The effects of maitotoxin on phosphoinositides and calcium metabolism in a primary culture of aortic smooth muscle cells

Maitotoxin, a potent marine toxin isolated from toxic tropical dinoflagellates and poisonous fishes induces contraction of different smooth muscle preparations. Actions of maitotoxin on phosphoinositides and calcium metabolism were studied using a primary culture of aortic smooth muscle cells. Maitotoxin induced a very large increase of cytosolic calcium concentration as evaluated by fura-2 acetoxymethyl ester fluorescence. This increase was concomitant with stimulation of inositol-phosphate accumulation and loss of viability of aortic smooth muscle cells. These responses to maitotoxin were abolished in Ca2+-free medium, and were mimicked by saponin. Calcium ionophores or K+ depolarisation did not induce inositol-phosphate formation. These results suggest that maitotoxin acts by altering smooth muscle cells permeability allowing a sustained calcium influx which is able to activate inositol-phosphate formation and which is lethal for the cells.

Acute adaptative changes to unilateral nephrectomy in humans

Renal function was monitored in 20, living-related kidney donors before and after uninephrectomy. Urinary protein excretion and retinoid metabolism respectively were studied in 10 and 6 of these donors. The functional adaptation was characterized by an increase in glomerular filtration rate and tubular function, which began in the first two days after uninephrectomy. Changes in tubular function were also demonstrated by significant increases in the urinary excretion of beta 2 microglobulin (beta 2M), retinol binding protein (RBP), kappa and lambda light chains of immunoglobulins. In addition, a protein identical to or homologous to cellular retinoic acid binding protein (CRABP), appeared in the urine after nephrectomy. We did not find CRABP in serum samples either before or after nephrectomy, suggesting that urinary CRABP was synthesized by the remaining kidney. Increases in serum levels of Vitamin A and RBP were also observed in the post-nephrectomy period. These modifications in retinol metabolism suggest that these substances could have a role as renotropic growth factors in compensatory hypertrophy.

Site-specific mutagenesis of the alpha-helices of calmodulin. Effects of altering a charge cluster in the helix that links the two halves of calmodulin

Alteration of residues 82-84 in the alpha-helix that links the two halves of calmodulin results in a differential effect on activator activity. Previous studies (Lukas, T. J., Burgess, W. H., Prendergast, F. G., Lau, W., and Watterson, D. M. (1986) Biochemistry 25, 1458-1464) indicated the importance of positive charge clusters in the calmodulin-binding protein, myosin light chain kinase. This suggested the possible importance of complementary negative charge clusters in calmodulin. By using an efficient cassette mutagenesis approach and a synthetic calmodulin gene (Roberts, D. M., Crea, R., Malecha, M., Alvarado-Urbina, G., Chiarello, R. H., and Watterson, D. M. (1985) Biochemistry 24, 5090-5098), this possibility was directly addressed by engineering a new calmodulin, VU-8 calmodulin, in which the glutamate cluster at residues 82-84 in the synthetic gene product (VU-1 calmodulin) was replaced by three lysines. VU-8 calmodulin activated phosphodiesterase to the same maximal extent as VU-1 calmodulin, although there was an alteration in the concentration of calmodulin required for half-maximal stimulation. In contrast, myosin light chain kinase was activated to only 30% of maximal activity and NAD kinase was not activated. These results provide insight into the functional role of the unusual central helix structure found in the calmodulin family of proteins and indicate that different, although possibly overlapping, chemical complementarities are employed in the interaction between calmodulin and its various physiological targets.

Influence of Ca2+e on 5-HT2- and alpha 1-induced arterial contraction and phosphoinositide metabolism

Serotonin and phenylephrine were found to induce contractile responses and inositol phosphate (IP) formation in isolated rat tail artery. Both processes displayed similar concentration dependence in the presence of 2.5 mM external calcium (Ca2+e) and both were respectively inhibited by either ketanserine or prazosin, depending on the agonist used. In the absence of Ca2+e the amines no longer produced a contractile effect. In addition, lack of Ca2+ caused a shift to the right in the dose-response curve for phenylephrine-induced IP formation whereas serotonin-induced IP formation was not affected by changes in Ca2+e. The results suggest that alpha 1- and 5-HT2-induced contractions are quantitatively related to phosphatidylinositol metabolism. Contraction, but not IP formation requires the presence of Ca2+e. Different effects of Ca2+e on phenylephrine- and serotonin-induced IP formation could be related to a differential Ca2+ effect on binding of alpha 1- or 5-HT2 agonists.

