Microinjection of nonmuscle and smooth muscle caldesmon into fibroblasts and muscle cells

Caldesmon is present in a high molecular mass form in smooth muscle and predominantly in a low molecular mass form in nonmuscle cells. Their biochemical properties are very similar. To examine whether these two forms of caldesmon behave differently in cultured cells, we microinjected fluorescently labeled smooth muscle and nonmuscle caldesmons into fibroblasts. Simultaneous injection of both caldesmons into the same cells has revealed that both high and low relative molecular mass caldesmons are quickly (within 10 min) and stably (over 3 d) incorporated into the same structures of microfilaments including stress fibers and membrane ruffles, suggesting that nonmuscle cells do not distinguish nonmuscle caldesmon from smooth muscle caldesmon. The effect of calmodulin on the incorporation of caldesmon has been examined by coinjection of caldesmon with calmodulin. We have found that calmodulin retards the incorporation of caldesmon into stress fibers for a short period (10 min) but not for a longer incubation (30 min). The behavior of caldesmon in developing muscle cells was also examined because we previously observed that caldesmon disappears during myogenesis (Yamashiro, S., R. Ishikawa, and F. Matsumura. 1988. Protoplasma Suppl. 2: 9-21). We have found that, in contrast to its stable incorporation into stress fibers of fibroblasts, caldesmon is unable to be incorporated into thin filament structure (I-band) of differentiated muscle.     

Caldesmon. Molecular weight and subunit composition by analytical ultracentrifugation

A wide range of values has been reported for the subunit and molecular weights of smooth muscle caldesmon. There have also been conflicting reports concerning whether caldesmon is a monomer or dimer. We attempted to resolve these uncertainties by determining the molecular weight of chicken gizzard smooth muscle caldesmon using the technique of sedimentation equilibrium in the analytical ultracentrifuge. Unlike previous methods that have been used to estimate the molecular weight of caldesmon, the molecular weight determined by equilibrium sedimentation does not depend upon assumptions about the shape of the molecule. We concluded that caldesmon in solution is monomeric with a molecular mass of 93 +/- 4 kDa, a value that is much less than those previously reported in the literature. This new value, in conjunction with sedimentation velocity experiments, led to the conclusion that caldesmon is a highly asymmetric molecule with an apparent length of 740 A in solution. The mass of a cyanogen bromide fragment, with an apparent mass of 37 kDa from sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was determined to be 25.1 +/- 0.6 kDa using sedimentation equilibrium. These results imply that the reported molecular weights of other fragment(s) of caldesmon have also been overestimated. We have determined an optical extinction coefficient for caldesmon (E1%(280 nm) = 3.3) by determining its concentration from its refractive index which was measured in the analytical ultracentrifuge. From the above values of the molecular weight and the extinction coefficient, we redetermined that the caldesmon molecule has two cysteines and recalculated the stoichiometric molar ratio of actin/tropomyosin/caldesmon in the smooth muscle thin filament to be 28:4:1.     

Characterization of 83-kilodalton nonmuscle caldesmon from cultured rat cells: stimulation of actin binding of nonmuscle tropomyosin and periodic localization along microfilaments like tropomyosin

