Limited tryptic digestion of Acanthamoeba myosin IA abolishes regulation of actin-activated ATPase activity by heavy chain phosphorylation

Acanthamoeba myosin IA is a globular protein composed of a 140-kDa heavy chain and a 17-kDa light chain. It expresses high actin-activated Mg2+-ATPase activity when one serine on the heavy chain is phosphorylated. We previously showed that chymotrypsin cleaves the heavy chain into a COOH-terminal 27-kDa peptide that can bind to F-actin but has no ATPase activity and a complex containing the NH2-terminal 112-kDa peptide and the light chain. The complex also binds F-actin and has full actin-activated Mg2+-ATPase activity when the regulatory site is phosphorylated. We have now localized the ATP binding site to within 27 kDa of the NH2 terminus and the regulatory phosphorylatable serine to a 20-kDa region between 38 and 58 kDa of the NH2 terminus. Under controlled conditions, trypsin cleaves the heavy chain at two sites, 38 and 112 kDa from the NH2 terminus, producing a COOH-terminal 27-kDa peptide similar to that produced by chymotrypsin and a complex consisting of an NH2-terminal kDa peptide, a central 74-kDa peptide, and the light chain. This complex is similar to the chymotryptic complex but for the cleavage which separates the 38- and 74-kDa peptides. The tryptic complex has full (K+, EDTA)-ATPase activity (the catalytic site is functional) and normal ATP-sensitive actin-binding properties. However, the actin-activated Mg2+-ATPase activity and the F-actin-binding characteristics of the tryptic complex are no longer sensitive to phosphorylation of the regulatory serine. Therefore, cleavage between the phosphorylation site and the ATP-binding site inhibits the effects of phosphorylation on actin binding and actin-activated Mg2+-ATPase activity without abolishing the interactions between the ATP- and actin-binding sites.     

Effects of limited tryptic cleavage on the physical and enzymatic properties of myosin II from Acanthamoeba castellanii

Limited digestion of Acanthamoeba myosin II by trypsin selectively cleaved the 185,000-Da heavy chains into a 73,000-Da peptide containing the catalytic and actin-binding sites and a 112,000-Da peptide containing the regulatory phosphorylatable sites. The light chains were unaffected. The proteolytic products remained associated and formed bipolar filaments that were very similar in appearance to filaments of native myosin by negative staining electron microscopy. Filaments of trypsin-cleaved, dephosphorylated myosin, however, had a smaller sedimentation coefficient than filaments of native dephosphorylated myosin. Trypsin-cleaved dephosphorylated myosin retained complete Ca2+-ATPase activity but had no actin-activated ATPase activity under conditions that are optimal for native, dephosphorylated myosin (pH 7.0, 4 mM MgCl2, 30 degrees C or pH 6.4, 1 mM MgCl2, 30 degrees C). Trypsin-cleaved dephosphorylated myosin had higher actin-activated ATPase activity at pH 6.0 and 1 mM MgCl2 than undigested dephosphorylated myosin which is appreciably inhibited under these conditions. Trypsin-cleaved, dephosphorylated myosin inhibited the actin-activated ATPase activity of native, dephosphorylated myosin when both were present in the same co-polymers, when enzymatic activity was assayed at pH 7.0, 4 mM MgCl2, and 30 degrees C, but this inhibition was overcome by raising the MgCl2 to 6 mM. These results provide additional evidence that regulation of acanthamoeba myosin II occurs at the filament level and that, under most conditions of assay, the heavy chains must be intact and the regulatory serines unphosphorylated for actin-activated ATPase activity to be maximally expressed.     

The effect of phosphorylation of gizzard myosin on actin activation

Gizzard myosin is phosphorylated by a kinase found in chicken gizzards. The 20,000 dalton light chains are the only subunits to show an appreciable extent of ³²P incorporation. Phosphorylation requires trace amounts of Ca²⁺. The Mg²⁺-ATPase activity of gizzard myosin in the phosphorylated form is activated to an appreciable extent by skeletal actin, whereas the activation of the non-phosphorylated myosin is verylow. These results suggest that the Ca²⁺-sensitive regulatory mechanism of gizzard actomyosin is mediated via a kinase. In the presence of Ca²⁺ the onset of contraction and the resultant increase of the Mg²⁺-ATPase activity we suggest is due, at least partly, to the phosphorylation of the 20,000 dalton light chains. Whether or not Ca²⁺ binding by myosin is also essential remains to be established.     

