regulated cross-linker of microfilaments was substantiated.     

Characteristic structures of actin gels induced with hepatic actinogelin or with chicken gizzard alpha-actinin: implication for their function

We studied the properties of actinogelin, a Ca2+-regulated actin cross-linking protein isolated from Ehrlich tumor cells or rat liver. Chicken gizzard alpha-actinin was used as a Ca2+-insensitive control. Actinogelin, which has very high gelation activity under low Ca2+ conditions, was found using electron microscopic or fluorescence studies to induce formation of a characteristic structure in which actin filaments and bundles radiate to (or converge from) all directions from spot-like core structures. A similar structure was induced with actinogelin, even in the presence of 0.7 saturation of tropomyosin. No such structure was detected with actinogelin under high Ca2+ conditions, and only a few were found with gizzard alpha-actinin. Because reconstituted structures are similar to those observed intracellularly, actinogelin may be important in the formation of similar microfilament organization in the cells. It seems also important that these structures are reconstituted with only two purified protein components, i.e., actinogelin and actin. Immunocompetition studies showed that actinogelin and gizzard alpha-actinin partially shared antigenicity, and their molecular shape and peptide maps were similar. Their amino acid compositions [Kuo et al., 1982], subunit and domain structures, and binding sites on actin [Mimura and Asano, 1987] are also very similar. Therefore, it is concluded that actinogelin belongs to alpha-actinin superfamily proteins. Furthermore, the presence of functionally different subfamilies concerned with Ca2+ sensitivity, gelation-efficiency, and others is discussed. Actinogelin, which induces networks of actin filaments, may be classified as high gelation type.     

Domain mapping of chicken gizzard caldesmon

Limited proteolysis, affinity chromatography, and immunoblotting have been used to define the domains of chicken gizzard caldesmon, caldesmon120, that interact with calmodulin, F-actin, and a monoclonal antibody prepared using human platelet caldesmon. Treatment of caldesmon120 with chymotrypsin produces groups of fragments near 100, 80, 60, 38, and 20 kDa. Further digestion produces peptides between 40 and 50 kDa. The 100- and 80-kDa peptides cross-react with the monoclonal antibody; the smaller polypeptides do not. The kinetics of cleavage and the antibody studies indicate that the 38- and 80-kDa fragments are the two major pieces of the 120-kDa protein. The 38-kDa fragment, purified by high performance liquid chromatography, and several of its subfragments at 21 and 25 kDa sediment with F-actin, bind to calmodulin-Sepharose in the presence of Ca2+, and are displaced from F-actin by Ca2+-calmodulin. The 80-kDa fragments did not interact with F-actin or calmodulin. We have tentatively placed the 38-kDa fragment at the C-terminal using polyclonal antibodies selected against a beta-galactosidase-caldesmon120 fusion protein produced by a lambda gt11 lysogen. The 38-, 25-, and 21-kDa fragments cross-react with these antibodies; the 80- and 60-kDa fragments do not. Caldesmon77 from human platelets also cross-reacts with these selected antibodies. The results suggest that interacting calmodulin and F-actin binding sites are localized on a 38-kDa C-terminal fragment of caldesmon. The smallest subfragment of this peptide that binds to both F-actin and calmodulin-Sepharose is about 21 kDa. The monoclonal antibody epitope is tentatively localized near the N-terminal of caldesmon77 and must be within 50 kDa of the N-terminal on caldesmon120.     

Differential expression and distribution of chicken skeletal- and smooth-muscle-type alpha-actinins during myogenesis in culture

Antibodies to chicken fast skeletal muscle (pectoralis) alpha-actinin and to smooth muscle (gizzard) alpha-actinin were absorbed with opposite antigens by affinity chromatography, and four antibody fractions were thus obtained: common antibodies reactive with both pectoralis and gizzard alpha-actinins ([C]anti-P alpha-An and [C]anti-G alpha-An), antibody specifically reactive with pectoralis alpha-actinin ([S]anti-P alpha-An), and antibody specifically reactive with gizzard alpha-actinin ([S]anti-G alpha-An). In indirect immunofluorescence microscopy, (C)anti-P alpha-An, (S)anti-P alpha-An, and (C)anti-G alpha- An stained Z bands of skeletal muscle myofibrils, whereas (S)anti-G alpha-An did not. Although (S)anti-G alpha-An and two common antibodies stained smooth muscle cells, (S)anti-P alpha-An did not. We used (S)anti-P alpha-An and (S)anti-G alpha-An for immunofluorescence microscopy to investigate the expression and distribution of skeletal- and smooth-muscle-type alpha-actinins during myogenesis of cultured skeletal muscle cells. Skeletal-muscle-type alpha-actinin was found to be absent from myogenic cells before fusion but present in them after fusion, restricted to Z bodies or Z bands. Smooth-muscle-type alpha- actinin was present diffusely in the cytoplasm and on membrane- associated structures of mononucleated and fused myoblasts, and then confined to membrane-associated structures of myotubes. Immunoblotting and peptide mapping by limited proteolysis support the above results that skeletal-muscle-type alpha-actinin appears at the onset of fusion and that smooth-muscle-type alpha-actinin persists throughout the myogenesis. These results indicate (a) that the timing of expression of skeletal-muscle-type alpha-actinin is under regulation coordination with other major skeletal muscle proteins; (b) that, with respect to expression and distribution, skeletal-muscle-type alpha-actinin is closely related to alpha-actin, whereas smooth-muscle-type alpha- actinin is to gamma- and beta-actins; and (c) that skeletal- and smooth- muscle-type alpha-actinins have complementary distribution and do not co-exist in situ.     