Nonmuscle caldesmon purified from cultured rat cells shows a molecular weight of 83,000 on SDS gels, Stokes radius of 60.5 A, and sedimentation coefficient (S20,w) of 3.5 in the presence of reducing agents. These values give a native molecular weight of 87,000 and a frictional ratio of 2.04, suggesting that the molecule is a monomeric, asymmetric protein. In the absence of reducing agents, the protein is self-associated, through disulfide bonds, into oligomers with a molecular weight of 230,000 on SDS gels. These S-S oligomers appear to be responsible for the actin-bundling activity of nonmuscle caldesmon in the absence of reducing agents. Actin binding is saturated at a molar ratio of one 83-kD protein to six actins with an apparent binding constant of 5 X 10(6) M-1. Because of 83-kD nonmuscle caldesmon and tropomyosin are colocalized in stress fibers of cultured cells, we have examined effects of 83-kD protein on the actin binding of cultured cell tropomyosin. Of five isoforms of cultured rat cell tropomyosin, tropomyosin isoforms with high molecular weight values (40,000 and 36,500) show higher affinity to actin than do tropomyosin isoforms with low molecular weight values (32,400 and 32,000) (Matsumura, F., and S. Yamashiro-Matsumura. 1986. J. Biol. Chem. 260:13851-13859). At physiological concentration of KCl (100 mM), 83-kD nonmuscle caldesmon stimulates binding of low molecular weight tropomyosins to actin and increases the apparent binding constant (Ka from 4.4 X 10(5) to 1.5 X 10(6) M-1. In contrast, 83-kD protein has slight stimulation of actin binding of high molecular weight tropomyosins because high molecular weight tropomyosins bind to actin strongly in this condition. As the binding of 83-kD protein to actin is regulated by calcium/calmodulin, 83-kD protein regulates the binding of low molecular weight tropomyosins to actin in a calcium/calmodulin-dependent way. Using monoclonal antibodies to visualize nonmuscle caldesmon along microfilaments or actin filaments reconstituted with purified 83-kD protein, we demonstrate that 83-kD nonmuscle caldesmon is localized periodically along microfilaments or actin filaments with similar periodicity (36 +/- 4 nm) as tropomyosin. These results suggest that 83-kD protein plays an important role in the organization of microfilaments, as well as the control of the motility, through the regulation of the binding of tropomyosin to actin.     

Purification of caldesmon and myosin light chain (MLC) kinase from arterial smooth muscle: comparisons with gizzard caldesmon and MLC kinase

We have developed a simple and conventional purification method for caldesmon and MLC kinase from bovine arterial smooth muscle, and compared the arterial and gizzard proteins. Arterial caldesmon shares the alternative binding to calmodulin or F-actin in a Ca2+-dependent manner and the antigenic determinants with the gizzard protein. Both caldesmons have the same association constant with F-actin (1.3-1.7 X 10(7) M-1) and the same maximum binding (1 caldesmon per 12-14 actins). However, the molecular weight of arterial caldesmon (dimer of a 148 kDa polypeptides) was slightly different from that of gizzard caldesmon (heterodimer of 150/147 kDa polypeptides). The molecular weight of arterial MLC kinase (160 kDa) was much larger than that of the gizzard enzyme (135 kDa). The enzyme activities of both MLC kinases were comparable (Km = 9.5 microM, Vmax = 12.5 mumol/min X mg). The association constant of the arterial enzyme to F-actin (5.1 X 10(6) M-1) was much larger than that of the gizzard enzyme (9.0 X 10(5) M-1) but the maximum binding was the same (1 enzyme per 12-13 actins). Immunocytochemical examinations showed that caldesmon and MLC kinase in cultured arterial cells have a restricted localization along the stress fibers, suggesting functional linkages between both proteins and actin filaments in vivo.     

Turkey gizzard caldesmon: molecular weight determination and calmodulin binding studies

Sedimentation equilibrium and sedimentation velocity measurements demonstrate that turkey gizzard caldesmon is an elongated molecule of molecular mass 75 +/- 2 kDa. The frictional ratio (2.14) is consistent with a prolate ellipsoid of axial ratio 24, corresponding to an apparent length and width of 516 and 21.5 A, respectively. As was previously determined for chicken gizzard caldesmon [Graceffa, P., Wang, C.-L.A., & Stafford, W.F. (1988) J. Biol. Chem. 263, 14196-14202], this molecular weight is appreciably smaller than the value (approximately 135,000) estimated from the results of NaDodSO4 gel electrophoresis experiments. However, a significant difference between the true molecular weights of turkey and chicken gizzard caldesmons--75,000 versus 93,000--also points to probable molecular weight variations within the subclass. Binding measurements, based on perturbation of the intrinsic tryptophan fluorescence of caldesmon in the presence of calmodulin, show that the interaction between the two proteins is strongly ionic strength and temperature dependent. Dissociation constants of 0.075 and 0.38 microM were determined in solutions containing 0.1 and 0.2 M KCl, respectively, at 24.3 degrees C. Fluorescence emission spectra and fluorescence anisotropy excitation spectra indicate that the tryptophanyl residues of caldesmon are located in solvent-accessible regions of the molecule, where they exhibit a high degree of mobility even when calmodulin is bound.     