Effect of steroid hormones on the regulation of uterine contractility

The kinetics of myosin light chain (LC20) phosphorylation has been studied during in vitro contraction and relaxation of rat uteri. Phosphorylation preceded contraction and continued during tetanus induced by KCl; the degree of phosphorylation was proportional to the percentage of contraction. On the other hand, during relaxation induced by isoproterenol, the level of phosphorylation did not change in the seconds following relaxation. A rapid change in cAMP did not appear to trigger a rapid change in LC20 phosphorylation. In cyclic rats, progesterone decreased the extent of LC20 phosphorylation: 50%-60% of the LC20 was phosphorylated in untreated animals or estrogen treated animals. This value fell to 30% after progesterone treatment of cyclic rats. In ovariectomized rats, steroid hormones did not affect the phosphorylation reaction. Under the same conditions, the level of cAMP-dependent protein kinases did not change during the cycle, or after estradiol-treatment, but in cyclic rats it doubled after progesterone treatment. Hence, the decrease in the level of LC20 phosphorylation observed in cyclic rats treated by progesterone could be due to a decrease in myosin light chain kinase (MLCK) activity, resulting from a higher proportion of the phosphorylated form of this enzyme. The concomitant increase in the proportion of activatable cAMP-dependent protein kinases could favor the maintenance of a higher level of phosphorylated MLCK for longer periods of time.

5-HT2 receptor-stimulated inositol phosphate formation in rat aortic myocytes

Serotonin (5-HT) stimulated inositol phosphate production in primary cultures of rat aortic myocytes via a 5-HT2 receptor. Agonists active at 5-HT2 receptors in other systems were also active here but the response to some agonists was potentiated by the hormone uptake blocker, cocaine HCl. Two 5-HT2 selective antagonists, ketanserin and spiperone, inhibited the serotonin-induced response while compounds selective for other 5-HT receptor subtypes did not.

Evidence for two distinct adenylate cyclase catalysts in rat brain

The Lubrol-soluble adenylate cyclase activity of brain synaptosomal membranes appeared, upon gel filtration or sucrose gradient centrifugation, as two overlapping peaks. Fractions corresponding to the peak of the largest Stokes radius (Biogel pool 1) or highest s value (gradient pool 1) contained an adenylate cyclase activity which could be detected whatever the enzyme assay conditions. In contrast, in fractions from the second peak (Biogel pool 2 or gradient pool 2), forskolin was needed to reveal adenylate cyclase activity. The enzyme activity of each Biogel pool was retained by forskolin-agarose and eluted by forskolin with a 34-83% yield. A polypeptide of 155 kDa made up 80% of the forskolin-agarose eluate 1, whereas it was almost absent from eluate 2. Since data from various groups point to the 155 kDa polypeptide as a brain adenylate cyclase catalyst, still another distinct catalyst of lower molecular mass is likely to be present in brain.

Biochemical and physiological evidences for antiserotonergic properties of naftidrofuryl

In experimental and clinical investigations, 2-(diethylamino)ethyl-tetrahydro-alpha-(1-naphthyl-methyl)-2-furanpro pionate (naftidrofuryl, Praxilene) appears to improve blood flow and microcirculation in ischemic areas. In order to define the mechanism by which the drug may exert its vascular effects, the binding affinity of naftidrofuryl toward various receptors was studied. From this biochemical study, it appeared that, in therapeutic doses, naftidrofuryl selectively inhibited the binding of spiperone or ketanserin to serotonin S2 receptors. This finding was corroborated in physiological models such as isolated rat caudal arteries or preparations of aortic myocytes. Naftidrofuryl effectively blocked the constrictive effect of serotonin on the artery in a dose-dependent, competitive manner. It also strongly inhibited the formation of serotonin-stimulated inositol triphosphate in the myocytes. From these good correlations between biochemical and physiological data it is concluded that the beneficial effects of naftidrofuryl on ischemic tissue perfusion may be partly explained on the basis of selective antiserotonergic S2 properties.