Substructure and higher structure of chicken smooth muscle alpha-actinin molecule

Substructure of chicken gizzard smooth muscle alpha-actinin molecule was deduced by domainal mapping of the proteolytic fragments with alpha-chymotrypsin. There were three chymotryptic cleavage sites (Sites I, II, and III, from the amino terminus). Cleavage at Site I generated two fragments, i.e. an NH2-terminal 36-kDa fragment and a COOH-terminal 70-kDa fragment. The 70-kDa fragment generated either a 55-kDa fragment by cleavage at Site II or a 65-kDa fragment by cleavage at Site III. Purified NH2-terminal 36-kDa fragment bound to F-actin, whereas the 55-kDa fragment formed a dimeric molecule. Circular dichroism and electron microscopic experiments demonstrated that the alpha-helical content of the 55-kDa fragment was 14% higher than that of native gizzard alpha-actinin, coinciding with the apparently rod-shaped configuration of this fragment. A 110-kDa product was generated from two 55-kDa fragments in a cross-linking study with the zero-length cross-linker 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. Two cross-linkable sites in the 55-kDa, A- and B-site, were shown to be involved in this reaction. Further, it was demonstrated by using N-(7-dimethylamino-4-methyl-3-coumarinyl)maleimide labeling and immunoblotting analyses that the A-site on one 55-kDa fragment was cross-linked to the B-site on the other. These results suggest that smooth muscle alpha-actinin formed an antiparallel dimeric molecule in which the 55-kDa fragments connected the two actin-binding domains composed of the 36-kDa fragments.     

Characterization of the carboxyl-terminal 10-kDa cyanogen bromide fragment of caldesmon as an actin-calmodulin-binding region

A pair of 10-kDa peptides, designated CB-a and CB-b, was isolated by calmodulin-Sepharose chromatography from a total CNBr digest of turkey gizzard caldesmon. CB-a encompasses the COOH-terminal segment of residues 659-756, according to the sequence of adult chicken gizzard caldesmon (Bryan, J., Imai, M., Lee, R., Moore, P., Cook, R.G., and Lin, W.G. (1989) J. Biol. Chem. 264, 13873-13879), whereas CB-b comprises the same structure but was a few amino acids shorter at its COOH terminus. Both peptides cosedimented with F-actin, and their binding was increased by smooth muscle tropomyosin. The Kd values were 1.3 and 0.5 microM, in the absence and presence of tropomyosin, respectively, with a maximum binding capacity of 6.9 actins/mol of peptides. The CB-a/CB-b fragments inhibited, in a tropomyosin-sensitive and Ca2(+)-calmodulin-dependent manner, the skeletal actomyosin subfragment 1 ATPase activity to a level close but not identical to that observed for the parent caldesmon. Ca2(+)-calmodulin was selectively cross-linked to either caldesmon or the CNBr peptides with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide producing 1:1 covalent complexes that were retained neither by phenyl-Sepharose nor by immobilized calmodulin. Moreover, the cross-linked caldesmon bound weakly to F-actin and did not inhibit the actomyosin subfragment 1 ATPase in the absence of Ca2+. The results suggest that the CB-a/CB-b peptide region contains major regulatory determinants of caldesmon.     