Differential modulation of actin-severing activity of gelsolin by multiple isoforms of cultured rat cell tropomyosin. Potentiation of protective ability of tropomyosins by 83-kDa nonmuscle caldesmon

Multiple isoforms of tropomyosin (TM) of rat cultured cells show differential effects on actin-severing activity of gelsolin. Flow birefringence measurements have revealed that tropomyosin isoforms with high Mr values (high Mr TMs) partially protect actin filaments from fragmentation by gelsolin, while tropomyosins with low Mr values (low Mr TMs) have no significant protection even when the actin filaments have been fully saturated with low Mr TMs. We have also examined effect of nonmuscle caldesmon on the severing activity of gelsolin because 83-kDa nonmuscle caldesmon stimulates actin binding of rat cell TMs (Yamashiro-Matsumura, S., and Matsumura, F. (1988) J. Cell Biol. 106, 1973-1983). While nonmuscle caldesmon alone or low Mr TMs alone show no significant protection against fragmentation by gelsolin, the low Mr TMs coupled with 83-kDa protein are able to protect actin filaments. Further, high Mr TMs together with 83-kDa protein appear to block the severing activity completely. Electron microscopic analyses of length distribution of actin filaments have confirmed the results. The average length of control actin filaments is measured as 1.46 +/- microns, and gelsolin shortens the average length to 0.084 +/- 0.039 micron. Similar short average lengths are obtained when gelsolin severs actin complexed with low Mr TMs (0.080 +/- 0.045 micron) or with nonmuscle caldesmon (0.11 +/- 0.072 micron) while longer average length (0.22 +/- 0.18 micron) is measured in the presence of high Mr TMs. The simultaneous addition of nonmuscle caldesmon makes the average length considerably longer, i.e. 0.61 +/- 0.37 micron in the presence of low Mr TMs and 1.57 +/- 0.97 micron in the presence of high Mr TMs. Furthermore, the actin binding of gelsolin is strongly inhibited by co-addition of high Mr TMs and nonmuscle caldesmon. These results suggest that TM and gelsolin share the same binding site on actin molecules and that the differences in the actin affinities between TMs are related to their abilities of protection against gelsolin.     

Cloning and expression of a smooth muscle caldesmon

Caldesmon is a smooth muscle and nonmuscle regulatory protein that interacts with actin, myosin, tropomyosin, and calmodulin. Two overlapping clones, isolated from a chicken oviduct cDNA plasmid library and a chicken gizzard cDNA lambda NM1149 library, were used to generate a 4108-base pair sequence coding for one caldesmon. Expression of the coding sequence confirms this is one of the large smooth muscle caldesmons. The deduced protein molecular weight is 86.974, significantly less than the molecular weights estimated by sodium dodecyl sulfate gel electrophoresis. The protein has a high content of Gly, Lys, Arg, and Ala; there are two cysteine residues, one at either end of the molecule. Comparison with the Protein Identification Resource database demonstrates a similarity with a tropomyosin binding domain of troponin T, but none with any calmodulin or actin binding proteins. The center of the protein has an 8-fold repeat of a 13 amino acid sequence whose general motif is -Glu3-(Lys/Arg)2-Ala2-Glu2-(Lys/Arg)1-X-(Lys/Arg)1-Ala1-, where X is Glu, Gln, or Ala. Comparison with peptide sequences from a chymotryptic fragment that binds actin and calmodulin places this domain on the C terminus of caldesmon adjacent to the troponin T similarity. A tentative map of the major binding domains is proposed on the basis of available data.     