Activation of phosphatidylinositol synthesis by different agonists in a primary culture of smooth muscle cells grown on collagen microcarriers

Regulation of inositol phosphate synthesis was examined in a primary culture of vascular smooth muscle cells grown on collagen-coated microcarriers. In the presence of LiCl (10 mM), four agonists [serotonin, angiotensin, (arginine) vasopressin and noradrenaline] were found to stimulate the formation of inositol phosphates in a dose-dependent manner. All agonists were found to have identical and additive effects on the time course of inositol phosphate formation. Therefore, our primary cell culture technique was proved to give smooth muscle cells suitable for the study of modulation of phosphoinositide metabolism in response to physiological effectors.

The role of subunit autolysis in activation of smooth muscle Ca2+-dependent proteases

Ca2+-dependent proteases isolated from chicken gizzard and bovine aortic smooth muscle were compared with respect to subunit autolysis and the role of autolysis in modulating enzyme activity. The protease isolated from chicken gizzard was a heterodimer consisting of 80,000- and 30,000-dalton subunits. The protease isolated under identical conditions from bovine aorta consisted of 75,000- and 30,000-dalton subunits. In the presence of Ca2+, both enzymes underwent autolysis of their 30,000-dalton subunits with conversion to an 18,000-dalton species. In addition, the 80,000-dalton subunit of the gizzard protease was degraded to a 76,000-dalton form. The Ca2+ concentrations required for autolysis of the 30,000-dalton subunits were different for the two enzymes (i.e. gizzard: K0.5 Ca2+ = 335 microM; aortic: K0.5 Ca2+ = 1,250 microM) although in both cases, stimulation of autolysis by Ca2+ exhibited positive cooperativity. When compared with respect to kinetics of substrate degradation, the native forms of the smooth muscle Ca2+-dependent proteases (gizzard, GIIa = 80,000/30,000-dalton heterodimer; bovine aortic, IIa = 75,000/30,000-dalton heterodimer) exhibited a lag phase in product appearance. On the other hand, the autolyzed forms (gizzard, GIIb = 76,000/18,000-dalton heterodimer; bovine aortic, IIb = 75,000/18,000-dalton heterodimer) exhibited linear rates of substrate degradation. These results were analyzed in terms of autolysis of the 30,000-dalton subunits as determined by the conversion of this subunit to its 18,000 dalton form. For both enzymes, the time course for the autolytic transition, 30,000----18,000 daltons, and Ca2+-dependence of the apparent rate constants for this transition were found to correlate well with the lag phase in enzymatic activity. No such correlation could be established for the 80,000----76,000 dalton autolytic transition of the high molecular mass subunit of the gizzard protease. Our results suggest that catalytic activity of the Ca2+-dependent proteases isolated from gizzard and bovine aortic smooth muscle requires autolysis of the 30,000-dalton subunit. The native or unautolyzed forms of these enzymes appear to be proenzymes that can be activated by autolysis.

Maitotoxin stimulates the formation of inositol phosphates in rat aortic myocytes

Maitotoxin is the most potent of the known marine toxins. The effect of maitotoxin on muscle contraction or hormone release was consistent with its action on the voltage-sensitive channel. Indeed, calcium antagonists such as nifedipine or diltiazem were able to reverse the maitotoxin effects. Using smooth muscle cells, we have analysed the effects of maitotoxin on the inositol phosphate metabolism. Maitotoxin stimulates the inositol phosphate formation (5 +/- 1.8-fold in the presence of 10 mM LiCl). Moreover, this effect is not reversed, even partially by calcium antagonists, by alpha 1 antagonists and is not mimicked by Ca2+ ionophores such as A23187 or calcium agonists such as Bay-K 8644. The action of maitotoxin is further discussed in this paper.

Structural variations in actins. Biochemical and immunological tools for probing the structure of rabbit skeletal-muscle and bovine aortic actins

Structural differences between skeletal-muscle and aortic actins were studied by using biochemical and immunological approaches. By using proteinase digestion we found that three regions of actin show structural differences: (a) in the C-terminal part, (b) the region around residue 227 and (c) the region around residue 167. By using antibodies specific to particular actin conformations we can discriminate between monomeric and filamentous forms of the two actins. Our results show that the minor sequence variations of the N- and C-terminal regions induce structural change in these regions, but also some long-range structural variations in other regions.

