Ca2(+)-dependent protein phosphatase which dephosphorylates regulatory light chain-a in scallop smooth muscle myosin

Ca2(+)-dependent protein phosphatase was purified from scallop adductor smooth muscle by a combination of DEAE-Toyoperal 650S ion exchange chromatographies and gel filtration on Sephacryl S-300. The phosphatase consisted of two subunits having molecular weights of 60 and 19 kDa. Phosphorylated regulatory light chain-a (RLC-a) was dephosphorylated by this phosphatase both in free and bound states in myosin prepared from the opaque portion of scallop smooth muscle (opaque myosin). The dephosphorylation was activated by Ca2+. The half maximal activation was a 1 microM free Ca2+ in the presence of calmodulin and 7 microM free Ca2+ in the absence of calmodulin. Opaque myosin phosphorylated at the heavy chain was not dephosphorylated with this phosphatase. p-Nitrophenyl phosphate was dephosphorylated. In addition to Ca2+, the phosphatase activity for RLC-a was activated by Mn2+, while p-nitrophenylphosphatase activity was activated by Mg2+ more strongly than by Mn2+. The pH-activity curves showed a maximum at pH 7 in the presence of Mn2+, but at around pH 8 in the presence of Mg2+. This phosphatase is similar to phosphatase 2B or calcineurin. The possible regulatory function of this phosphatase in scallop catch muscle is discussed.     

Regulatory light chain-a myosin kinase (aMK) catalyzes phosphorylation of smooth muscle myosin heavy chains of scallop, Patinopecten yessoensis

Regulatory light chain-a myosin kinase (aMK), which phosphorylates one of the myosin regulatory light chains, RLC-a, contained in the catch muscle of scallop, was also found to phosphorylate heavy chains of scallop myosin. After incubation of myosin isolated from the opaque portion of scallop smooth muscle (opaque myosin) with aMK in the presence of [gamma-32P]ATP, about 2 mol of 32P was incorporated per mol of the myosin. The radioactivity was mostly found in the heavy chain at 0.26 M KCl. The pH-activity curve and MgCl2 requirement for the heavy chain phosphorylation were similar to those for RLC-a phosphorylation. In contrast, the dependency of activity on KCl concentration was different from that for RLC-a. The heavy chain phosphorylation activity decreased with increase in KCl concentration up to 0.06 M, and then increased at concentrations over 0.06 M to a maximum at around 0.26 M KCl. This complicated profile probably reflects the solubility of myosin, and the phosphorylation site may be located in the rod portion insoluble at low KCl concentrations. Phosphorylation of heavy chain did not change the solubility of the opaque myosin molecule at all. The acto-opaque myosin ATPase activity in the presence of Ca2+ was found to be decreased to less than one-fourth by the heavy chain phosphorylation.     

Temperature dependence of the decay of the UV absorption difference spectrum of heavy meromyosin induced by adenosine triphosphate and inosine triphosphate.

The UV absorption difference spectrum of heavy meromyosin induced by ATP was measured at various temperatures. At higher temperatures, the difference spectrum formed rapidly after adding ATP and continued steadily during the steady state which we have called the ATP-form of difference spectrum. At lower temperatures, the ATP-form of difference spectrum decayed into the other form before the steady state was attained. This was identical to the difference spectrum obtained by adding ADP and has been called the ADP-form of difference spectrum. At intermediate temperatures, biphasic decay was observed. The results indicate that the dominant intermediate at the steady state is altered from the one showing the ATP-form of difference spectrum at higher temperatures to that showing the ADP-form at lower temperatures. The population of the two intermediates depends on the temperature between the two extremes. This temperature-induced transition was observed in the presence of any divalent cation such as Mg2+, Mn2+, or Ca2+. A similar transition was observed with the difference spectrum induced by ITP in the presence of MgCl2. The pH dependence of the single early decay of the ATP-induced difference spectrum was measured in the presence of MnCl2 at 1 degree. The apparent rate constant of the decay showed a biphasic pH dependence, having the same shape as the pH activity curve of ATPase [EC 3.6.1.3] observed at higher temperatures. The rate determining step for the steady state ATPase at higher temperatures is thought to be the step of changing from the intermediate complex showing the ATP-form of difference spectrum to that showing the ADP-form. This is inconsistent with our previous mechanism (Yazawa, M. et al. (1973) J. Biochem. 74, 1107-1117). The rate determining step at lower temperatures was assigned as a step of ADP dissociation.     