Primary structure of chicken skeletal muscle and fibroblast alpha-actinins deduced from cDNA sequences

The complete 897-amino-acid sequence of chicken skeletal muscle alpha-actinin and the 856-amino-acid sequence (97% of the entire sequence) of chicken fibroblast alpha-actinin have been determined by cloning and sequencing the cDNAs. Genomic Southern analysis with the cDNA sequences shows that skeletal and fibroblast alpha-actinins are encoded by separate single-copy genes. RNA blot analyzes show that the skeletal alpha-actinin gene is expressed in the pectoralis muscle and that the fibroblast gene is expressed in the gizzard smooth muscle as well as in the fibroblast. The deduced skeletal alpha-actinin molecule has a calculated Mr of 104 x 10(3), and each alpha-actinin can be divided into three domains: (1) the NH2-terminal highly conserved actin-binding domain, which shows similarity to the product of the Duchenne's muscular dystrophy locus; (2) the middle rod-shaped dimer-forming domain, which contains the spectrin-type repeat units; and (3) the COOH-terminal two EF-hand consensus regions. Comparison of the skeletal alpha-actinin sequence with the fibroblast and smooth muscle alpha-actinin sequences demonstrated that the EF-hand structure was conserved in all of these alpha-actinin sequences, despite the reported variability of the Ca2+ sensitivities of the actin-gelation by various alpha-actinin isoforms.     

Monoclonal antibodies against 5'-nucleotidase from chicken gizzard. Evidence for species and tissue specific differences of 5'-nucleotidase

5'-Nucleotidase from chicken gizzard smooth muscle was purified to homogeneity and used as immunogen for generating monoclonal antibodies. From about 150 positive clones nine IgG producing hybridoma cell lines have been selected for further characterization and antibody preparation. The resulting antibodies bind 5'-nucleotidase from chicken smooth muscle, chicken skeletal muscle, and chicken heart muscle but not the enzyme from chicken liver or rat liver. It could clearly be demonstrated that the nine antibodies recognize different antigenic determinants. Four of these antibodies are strong inhibitors of the AMPase activity of 5'-nucleotidase. One antibody is a weak inhibitor and four other antibodies have no effect on its enzymic activity. One of the monoclonal antibodies was used for immunoaffinity purification of 5'-nucleotidase from chicken heart muscle and chicken skeletal muscle. Pure and active enzymes could be isolated from detergent extracts in one step with a 10 to 20-fold higher yield compared to classical purification procedures. The subcellular distribution of 5'-nucleotidase in chicken gizzard was investigated using indirect immunofluorescence. We found a staining of the plasma membrane of smooth muscle cells and endothelial cells by all of the nine antibodies with variations in the staining intensity.     

Transfection of chicken skeletal muscle alpha-actinin cDNA into nonmuscle and myogenic cells: dimerization is not essential for alpha-actinin to bind to microfilaments.

alpha-Actinins from striated muscle, smooth muscle, and nonmuscle cells are distinctive in their primary structure and Ca2+ sensitivity for the binding to F-actin. We isolated alpha-actinin cDNA clones from a cDNA library constructed from poly(A)+ RNA of embryonic chicken skeletal muscle. The amino acid sequence deduced from the nucleotide sequence of these cDNAs was identical to that of adult chicken skeletal muscle alpha-actinin. To examine whether the differences in the structure and Ca2+ sensitivity of alpha-actinin molecules from various tissues are responsible for their tissue-specific localization, the cDNA cloned into a mammarian expression vector was transfected into cell lines of mouse fibroblasts and skeletal muscle myoblasts. Immunofluorescence microscopy located the exogenous alpha-actinin by use of an antibody specific for skeletal muscle alpha-actinin. When the protein was expressed at moderate levels, it coexisted with endogenous alpha-actinin in microfilament bundles in the fibroblasts or myoblasts and in Z-bands of sarcomeres in the myotubes. These results indicate that Ca2+ sensitivity or insensitivity of the molecules does not determine the tissue-specific localization. In the cells expressing high levels of the exogenous protein, however, the protein was diffusely present and few microfilament bundles were found. Transfection with cDNAs deleted in their 3' portions showed that the expressed truncated proteins, which contained the actin-binding domain but lacked the domain responsible for dimerization, were able to localize, though less efficiently in microfilament bundles. Thus, dimer formation is not essential for alpha-actinin molecules to bind to microfilaments.     

Tropomyosin from smooth and skeletal muscles initiates various conformational changes in skeletal F-actin

Changes in F-actin conformation in myosin-free single ghost fibers of rabbit skeletal muscle induced by the binding of skeletal and gizzard tropomyosin to F-actin were studied by measuring intrinsic tryptophan-polarized fluorescence of F-actin. It was found that skeletal and gizzard tropomyosin binding to F-actin initiate different conformational changes in actin filaments. Skeletal tropomyosin inhibits, while gizzard tropomyosin activates the Mg2+-ATPase activity of skeletal actomyosin. It is supposed that in muscle fibers tropomyosin modulates the ATPase activity of actomyosin via conformational changes in F-actin.     