Caldesmon: a common actin-linked regulatory protein in the smooth muscle and nonmuscle contractile system

Caldesmon was originally purified from gizzard smooth muscle as a major calmodulin-binding protein which also interacts with actin filaments. It has an alternative binding ability to either calmodulin or actin filaments depending upon the concentration of Ca2+ ("flip-flop binding"). Two forms of caldesmon (Mr's in the range of 120-150 kDa and 70-80 kDa) have been demonstrated in a wide variety of smooth muscles and nonmuscle cells. Immunohistochemical studies suggest that caldesmon is colocalized with actin filaments in vivo. Considering its abundance, the Ca2+-dependent flip-flop binding ability to either calmodulin or actin filaments, and its intracellular localization, caldesmon is expected to be involved in contractile events. Recent results from our laboratory have led to the conclusion that caldesmon regulates the smooth muscle and nonmuscle actin-myosin interaction and the smooth muscle actin-high Mr actin-binding protein (ABP or filamin) interactin in a flip-flop manner. It might function in cell motility by regulating the contractile system.     

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.     

Embryonic chicken gizzard: expression of the smooth muscle regulatory proteins caldesmon and myosin light chain kinase

The patterns of expression of the smooth muscle regulatory proteins caldesmon and myosin light chain kinase were investigated in the developing chicken gizzard. Immunofluorescent studies revealed that both proteins were expressed as early as E5 throughout the mesodermal gizzard anlage, together with actin, -actinin and a small amount of nonmuscle myosin. These proteins appear to form the scaffold for smooth muscle development, defined by the onset of smooth muscle myosin expression. During E6, a period of extensive cell division, smooth muscle myosin begins to appear in the musculi laterales close to the serosal border and, later, also in the musculi intermedii. Until about E10, myosin reactivity expands into the pre-existing thin filament scaffold. Later in development, the contractile and regulatory proteins co-localize and show a regular uniform staining pattern comparable to that seen in adult tissue. By using immunoblotting techniques, the low-molecular mass form of caldesmon and myosin light chain kinase were detected as early as E5. During further development, the expression of caldesmon switched from the low-molecular mass to the high-molecular mass form; in neonatal and adult tissue, high-molecular mass caldesmon was the only isoform expressed. The level of expression of myosin light chain kinase increased continously during embryonic development, but no embryospecific isoform with a different molecular mass was detected.     

Purification and characterization of calmodulin-dependent multifunctional protein kinase from smooth muscle: isolation of caldesmon kinase

Previously, it was reported that smooth muscle caldesmon is a protein kinase and is autophosphorylated [Scott-Woo, G.C., & Walsh, M.P. (1988) Biochem. J. 252, 463-472]. We separated a Ca2+/calmodulin-dependent protein kinase from caldesmon in the presence of 15 mM MgCl2. The Ca2+/calmodulin-dependent caldesmon kinase was purified by using a series of liquid chromatography steps and was characterized. The subunit molecular weight (MW) of the kinase was 56K by SDS gel electrophoresis and was autophosphorylated. After the autophosphorylation, the kinase became active even in the absence of Ca2+/calmodulin. The substrate specificity of caldesmon kinase was similar to the rat brain calmodulin-dependent multifunctional protein kinase II (CaM PK-II) and phosphorylated brain synapsin and smooth muscle 20-kDa myosin light chain. The purified kinase bound to caldesmon, and the binding was abolished in the presence of high MgCl2. Enzymological parameters were measured for smooth muscle caldesmon kinase, and these were KCaM = 32 nM, KATP = 12 microM, Kcaldesmon = 4.9 microM, and KMg2+ = 1.1 mM. Optimum pH was 7.5-9.5. The observed properties were similar to brain CaM PK-II, and, therefore, it was concluded that smooth muscle caldesmon kinase is the isozyme of CaM PK-II in smooth muscle.     

Conformational change of turkey-gizzard caldesmon induced by specific chemical modification with carbodiimide