A cAMP-dependent regulatory protein for RLC-a myosin kinase catalyzing the phosphorylation of scallop smooth muscle myosin light chain

A cAMP-dependent regulatory protein which modulates the phosphorylation of scallop myosin regulatory light chain-a (RLC-a) by RLC-a myosin kinase (aMK) (Sohma, H. & Morita, F. (1986) J. Biochem. 100, 1155-1163) was purified from the scallop smooth muscle. RLC-a is abundant in the opaque portion of scallop smooth muscle, one of the catch muscles. The regulatory protein for aMK was purified by employing successively DEAE Toyopearl ion exchange chromatography, Sepharose 4B-8(6-aminohexylamino)cAMP affinity chromatography, and Sephadex G 100 gel filtration. The molecular mass of the regulatory protein was 41 kDa, based on the mobility in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. With increasing amounts of the regulatory protein, the aMK activity decreased, and complete inhibition was observed at the concentration of twice that of aMK. The aMK activity inhibited by the regulatory protein was restored by the addition of cAMP. These results suggest that aMK is similar to a catalytic subunit of cAMP-dependent protein kinase, and the protein reported here is similar to its regulatory subunit. aMK may exist as an inactive form, as a combination with this regulatory protein, in vivo and be deinhibited by an increase in the intracellular concentration of cAMP. We discuss a possible correlation between the phosphorylation of RLC-a in myosin catalyzed by aMK and the catch state of the opaque portion of scallop smooth muscle.     

Myosin may stay in EADP species during the catch contraction in scallop smooth muscle

Myosin (opaque myosin) isolated from the opaque portion of scallop smooth muscle, a catch muscle, was subjected to limited digestion by trypsin during the steady-state ATPase reaction. The 200-kDa heavy chain of opaque myosin was cleaved into 125- and 74-kDa fragments. The proteolytic rate in the absence of Ca2+ was lower than that in the presence of Ca2+, and was similar to that in the presence of ADP and absence of Ca2+. The results suggest that the steady-state intermediate of opaque myosin ATPase in the absence of Ca2+ is EADP, which is consistent with the previous results based on the difference UV-absorption spectrum (Takahashi, M., Sohma, H., & Morita, F. (1988) J. Biochem. 104, 102-107). In the presence of F-actin, the proteolytic rates were decreased, but the digestive patterns by trypsin were similar to those of myosin alone. Even in the presence of F-actin, the proteolytic rate during the ATPase reaction in the absence of Ca2+ was lower than that in the presence of Ca2+, and was similar to that in the presence of ADP and absence of Ca2+. In addition, there was another trypsin-susceptible site which is probably located at 18 kDa from the N-terminal of the heavy chain. The site in the absence of Ca2+ was hardly cleaved when ATP or ADP was present. Similar tendencies were observed even in the presence of F-actin. These findings suggest that the intermediate of opaque myosin ATPase at the steady state in the absence of Ca2+ is EADP even in the presence of F-actin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of regulatory light chain-a myosin kinase from smooth muscle of scallop, Patinopecten yessoensis

The protein kinase that phosphorylates the regulatory light chain-a (RLC-a) of scallop smooth muscle myosin was isolated from scallop smooth muscle (Sohma, H. & Morita, F. (1986) J. Biochem. 100, 1155-1163). The enzymatic properties of this kinase (aMK) were investigated using RLC-a as the substrate. The Km value for ATP was 6.5 microM in the presence of 27 microM RLC-a at pH 7.0, and that for RLC-a was 133 microM in the presence of 1 mM ATP. The Vm value at saturation of both RLC-a and ATP was 0.25 s-1 at pH 7.0. The pH activity curve for aMK was bell-shaped with a maximum at around pH 7.8. The aMK activity was inhibited strongly by an increase in the KCl concentration. aMK required Mg2+, but was inhibited by high concentrations of Mg2+. The optimum activity was seen at 3 mM MgCl2. The mode of inhibition of the aMK activity by Ca2+ was studied. Assuming that the binding of Ca2+ to aMK induces the inhibition, the dissociation constant of Ca2+ was estimated to be 64 microM. aMK also phosphorylated LC20 of chicken gizzard myosin at a similar rate to that for RLC-a and the DTNB light chain of rabbit skeletal muscle myosin at a more lower rate. The helix and beta-sheet contents of aMK were estimated to be 19 and 30%, respectively, from the CD spectrum.     

Temperature induced analog reaction of adenylyl imidodiphosphate to an intermediate step of heavy meromyosin adenosine triphosphatase.