Identification of the catalytic subunit of brain adenylate cyclase: a calmodulin binding protein of 135 kDa

The partial purification of the eukaryote adenylate cyclase [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1] catalytic subunit has been achieved by a procedure based on the calmodulin (CaM) sensitivity of the enzyme. Small amounts of rat brain synaptosomal membranes depleted of CaM were solubilized with Lubrol and subjected to a three-step chromatographic procedure involving gel filtration, a CaM-Sepharose affinity step, and fast protein liquid chromatography. About 20% of the adenylate cyclase activity contained in the membranes was recovered in the final enriched fraction with a specific activity of 200 nmol X mg-1 X min-1. The alpha subunits of the adenylate cyclase stimulatory proteins NS were absent from this final fraction. The addition of CaM, of forskolin, or of preactivated NS-containing fractions to this preparation greatly increased the enzyme activity. A CaM-binding polypeptide of 135,000 Da copurified with the adenylate cyclase activity in each of the three steps. Polyacrylamide gel electrophoresis of the final fraction showed that this polypeptide represented 35% of the total protein. We propose that this polypeptide is likely to be the adenylate cyclase catalytic subunit. This enzyme would represent close to 0.5% of the synaptosomal membrane proteins. Its low turnover number would be due to the absence of the alpha subunits of the NS regulatory proteins and would correspond to the enzymic basal level.

Calcium binding of arterial tropomyosin: involvement in the thin filament regulation of smooth muscle

Bovine aortic tropomyosin has been isolated by DEAE-Sepharose chromatography following isoelectric precipitation and ammonium sulfate fractionation. A single polypeptide [Mr 36 000 on a sodium dodecyl sulfate (SDS)-polyacrylamide gel] was obtained under different electrophoretic conditions. The amino acid composition of bovine tropomyosin was very similar to that of rabbit skeletal muscle; the amino-terminal residue is blocked. The molecular weight of the native tropomyosin (76 000), which is twice that calculated from the SDS-polyacrylamide gel, suggests that the molecule is a dimer. The diffusion coefficient of 3.4 X 10(-7) cm2 s-1 and the frictional coefficient of 1.7 indicate that the molecule is asymmetric. Comparative high-pressure liquid chromatography peptide mapping of rabbit skeletal and bovine aortic tropomyosins shows primary structure variation. Bovine aortic tropomyosin binds calcium under physiological conditions of pH and ionic strength (22 mol of Ca2+/mol of tropomyosin with a Kd of 1.4 mM). Such a property is not shared by skeletal tropomyosin. In low Mg2+ concentration, both skeletal and aortic actin activations of the skeletal myosin ATPase activity are calcium independent. Addition of aortic tropomyosin to a hybrid actomyosin (aortic actin, skeletal myosin) yields an enhancement of the actin activation of the myosin ATPase activity, but the addition of skeletal tropomyosin yields a decrease of this activity. However, both the enhancement and decrease are calcium dependent. Addition of skeletal or aortic tropomyosin to an actomyosin system, where both actin and myosin come from skeletal muscle, yields only an enhancement of the actin activation of the myosin ATPase activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Preparation and characterization of bovine aortic actin

A functional vascular smooth-muscle actin from bovine aorta was purified to homogeneity by an original method and was able to polymerize. Aortic actin is composed of two major isoforms and at least two minor ones. This actin was not phosphorylated by either cyclic AMP-dependent protein kinase or C kinase. The physical properties of aortic actin were found to be very similar to those of skeletal-muscle actin, except for amino acid composition (three tryptophan residues instead of four). The aortic actin and skeletal-muscle actin differ in the extent of activation of the Mg-dependent ATPase of skeletal-muscle myosin.

Search for promoter sites of prokaryotic DNA using learning techniques

Using learning techniques previously described in this journal, we have built an expert system able to point to the start DNA point of a sequence and therefore to recognize a promoter. However, to build this system, we have focused on the TATA box and its environment. We have used this expert system to look for new promoters and also to construct new promoters. The results obtained are discussed.

Computer search of calcium binding sites in a gene data bank: use of learning techniques to build an expert system

Using a learning set of 28 sequences able to bind calcium (each sequence is 12 residues long), we have built two filters by learning on this set. The first filter uses a pattern-matching technique and the second one takes into account the environment of amino-acids. These two filters have been used to find new calcium-binding proteins in a data bank. The results are discussed.