ATPase activities and actin-binding properties of subfragments of Acanthamoeba myosin IA

Previous studies had led to the conclusion that the globular, single-headed myosins IA and IB from Acanthamoeba castellanii contain two actin-binding sites: one associated with the catalytic site and whose binding to F-actin activates the Mg2+-ATPase activity and a second site whose binding results in the cross-linking of actin filaments and makes the actin-activated ATPase activity positively cooperative with respect to myosin I concentration. We have now prepared a 100,000-Da NH2-terminal peptide and a 30,000-Da COOH-terminal peptide by alpha-chymotryptic digestion of the myosin IA heavy chain. The intact 17,000-Da light chain remained associated with the 100,000-Da fragment, which also contained the serine residue that must be phosphorylated for expression of actin-activated ATPase activity by native myosin IA. The 30,000-Da peptide, which contained 34% glycine and 21% proline, bound to F-actin with a KD less than 0.5 microM in the presence or absence of ATP but had no ATPase activity. The 100,000-Da peptide bound to F-actin with KD = 0.4-0.8 microM in the presence of 2 mM MgATP and KD less than 0.01 microM in the absence of MgATP. In contrast to native myosin IA, neither peptide cross-linked actin filaments. The phosphorylated 100,000-Da peptide had actin-activated ATPase activity with the same Vmax as that of native phosphorylated myosin IA but this activity displayed simple, noncooperative hyperbolic dependence on the actin concentration in contrast to the complex cooperative kinetics observed with native myosin IA. These results provide direct experimental evidence for the presence of two actin-binding sites on myosin IA, as was suggested by enzyme kinetic and filament cross-linking data, and also for the previously proposed mechanism by which monomeric myosins I could support contractile activities.     

Deoxyribonuclease I binding masks the major tryptic cleavage sites on actin

The formation of a 1:1 molecular complex of deoxyribonuclease I with muscle G-actin protects both proteins against proteolytic attack by trypsin. After 1$\text{1}\text{2}$ hours of digestion, negligible proteolysis of the complex is observed by sodium dodecyl sulfate polyacrylamide gel electrophoresis, while G-actin alone is rapidly broken down to a trypsin resistant core. The binding of deoxyribonuclease I to actin apparently masks the major tryptic cleavage sites (arginine-62 and lysine-68) on the latter protein.     

The limited tryptic cleavage of chymotryptic S-1: an approach to the characterization of the actin site in myosin heads.

Limited tryptic proteolysis of S-1 (A₁+A₂) or S-1 (A₁) and S-1 (A₂) converts the heavy chain into 3 fragments of Mr = 27K-50K-20K. As a result the actin-stimulated ATPase activity of the fragmented heads is lost. When the digestion is performed using the complex F-actin-S-1, this ATPase activity is completely preserved and the heavy chain is split into only 2 fragments of Mr = 27K–70K. The specific protection by F-actin of the -COOH terminal region of the heavy chain at the joint 50K-20K against tryptic cleavage and loss of activity suggests that this part of the head can be involved in actin binding site and/or Mg²⁺ ATP hydrolysis by the acto-S-1 complex.     