The UV absorption difference spectrum of heavy meromyosin induced by adenylyl imidodiphosphate (AMP-PNP) was found to be changed by temperature. At higher temperatures, the shape of the difference spectrum resembled the ATP-form of difference spectrum induced by ATP. At lower temperatures, a different shape was observed, resembling that induced by ADP. This temperature transition was found in the presence of both MgCl2 and MnCl2. The transition temperatures, were 21 degrees and 9 degrees in the presence of MnCl2 and MgCl2, respectively. A similar temperature dependence was observed with the difference spectrum induced by ATP at the steady state. The transition temperatures in this case were 11 degrees and 4.5 degrees in the presence of MnCl2 and MgCl2, respectively. The similarity of the effects of the two kinds of divalent cation on both transitions indicates that the temperature induced transition between two species of heavy meromyosin-AMP-PNP complex mimics the step in APTase [EC 3.6.1.3] reaction in which the intermediate complex showing the ATP-form of difference spectrum changes to that showing the ADP-form. The equilibrium constant of the decay step of the ATP-form of difference spectrum to the ADP-form in ATPase is, therefore, thought to be highly temperature dependent. Thermodynamic parameters were calculated for the transition between the two species of heavy meromyosin AMP-PNP complex. Large decreases in enthalpy and entropy were observed, while the standard free energy change was small. The results suggest that the intermediate showing the ATP-form of difference spectrum hardly changes to the forward direction in the ATPase reaction at higher temperature. The complex appears to be so stable in the steady state that almost all the myosin is present as this complex. The decay step in ATPase of the difference spectrum from the ATP-form to to the ADP-form may be coupled to muscular contraction. The temperature induced transition of heavy meromyosin AMP-PNP complex may, therefore, provide information concerning the state of myosin in active muscles.     

Calcium binding and conformation of regulatory light chains of smooth muscle myosin of scallop

Calcium binding was studied with two regulatory light chains (RLC-a and RLC-b) of smooth muscle myosin of scallop. With the equilibrium dialysis method, the binding of 0.98 mol Ca2+ per mol of RLC-b was observed with a dissociation constant of 2.3 X 10(-5) M. Similar values for RLC-b, 1.9 X 10(-5) M, and RLC-a, 1.5 X 10(-5) M, were obtained by measuring the difference absorption spectrum induced by Ca2+. The difference molar absorption coefficient at 288 nm was 159 and 209 M-1 X cm-1 for RLC-a and RLC-b, respectively, while it was -34 M-1 X cm-1 for the regulatory light chain of striated muscle myosin of scallop (RLC-st). Proton NMR spectra of the three light chains were very similar to each other and were broader than those of other Ca2+ binding proteins, parvalbumin and calmodulin. The regulatory light chains may be more rigid than in these Ca2+ binding proteins. CD spectra were measured for the three light chains, and the estimated helix contents were 27, 29, and 24%, respectively, for RLC-a, RLC-b, and RLC-st. All these results in comparison with the primary structures led us to suppose that the polypeptide of regulatory light chains is folded in such a way that domain 4 becomes near to the calcium binding site of domain 1. The decrease in intact light chains on trypsin digestion was determined for the gel electrophoretic patterns. RLC-a was 6 times more susceptible to the tryptic digestion than RLC-b.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation of regulatory light chain a (RLC-a) in smooth muscle myosin of scallop, Patinopecten yessoensis

One of the two regulatory light chains, RLC-a, of scallop smooth muscle myosin was fully phosphorylated by myosin light chain kinase of chicken gizzard muscle. The residue phosphorylated was Ser. It may be the Ser at number 11 from the N-terminal. The sequence of 9 residues around the Ser-11, QRATSNVFA, is identical with that around the phosphorylatable Ser of LC20 of chicken gizzard myosin. RLC-a was also phosphorylated slowly by cAMP-dependent protein kinase. The phosphorylation of RLC-a may be involved in the regulatory system for the catch contraction of scallop muscle.     

The effect of dicyclohexylcarbodiimide and cyclopiazonic acid on the difference FTIR spectra of sarcoplasmic reticulum induced by photolysis of caged-ATP and caged-Ca2+.