Zinc ion binding to human brain calcium binding proteins, calmodulin and S100b protein

Comparative studies have been performed on the binding properties of zinc ions to human brain calmodulin and S100b protein. Calmodulin is characterized by two sets of Zn2+ binding sites, with KD ranging from 8.10(-5)M to 3.10(-4)M. The S100b protein also exhibited two sets of zinc binding sites, with a much higher affinity. KD = 10(-7) - 10(-6)M. We suggest that S100b protein should no longer be considered only as a "calcium binding protein" but also as a "zinc binding protein", and that Zn2+ ions are involved in the functions of the S100 proteins.

Phosphorylation and the control of calcium fluxes

Cell activation, e.g. stimulus-contraction or stimulus-secretion coupling, is brought about by a 100-fold increase in cytosolic free Ca2+ concentration from 0.1 to 10 microM, upon release of Ca2+ from intrareticular or extracellular stores along the concentration gradient. A return to steady state is achieved by either Na+-Ca2+ exchange or ATP-dependent Ca2+ transport against the concentration gradient. Both processes, Ca2+ influx and Ca2+ efflux, are regulated by sophisticated covalent mechanisms. The positive inotropic effect of adrenalin is mediated by the cyclic-AMP-dependent phosphorylation of cardiac sarcolemmal proteins, among which calciductin is the major phosphate acceptor. Upon cyclic-AMP-dependent phosphorylation, the slow Ca2+ channel is activated 3.5 time above its basal low-conductance state, and retains its characteristics, competition by divalent metals, inhibition by La3+ and Ca2+ entry blockers. The adrenalin-induced abbreviation of systole is also explained in terms of the dual phosphorylation of the cardiac sarcoplasmic reticulum calcium pump activator, phospholamban, by cyclic-AMP-dependent protein kinase on the one hand and Ca2+-calmodulin-dependent phospholamban kinase on the other. Calciductin and phospholamban are closely similar acidic proteolipids. A phospholamban-like protein is also found in platelet Ca2+-accumulating vesicles, where its cyclic-AMP-dependent phosphorylation doubles the rate of Ca2+ efflux. These observations raise the possibility that calcium fluxes are regulated by phosphorylation of membrane-bound proteolipids. More generally, phosphorylation modulates K+, Na+ and Ca2+ fluxes through membranes, i.e. the general excitability properties of the cell.

Ion binding to calmodulin. A comparison with other intracellular calcium-binding proteins

Over the past few years calcium has emerged as an important bioregulator. Upon external stimulation, the cell generates a transient Ca2+ increase, which is transformed into a cellular event through a molecular cascade. The first step in this cascade is the binding of calcium to proteins present in the cytosol. These proteins capable of binding Ca2+ under physiological conditions all belong to the same evolutionary family that evolved from a common ancestor. However, they strongly differ in the properties of their calcium binding sites. Calmodulin, the ubiquitous calcium binding protein present in all eukaryotic cells, is very close to the ancestor protein, presents four calcium binding sites which bind calcium, magnesium and monovalent ions competitively and is involved in the triggering of cellular processes. Parvalbumin, another member of the family, is more specialized and found mostly in fast-twitch skeletal muscle. It binds calcium and magnesium with high affinity and seems to be involved in muscle relaxation. On the other hand, troponin C which confers Ca2+ sensitivity to acto-myosin interaction exhibits both triggering and relaxing sites. The study of intracellular Ca2+ binding proteins has shown that calcium binding proteins have evolved from a simple common structure to fulfill different functions.

Effects of cations on affinity of calmodulin for calcium: ordered binding of calcium ions allows the specific activation of calmodulin-stimulated enzymes

The acid stability of calmodulin has been used to devise a rapid and efficient method of decalcification based on trichloroacetic acid precipitation. Study of the competitive binding of K+, Mg2+, and Ca2+ to the Ca2+-binding sites of calmodulin has allowed determination of the intrinsic binding constants of each of the three cations for the four Ca2+-binding sites. The data are compatible with an ordered binding of Ca2+. If the Ca2+ sites are labeled A, B, C, and D starting at the NH2 terminus, the order of binding is postulated to be B, A, C, and D. The ordered binding properties support the suggestion that calmodulin translates quantitative Ca2+ signals into qualitatively different cellular responses.