Water soluble 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide was used to internally cross-link carboxyl and lysyl groups of caldesmon. The modification did not involve the two cysteines of the molecule which were previously labelled with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine. The modified caldesmon exhibited a smaller Stokes radius (4.0 nm instead of 6.3 nm) and its electrophoretic mobility corresponded to an apparent molecular mass of approximately 82 kDa, appreciably lower than that of the native molecule (120 kDa), but more similar to the reported true molecular mass of 86,974 Da of chicken-gizzard caldesmon (Bryan, J., Imai, M., Lee, R., Moore, P., Cook. R. G. & Lin, W. (1989) J. Biol. Chem. 264, 13,873-13,879). Comparative circular dichroism analysis indicated a decrease of the alpha-helix content from 43% to 36% resulting from the chemical modification. The 1H-NMR spectra of the native and modified caldesmon showed that the covalent cross-linking affected mainly the central and N-terminal parts of the molecule. The C-terminal part, rich in aromatic amino acids, was unmodified by the carbodiimide treatment. This was also corroborated by the continued ability of the modified caldesmon to bind to actin and calmodulin, and by the property of the 90-kDa proteolytic N-terminal fragment to give an internally cross-linked species of 60 kDa. Using electron microscopy, the modified protein was shown to have a more compact shape and a reduced capacity to induce tight and long F-actin bundles. These conformational changes were obtained when the carbodiimide reaction was conducted at pH 6.0 and were not observed at pH 8.0. This suggests that local variation of the pH might affect the conformation of caldesmon which changes from an elongated to more compact shape, stabilized by electrostatic interactions. It is proposed that the flexibility of caldesmon might be involved in the regulatory function of this protein in the smooth muscle and might favour tightly packed F-actin bundles or weaker interactions between actin filaments.     

Mapping of caldesmon: relationship between the high and low molecular weight forms

Caldesmon is a widely distributed contractile protein that occurs in both a high molecular weight [120-150-kilodalton (kDa)] and a low molecular weight (71-80-kDa) form, depending on the tissue. The structural relationship between these two forms was examined by mapping techniques. Partial cyanogen bromide cleavage in conjunction with sodium dodecyl sulfate gel electrophoresis was used to construct a map of the cleavage points and determine the relative position of the fragments in a high molecular weight caldesmon from chicken gizzard (caldesmon125). By use of this map, markers for different regions of the protein were obtained: Antibodies directed toward certain areas were prepared by affinity purification, and specific 125I-labeled tryptic peptides were found to originate from terminal cyanogen bromide fragments. Mapping of a lower molecular weight form of caldesmon (caldesmon72 from chicken liver) revealed the presence of sequences located in both ends of caldesmon125. A terminal 38-kDa fragment of both proteins was apparently identical on the basis of arrangement of cleavage sites, antibody reactivity, and iodopeptide mapping. Fragments from the other end of both proteins exhibited an identical pattern of peptides. These results show that it is sequences located in the central area of caldesmon125 which are missing in caldesmon72, indicating that the smaller molecule is not simply a proteolytic product of the larger. The two forms of caldesmon may be derived from separate genes or by alternative splicing from a single gene.     

Nonmuscle caldesmon: its distribution and involvement in various cellular processes

Summary. Smooth muscle caldesmon is a thin-filament constituent which takes part in the Ca²⁺-dependent regulation of actomyosin motor activity which converts chemical energy of ATP into force. The molecular anatomy of its counterpart found in a variety of nonmuscle cells is similar. Both contain about 20nm long terminal domains responsible for functionally important multisite interactions with filamentous actin, tropomyosin, Ca²⁺/calmodulin, and myosin and differ by a 35nm long central, -helical fragment which is lacking in nonmuscle caldesmon. The different structural organisation of nonmuscle cells and thus distinct distribution of caldesmon implicates its different physiological functions. Due to direct interaction with globular and filamentous actin as well as with tropomyosin, nonmuscle caldesmon is involved in the assembly, dynamics, or stability of microfilaments, whereas the indirect inhibitory effect on interaction of the microfilaments with myosin causes its participation in the regulation of cell contraction and intracellular motional processes. These functions of nonmuscle caldesmon of vertebrates are controlled by Ca²⁺/calmodulin (or other Ca²⁺-binding proteins) or caldesmon phosphorylation catalysed by various protein kinases. Examples of nonmuscle caldesmon involvement in functions of higher and lower eukaryote, animal and plant cells are presented.Correspondence and reprints: Department of Muscle Biochemistry, Nencki Institute of Experimental Biology, 3 Pasteur ulica, 02-093 Warsaw, Poland.     

Leptin receptors in human skeletal muscle.