Localization of the calmodulin- and the actin-binding sites of caldesmon

Expression of the C-terminal third of chicken gizzard caldesmon in Escherichia coli, using the Nagai vector (Nagai, K., and Th?gersen, H.V. (1987) Methods Enzmol. 153, 461-481), produces a cII-caldesmon fusion protein (27 kDa) with caldesmon sequence beginning at Lys579. Degradation during purification yields five peptides with molecular masses of 24, 22, 19 (two peptides), and 15 kDa. The 24-kDa peptide begins at Phe581; the 22-kDa peptide begins at Leu597, the two 19-kDa peptides begin at Phe581 and Val629, respectively; the 15-kDa peptide also begins at Val629. We estimate that the 15-kDa and one of the 19-kDa peptides end near Leu710. Site-directed mutagenesis was used to produce truncated peptides with known C termini; one peptide (17 kDa) terminates at Asn675. Digestion of the fragments with chymotrypsin generates a second 15-kDa fragment that begins at Ser666 (15K'). All of the peptides, with the exception of 15K', bind Ca(2+)-calmodulin-Sepharose and share a common 37-amino acid peptide between Val629 and Ser666, suggesting this contains the calmodulin binding site. Comparison with published sequences (Takagi, T., Yazawa, M., Ueno, T., Suzuki, S., and Yagi, K. (1989) J. Biochem. (Tokyo) 106, 778-783 and Bartegi, A., Fattoum, A., Derancourt, J., and Kassab, R. (1990) J. Biol. Chem. 265, 15231-15238) for other calmodulin-binding fragments further restricts the binding site to 7 residues, Trp-Glu-Lys-Gly-Asn-Val-Phe, between Trp659 and Ser666. All of the fragments, except the two 15-kDa peptides, co-sediment with F-actin, indicating that there are two segments in the C-terminal third of caldesmon that can interact with F-actin: one between Leu597 and Val629, the other between Arg711 and Pro756. Although separated in the primary sequence, these domains may interact with the calmodulin-binding region in the folded structure.     

Comparison of the effects of smooth and skeletal muscle actins on smooth muscle actomyosin Mg2+-ATPase

Actin has been purified from smooth muscle (chicken gizzard) by two different procedures and its activation of smooth muscle myosin Mg2+-ATPase activity compared with that achieved with rabbit skeletal muscle actin. The procedure of Pardee and Spudich (Methods Enzymol. (1982) 85, 164-181) for the purification of rabbit skeletal muscle actin is readily applicable to the isolation of chicken gizzard actin, enabling large quantities to be purified in two days. Smooth muscle actin could be successfully stored as F-actin at -80 degrees C and survived freezing and thawing at least twice. Smooth muscle actin activated myosin Mg2+-ATPase to a higher level than its skeletal muscle counterpart (77.9 nmol Pi/min/mg myosin vs 48.1 nmol Pi/min/mg myosin).     

Mapping of the functional domains in the amino-terminal region of calponin.

Three chymotryptic fragments accounting for almost the entire amino acid sequence of gizzard calponin (Takahashi, K., and Nadal-Ginard, B. (1991) J. Biol. Chem. 266, 13284-13288) were isolated and characterized. They encompass the segments of residues 7-144 (NH2-terminal 13-kDa peptide), 7-182 (NH2-terminal 22-kDa peptide), and 183-292 (COOH-terminal 13-kDa peptide). They arise from the sequential hydrolysis of the peptide bonds at Tyr182-Gly183 and Tyr144-Ala145 which were protected by the binding of F-actin to calponin. Only the NH2-terminal 13- and 22-kDa fragments were retained by immobilized Ca(2+)-calmodulin, but only the larger 22 kDa entity cosedimented with F-actin and inhibited, in the absence of Ca(2+)-calmodulin, the skeletal actomyosin subfragment-1 ATPase activity as the intact calponin. Since the latter peptide differs from the NH2-terminal 13-kDa fragment by a COOH-terminal 38-residue extension, this difference segment appears to contain the actin-binding domain of calponin. Zero-length cross-linked complexes of F-actin and either calponin or its 22-kDa peptide were produced. The total CNBr digest of the F-actin-calponin conjugate was fractionated over immobilized calmodulin. The EGTA-eluted pair of cross-linked actin-calponin peptides was composed of the COOH-terminal actin segment of residues 326-355 joined to the NH2-terminal calponin region of residues 52-168 which seems to contain the major determinants for F-actin and Ca(2+)-calmodulin binding.