The photochemical release of Ca2+ from caged-Ca2+ in the absence of ATP, and the release of ATP from caged-ATP in the presence of Ca2+ induce characteristic difference FTIR spectra on rabbit sarcoplasmic reticulum that are related to the formation of Ca2-E1 and E approximately P intermediates of the Ca(2+)-ATPase, respectively. Dicyclohexylcarbodiimide (10 nmol/mg protein) abolished both the Ca(2+)-and ATP-induced difference FTIR spectra parallel with inhibition of ATPase activity. Cyclopiazonic acid (50 nmol/mg protein) inhibited the Ca(2+)-induced difference spectrum measured in the absence of ATP, but had no significant effect on the ATP-induced difference spectrum measured in the presence of 1 mM Ca2+. The dog kidney Na+,K(+)-ATPase did not give significant difference spectrum after photolysis of caged-ATP in Ca(2+)-free media containing 90 mM Na+ and 10 mM K+, with or without ouabain. We propose that both the Ca2+ and the ATP-induced difference FTIR spectra of the Ca(2+)-ATPase reflect the occupancy of the high-affinity Ca2+ transport site of the enzyme.     

Chimaeric myosin regulatory light chains: sub-domain switching experiments to analyse the function of the N-terminal EF hand.

The regulatory light chains (RLCs) located on the myosin head, regulate the interaction of myosin with actin in response to either Ca2+ or phosphorylation signals. The RLCs belong to a family of calcium binding proteins and are composed of four "EF hand" ancestral calcium binding motifs (numbered I to IV). To determine the role of the first EF hand (EF hand I) in the regulatory process, chimaeric light chains were constructed by protein engineering, by switching this region between smooth muscle and skeletal muscle myosin RLCs. For example, chimaera G(I)S consisted of EF hand I of the smooth muscle (gizzard) RLC and EF hands II to IV of the skeletal muscle RLC, whereas chimaera S(I)G consisted of EF hand I of the skeletal muscle RLC and EF hands II to IV of the smooth muscle RLC. The chimaeric RLCs were expressed in Escherichia coli using the pLcII expression system, and after isolation and purification their regulatory properties were compared with those of wild-type smooth and skeletal muscle myosin RLCs. The chimaeric RLCs bound to the myosin heads in scallop striated muscle myofibrils from which the endogenous RLCs had been removed ("desensitized" myofibrils) with similar affinities to those of the wild-type smooth and skeletal muscle RLCs. Both chimaeric RLCs were able to regulate the actin-activated Mg(2+)-ATPase activity of scallop myosin: G(I)S inhibited the ATPase in the presence and absence of Ca2+, like the wild-type skeletal muscle RLC, while S(I)G inhibited the myosin ATPase in the absence of Ca2+, and this inhibition was relieved on Ca2+ addition, in the same way as the wild-type smooth muscle RLC. Thus the type of regulation that the RLCs confer on the myosin is determined by the source of EF hands II to IV rather than that of EF hand I.     

Purification of a protein kinase phosphorylating myosin regulatory light chain-a (RLC-a) from smooth muscle of scallop, Patinopecten yessoensis

A protein kinase activity phosphorylating regulatory light chain-a (RLC-a) of scallop smooth muscle myosin was found to be present in scallop smooth muscle homogenate. The kinase was purified to homogeneity and named RLC-a myosin kinase (aMK). aMK was extracted from the muscle homogenate with a low salt solution and was purified by successive DE-32 ion exchange chromatography, gel filtration on Ultrogel AcA 44, and affinity chromatography on Sepharose 4B-6-aminohexyl-1-pyrophosphate. The molecular weight of aMK was estimated to be 40-kDa from the mobility on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and 35-kDa from the elution volume on Sephadex G-150 gel filtration. The phosphorylation site of RLC-a by aMK was determined to be Ser residue(s). Only RLC-a was phosphorylated; the other regulatory light chain, RLC-b, was not. The phosphorylatable Ser of RLC-a is, therefore, considered to be Ser-11, which is located in the N-terminal region having a different amino acid sequence from that of RLC-b. RLC-a was phosphorylated by aMK 3 times faster in the free state than in the bound state to myosin. aMK does not require calmodulin and is rather inhibited by CaCl2.     