Human skeletal muscle expresses leptin receptor mRNA; however, it remains unknown whether leptin receptors (OB-R) are also expressed at the protein level. Fourteen healthy men (age = 33.1 +/- 2.0 yr, height = 175.9 +/- 1.7 cm, body mass = 81.2 +/- 3.8 kg, body fat = 22.5 +/- 1.9%; means +/- SE) participated in this investigation. The expression of OB-R protein was determined in skeletal muscle, subcutaneous adipose tissue, and hypothalamus using a polyclonal rabbit anti-human leptin receptor. Three bands with a molecular mass close to 170, 128, and 98 kDa were identified by Western blot with the anti-OB-R antibody. All three bands were identified in skeletal muscle: the 98-kDa and 170-kDa bands were detected in hypothalamus, and the 98-kDa and 128-kDa bands were detected in thigh subcutaneous adipose tissue. The 128-kDa isoform was not detected in four subjects, whereas in the rest its occurrence was fully explained by the presence of intermuscular adipose tissue, as demonstrated using an anti-perilipin A antibody. No relationship was observed between the basal concentration of leptin in serum and the 170-kDa band density. In conclusion, a long isoform of the leptin receptor with a molecular mass close to 170 kDa is expressed at the protein level in human skeletal muscle. The amount of 170-kDa protein appears to be independent of the basal concentration of leptin in serum.     

Phosphorylation of smooth muscle caldesmon by three protein kinases: implication for domain mapping

Phosphorylation of duck gizzard caldesmon by Ca2+/phospholipid-dependent protein kinase, Ca2+/calmodulin-dependent protein kinase and casein kinase II has been investigated. The Ca2+/phospholipid-dependent protein kinase incorporates more than 3 mol phosphate per mol (140 kDa) caldesmon. All phosphorylation sites are localized in the actin- and calmodulin-binding peptide (40-45 kDa) supposed to be a part of the C-terminal domain of caldesmon. Casein kinase II phosphorylates only one site located in a short (25-27 kDa) peptide, presumably in the caldesmon N-terminal domain. The Ca2+/calmodulin-dependent protein kinase phosphorylates two sites located in the N- and C-terminal domains of caldesmon.     

Characterization of mitotically phosphorylated caldesmon.

Mitosis-specific phosphorylation by cdc2 kinase causes nonmuscle caldesmon to dissociate from microfilaments (Yamashiro, S., Yamakita, Y., Ishikawa, R., and Matsumura, F. (1990) Nature 344, 675-678; Yamashiro, S., Yamakita, Y., Hosoya, H., and Matsumura, F. (1991) Nature 349, 169-172). To explore the function of mitosis-specific phosphorylation of caldesmon, in vivo- and in vitro-phosphorylated caldesmons have been characterized. We have found that both in vivo and in vitro phosphorylation of caldesmon causes similar changes in the properties, including reduction in actin, calmodulin, and myosin binding of caldesmon, and a decrease in the inhibition of actomyosin ATPase by caldesmon. Rat non-muscle caldesmon is phosphorylated in vitro up to a ratio of 7 mol/mol of protein. Actin-binding constants of both a high affinity (K a = 1.2 x 10(7) M-1) and a low affinity (K a = 1 x 10(6) M-1) site of unphosphorylated caldesmon are reduced to less than 10(5) M-1 with 5 mol of phosphate incorporation per mol of protein. Actin-bound caldesmon can be phosphorylated by cdc2 kinase, which results in the dissociation of caldesmon from F-actin. Caldesmon has a second myosin-binding site in the C terminus, in addition to the N terminus myosin-binding domain previously reported, because the bacterially expressed C terminus of caldesmon shows binding to myosin. Phosphorylation of the C-terminal fragments decreases their myosin-binding affinity as observed with intact caldesmon. These results suggest that caldesmon loses most of its in vitro functions during mitosis as a result of phosphorylation, which may be required for the reorganization of microfilaments during mitosis.     

Autophosphorylation of smooth-muscle caldesmon.