Xenopus laevis oocyte calmodulin in the process of meiotic maturation

Calcium ions are postulated to be involved in the process of meiotic maturation of amphibian oocytes. Since several of the calcium effects in eukaryotic cells are mediated by calmodulin, the present study was undertaken to assess the presence and level of calmodulin in Xenopus laevis oocytes before and after progesterone treatment. Calmodulin was shown to be present at a concentration of approximately microM in control oocytes cytosol. This level remained stable for 2 h when the maturation promoting factor appeared, and increased to approximately 44 to 59 microM at the time of the germinal vesicle breakdown. Maturation is therefore associated with calmodulin synthesis. Xenopus calmodulin was isolated from oocyte cytosol after heat treatment, anion exchange chromatography, and gel filtration, with a yield of approximately 23%. When compared to mammalian calmodulins, the amphibian protein exhibited the same ultraviolet absorption spectrum, a similar amino acid composition with 1 residue of trimethyllsine, and the same shape conformers in the absence or presence of divalent metals, as shown by different mobilities upon dodecyl sulfate-polyacrylamide gel electrophoresis. The protein migrated faster in the presence than in the absence of Ca2+ ions, Mn2+ and Mg2+ being less effective. It was able to activate calmodulin-deficient myosin light chain kinase. Its high serine content and the tryptic peptide maps obtained after high performance liquid chromatography point, however, to minor differences in the primary structures of mammalian and amphibian calmodulins.

Evolutionary diversification of structure and function in the family of intracellular calcium-binding proteins

The maximum parsimony method was used to reconstruct the genealogical history of the family of intracellular calcium-binding proteins represented by six major present-day lineages, three of which--calcium dependent modulator protein, heart and skeletal muscle troponin Cs, and alkali light chains of myosin--were found to share a closer kinship with one another than with the other lineages. Similarly, parvalbumins and regulatory light chains of myosin were depicted as more closely related, whereas the branch of intestinal calcium-binding protein proved to have the most distant separation. The computer-generated amino acid sequence for the common ancestor of these six lineages described a four domain protein in which each domain of approximately 40 amino acid residues had a mid-region. 12 residue segment that bound calcium and had properties most resembling those of the calcium dependent modulator protein. It could then be deduced that parvalbumins evolved by deletion of domain I, inactivation of calcium-binding properties in domain II, and acquisition of increased affinity for Ca++ and Mg++ in domains III and IV. Regulatory light chains of myosin lost the cation binding property from three domains, retaining it in I, whereas alkali light chains of myosin lost this ability from each of the four domains. In skeletal muscle troponin C all domains retained their calcium-binding activity; however, like parvalbumins, domains III and IV acquired high affinity properties. Cardiac troponin C lost its binding activity from domain I but otherwise resembled the skeletal muscle form. Finally, intestinal calcium-binding protein evolved by deletion of domains III and IV. Positive selection could be implicated in these evolutionary changes in that the rate of fixation of mutations substantially increased in the mid portions of those domains which were loosing calcium-binding activity. Likewise, when the cation binding sites were changing from low to high affinity, an accelerated rate of fixed mutations was observed. Once this new functional parameter was selected these regions showed a remarkable conservatism, as did those binding sites which were maintaining the lower affinity. Moreover even in sequence regions not directly involved in cation binding, the lineage of troponin C because very conservative over the past 300 million years, perhaps becuase of the necessity for maintaining specific interfaces in order for the molecule to interact with troponin I and T in a functional thin myofilament. A similar phenomenon was observed in domain II of the regulatory light chains of the myosin lineage suggesting a possible binding site with the heavy chain of myosin.

Calcium and magnesium binding by parvalbumin. A proton magnetic resonance spectral study

Proton magnetic resonance spectroscopy has been used to monitor the kinetics and nature of the conformational transitions induced by binding of calcium and magnesium to carp parvalbumin. Rate constants have been determined for the exchange between the cation dependent conformational states of the protein in solution. These data enable a description of the kinetics and mechanism controlling the calcium flux in vivo during contraction.

Binding of calcium by parvalbumin fragments

Parvalbumin fragments from carp pI 4.47 parvalbumin corresponding to its residues 1--75 and 76--108 bind Ca2+ with affinities corresponding to Kd 0.9 . 10(-4) M and Kd 3 . 10(-3) M, respectively.