Inhibitory effect of MgATP on the release of regulatory light chain from scallop myosin and light chain composition of scallop myosin hybridized with abalone light chain 2 at 30 degrees C

The experimental conditions for release of the regulatory light chain (RLC) of scallop myosin at 30 degrees C were studied. Substantially all RLC was released from myosin by incubation for 5 min in medium containing buffer and KCl. This release of RLC was inhibited strongly by Ca2+, while the effect of Mg2+ was about 10,000 times weaker than that of Ca2+. Even in the absence of Ca2+, MgATP and MgADP inhibited the release of RLC, while the protective effect of AMPPNP was negligible. Other Mg nucleotides also showed some protective effect, though appreciably less than MgATP. The incubation of scallop myosin with abalone regulatory light chain (LC2) at 30 degrees C for 5 min produced a hybrid myosin. In the presence of 5 mM MgCl2, 1 of the 2 mol of RLC per mol of scallop myosin was exchanged with 1 mol of LC2. In the presence of Ca2+ or MgATP, myosin bound 1 extra mole of LC2 besides the 2 mol each of SH-LC and RLC.     

Ca2+-sensitive transition in the molecular conformation of molluscan muscle myosins

Filament assemblies of myosin molecules purified from scallop adductor muscles were stabilized by Ca2+ in the presence of ATP or ADP. Electron micrographs showed that the tail part of monomeric myosin molecules was folded in the absence of Ca2+, but was extended in the presence of Ca2+ at physiological ionic strength.     

The C-terminal helix in subdomain 4 of the regulatory light chain is essential for myosin regulation.

In vertebrate smooth/non-muscle myosins, phosphorylation of the regulatory light chains by a specific calmodulin-activated kinase controls both myosin head interaction with actin and assembly of the myosin into filaments. Previous studies have shown that the C-terminal domain of the regulatory light chain is crucial for the regulation of these myosin functions. To further dissect the role of this region of the light chain in myosin regulation, a series of chicken smooth muscle myosin regulatory light chain mutants has been constructed with successive C-terminal deletions. These mutants were synthesized in Escherichia coli and analysed by their ability to restore Ca2+ regulation to scallop myosin that had been stripped of its native regulatory light chains ('desensitized'). The results show that regulatory light chain mutants with deletions in the C-terminal helix in subdomain 4 were able to reform the regulatory Ca2+ binding site on the scallop myosin head, but had lost the ability to suppress scallop myosin filament assembly and interaction with actin in the absence of Ca2+. Further deletions in the C-terminal domain led to a gradual loss of ability to restore the regulatory Ca2+ binding site. Thus, the regions in the C-terminal half of the regulatory light chain responsible for myosin regulation can be identified.     

Regulation of molluscan actomyosin ATPase activity

The interaction of myosin and actin in many invertebrate muscles is mediated by the direct binding of Ca2+ to myosin, in contrast to modes of regulation in vertebrate skeletal and smooth muscles. Earlier work showed that the binding of skeletal muscle myosin subfragment 1 to the actin-troponin-tropomyosin complex in the presence of ATP is weakened by less than a factor of 2 by removal of Ca2+ although the maximum rate of ATP hydrolysis decreases by 96%. We have now studied the invertebrate type of regulation using heavy meromyosin (HMM) prepared from both the scallop Aequipecten irradians and the squid Loligo pealii. Binding of these HMMs to rabbit skeletal actin was determined by measuring the ATPase activity present in the supernatant after sedimenting acto-HMM in an ultracentrifuge. The HMM of both species bound to actin in the presence of ATP, even in the absence of Ca2+, although the binding constant in the absence of Ca2+ (4.3 X 10(3) M-1) was about 20% of that in the presence of Ca+ (2.2 X 10(4) M-1). Studies of the steady state ATPase activity of these HMMs as a function of actin concentration revealed that the major effect of removing Ca2+ was to decrease the maximum velocity, extrapolated to infinite actin concentration, by 80-85%. Furthermore, at high actin concentrations where most of the HMM was bound to actin, the rate of ATP hydrolysis remained inhibited in the absence of Ca+. Therefore, inhibition of the ATPase rate in the absence of Ca2+ cannot be due simply to an inhibition of the binding of HMM to actin; rather, Ca2+ must also directly alter the kinetics of ATP hydrolysis.     

Ca2+ activates actin-filament sliding on scallop myosin but inhibits that on Physarum myosin

The actin-activated ATPase activity of Physarum myosin has been shown to be inhibited by microM levels of Ca2+, the mode of which is in contrast to the activating effect of Ca2+ on scallop myosin (Kohama, K. (1987) Adv. Biophys. 23, 149-182 for a review). To determine if Ca2+ regulates ATP-dependent sliding between actin and the myosins, fluorescent actin-filaments were allowed to move on the myosins fixed to a glass surface. The movement on Physarum and scallop myosins was inhibited and activated, respectively, by Ca2+. For this myosin-linked regulation to occur for Physarum myosin, myosin phosphorylation was shown to be a prerequisite.     