Caldesmon, a major actin- and calmodulin-binding protein of smooth muscle, has been implicated in regulation of the contractile state of smooth muscle. The isolated protein can be phosphorylated by a co-purifying Ca2+/calmodulin-dependent protein kinase, and phosphorylation blocks inhibition of the actomyosin ATPase by caldesmon [Ngai & Walsh (1987) Biochem. J. 244, 417-425]. We have examined the phosphorylation of caldesmon in more detail. Several lines of evidence indicate that caldesmon itself is a kinase and the reaction is an intermolecular autophosphorylation: (1) caldesmon (141 kDa) and a 93 kDa proteolytic fragment of caldesmon can be separated by ion-exchange chromatography: both retain caldesmon kinase activity, which is Ca2+/calmodulin-dependent; (2) chymotryptic digestion of caldesmon generates a Ca2+/calmodulin-independent form of caldesmon kinase; (3) caldesmon purified to electrophoretic homogeneity retains caldesmon kinase activity, and elution of enzymic activity from a fast-performance-liquid-chromatography ion-exchange column correlates with caldesmon of Mr 141,000; (4) caldesmon is photoaffinity-labelled with 8-azido-[alpha-32P]ATP; labelling is inhibited by ATP, GTP and CTP, indicating a lack of nucleotide specificity; (5) caldesmon binds tightly to Affi-Gel Blue resin, which recognizes proteins having a dinucleotide fold. Autophosphorylation of caldesmon occurs predominantly on serine residues (83.3%), with some threonine (16.7%) and no tyrosine phosphorylation. Autophosphorylation is site-specific: 98% of the phosphate incorporated is recovered in a 26 kDa chymotryptic peptide. Complete tryptic/chymotryptic digestion of this phosphopeptide followed by h.p.l.c. indicates three major phosphorylation sites. Caldesmon exhibits a high degree of substrate specificity: apart from autophosphorylation, brain synapsin I is the only good substrate among many potential substrates examined. These observations indicate that caldesmon may regulate its own function (inhibition of the actomyosin ATPase) by Ca2+/calmodulin-dependent autophosphorylation. Furthermore, caldesmon may regulate other cellular processes, e.g. neurotransmitter release, through the Ca2+/calmodulin-dependent phosphorylation of other proteins such as synapsin I.     

The smooth muscle 132 kDa cyclic GMP-dependent protein kinase substrate is not myosin light chain kinase or caldesmon.

Atrial natriuretic peptide (ANP) stimulates the phosphorylation of three cyclic GMP-dependent protein kinase substrate proteins of 225, 132, and 11 kDa (P225, P132 and P11 respectively) in the particulate fraction of cultured rat aortic smooth muscle cells [Sarcevic, Brookes, Martin, Kemp & Robinson (1989) J. Biol. Chem. 264, 20648-20654]. Vrolix, Raeymaekers, Wuytack, Hofmann & Casteels [(1988) Biochem. J. 255, 855-863] have reported the presence of a 130 kDa cyclic GMP-dependent protein kinase substrate protein in the membrane fraction of pig aorta or stomach, and suggested that it may be myosin light chain kinase (MLCK). The aim of the present study was to determine whether P132 from rat aorta was MLCK or caldesmon. Although P132 co-migrates with purified chicken gizzard MLCK on SDS/polyacrylamide gels, it is distinct from rat aortic MLCK. Partially purified MLCK from rat aorta migrated as a 145 kDa protein on SDS/polyacrylamide gels. Immunoblotting the partially purified rat aortic MLCK with antibody to bovine tracheal MLCK identified rat aortic MLCK (145 kDa) and a corresponding 145 kDa protein in the particulate fraction of cultured rat aortic smooth muscle cells, but did not detect the 132 kDa protein. Phosphopeptide maps of purified rat aortic MLCK prepared by digestion with Staphylococcus aureus V8 protease were distinct from those of P132. P132 was not caldesmon, since antibodies to caldesmon cross-reacted with 136 and 76 kDa proteins in the particulate fraction of rat aortic cells, but not with P132. Furthermore, caldesmon was partially extracted from the particulate into the soluble fraction by heating at 90 degrees C, whereas P132 was not. These results demonstrate that the ANP-responsive cyclic GMP-dependent protein kinase substrate of 132 kDa from rat aortic smooth muscle cells is not MLCK or caldesmon.