Structural evidence for non-canonical binding of Ca2+ to a canonical EF-hand of a conventional myosin

We have previously identified a single inhibitory Ca2+-binding site in the first EF-hand of the essential light chain of Physarum conventional myosin (Farkas, L., Malnasi-Csizmadia, A., Nakamura, A., Kohama, K., and Nyitray, L. (2003) J. Biol. Chem. 278, 27399-27405). As a general rule, conformation of the EF-hand-containing domains in the calmodulin family is "closed" in the absence and "open" in the presence of bound cations; a notable exception is the unusual Ca2+-bound closed domain in the essential light chain of the Ca2+-activated scallop muscle myosin. Here we have reported the 1.8 A resolution structure of the regulatory domain (RD) of Physarum myosin II in which Ca2+ is bound to a canonical EF-hand that is also in a closed state. The 12th position of the EF-hand loop, which normally provides a bidentate ligand for Ca2+ in the open state, is too far in the structure to participate in coordination of the ion. The structure includes a second Ca2+ that only mediates crystal contacts. To reveal the mechanism behind the regulatory effect of Ca2+, we compared conformational flexibilities of the liganded and unliganded RD. Our working hypothesis, i.e. the modulatory effect of Ca2+ on conformational flexibility of RD, is in line with the observed suppression of hydrogen-deuterium exchange rate in the Ca2+-bound form, as well as with results of molecular dynamics calculations. Based on this evidence, we concluded that Ca2+-induced change in structural dynamics of RD is a major factor in Ca2+-mediated regulation of Physarum myosin II activity.     

High molecular weight calcium binding protein in the microsome of scallop striated muscle

In the microsome of scallop adductor striated muscle, 30K, 55K, 90K, and 360K proteins were detected as calcium binding proteins by 45Ca autoradiography on the transferred nitrocellulose membrane after sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS PAGE). The 360K protein was directly extracted with Triton X-100 from the whole homogenate of striated portion of scallop adductor muscle and purified through DEAE cellulose and hydroxyapatite column chromatography. This purified scallop high molecular weight calcium binding protein (SHCBP) showed a faster mobility in SDS PAGE in the presence of Ca2+ than in its absence. The decrease of tryptophan fluorescence had a half maximum near pCa 7 and was slightly co-operative with Mg2+. UV absorbance was slightly increased with Ca2+. The CD spectrum also changed with Mg2+ and Ca2+. These results reflect that this SHCBP binds calcium ions under near physiological conditions. SHCBP-like high molecular weight calcium binding proteins were also detected in the smooth muscle portion of adductor muscle and branchiae of scallop by 45Ca autoradiography, but not in liver. The adductor muscle of clam had a high molecular weight calcium binding protein whose molecular weight was a little smaller than that of SHCBP. The foot of turban shell had the same molecular weight calcium binding protein as SHCBP. Stains-all, a cationic carbocyanine dye, which has been reported to stain calcium binding proteins blue, stained SHCBP blue. The spectrum of SHCBP stained with Stains-all was very similar to that of calsequestrin. Although the function of SHCBP is still unknown, it might be expected to correspond to calsequestrin of vertebrate skeletal muscle, a calcium sequestering protein, in the sarcoplasmic reticulum.     

Monoclonal antibodies toward scallop (Patinopecten yessoensis) testis and wheat germ calmodulins.

A monoclonal antibody (IM7) toward scallop testis calmodulin and another one (PBE2) toward wheat germ calmodulin were produced. Ca2+ was required for IM7 to react with scallop calmodulin. IM7 reacted with the C-terminal region (Asp78-Lys148) of the calmodulin. As observed on competitive ELISA, IM7 reacted with chicken calmodulin, but not with Euglena gracilis or wheat calmodulin, troponin C, myosin light chains, or parvalbumin. It is assumed that the cluster of Thr143, Thr146, and Ser147 in the C-terminal region acts as the antigenic site. IM7 (and Fab of IM7) inhibited the activities of myosin light chain kinase and cAMP-phosphodiesterase. PBE2 reacted with wheat germ calmodulin irrespective of the presence or absence of Ca2+, the antigenic site being in the N-terminal region (Ala1-Met37). It reacted with wheat and spinach calmodulins, but not with scallop, chicken, or Euglena calmodulin, troponin C, myosin light chains, or parvalbumin. PBE2 had no effect on the activities of myosin light chain kinase and cAMP-phosphodiesterase.