Localization of the active site and phosphorylation site of Acanthamoeba myosins IA and IB

The 130- and 125-kDa heavy chains of Acanthamoeba myosins IA and IB were radioactively labeled at either the regulatory phosphorylation site or the catalytic site and then subjected to controlled proteolysis by either trypsin or chymotrypsin. The labeled and unlabeled peptides generated during the course of proteolysis were identified by autoradiography and Coomassie Blue staining after separation by electrophoresis on sodium dodecyl sulfate-polyacrylamide gels. The relative positions of the phosphorylation and active sites could be deduced. The catalytic site of myosin IA is most probably within 38 kDa of one end of the 130-kDa heavy chain, and the phosphorylation site, which can be no more than 40 kDa away from the catalytic site, would then be between 38 and 78 kDa of that same end of the heavy chain. Possibly, the phosphorylation site is further restricted to the region between 38 and 64 kDa from the end of the heavy chain. The catalytic and phosphorylation sites of myosin IB are both contained within a segment of 62 kDa at one end of the 125-kDa heavy chain and are within 40 kDa of each other. The phosphorylation site may be restricted to a small segment between 60 and 62 kDa from one end of the heavy chain which would limit the possible position of the catalytic site to the region between 20 and 60 kDa of that end.     

Localization and specificity of the phospholipid and actin binding sites on the tail of Acanthamoeba myosin IC

We used bacterially expressed beta-galactosidase fusion proteins to localize the phospholipid binding domain of Acanthamoeba myosin IC to the region between amino acids 701 and 888 in the NH2-terminal half of the tail. Using a novel immobilized ligand lipid binding assay, we determined that myosin I can bind to several different acidic phospholipids, and that binding requires a minimum of 5 mol% acidic phospholipid in a neutral lipid background. The presence of di- and triglycerides and sterols in the lipid bilayer do not contribute to the affinity of myosin I for membranes. We confirm that the ATP-insensitive actin binding site is contained in the COOH-terminal 30 kD of the tail as previously shown for Acanthamoeba myosin IA. We conclude that the association of the myosin IC tail with acidic phospholipid head groups supplies much of the energy for binding myosin I to biological membranes, but probably not specificity for targeting myosin I isoforms to different cellular locations.     

Identification of three phosphorylation sites on each heavy chain of Acanthamoeba myosin II

It has been previously demonstrated that the actin-activated Mg2+-ATPase activity of Acanthamoeba myosin II is inhibited by phosphorylation of its two heavy chains (Collins, J. H., and Korn, E. D. (1980) J. Biol. Chem. 255, 8011-8014). In this paper, it is shown that a partially purified kinase preparation from Acanthamoeba catalyzes the incorporation of 3 mol of phosphate into each mole of myosin II heavy chain. Tryptic digestion of the 32P-myosin, followed by two-dimensional peptide mapping, indicates that two of the three sites phosphorylated by the kinase in vitro correspond to the two major phosphorylation sites on the myosin heavy chain in vivo. Phosphorylation of myosin II in vitro by the kinase fraction completely inhibits the actin-activated Mg2+-ATPase activity of myosin II. Myosin II can be isolated in a highly phosphorylated, enzymatically inactive form, then dephosphorylated to an active form, and finally rephosphorylated to an inactive form. The Acanthamoeba kinase fraction catalyzes the phosphorylation of all three sites on the heavy chain of myosin II at virtually the same rate. From a comparison of the decrease in actin-activated Mg2+-ATPase activity with the amount of phosphate incorporated into myosin II, and from the results obtained previously by dephosphorylating myosin II (Collins, J. H., and Korn, E. D., (1980) J. Biol. Chem. 255, 8011-8014), it can be inferred that two of the sites phosphorylated in vitro act in a synergistic manner to inhibit the actin-activated myosin II Mg2+-ATPase.     

Regulation of the actin-activated ATPase activity of Acanthamoeba myosin I by cross-linking actin filaments

The actin-activated Mg2+-ATPase activity of phosphorylated Acanthamoeba myosin I was previously shown to be cooperatively dependent on the myosin concentration (Albanesi, J. P., Fujisaki, H., and Korn, E. D. (1985) J. Biol. Chem. 260, 11174-11179). This observation was rationalized by assuming that myosin I contains a high-affinity and a low-affinity F-actin-binding site and that binding at the low-affinity site is responsible for the actin-activated ATPase activity. Therefore, enzymatic activity would correlate with the cross-linking of actin filaments by myosin I, and the cooperative increase in specific activity at high myosin:actin ratios would result from the fact that cross-linking by one myosin molecule would increase the effective F-actin concentration for neighboring myosin molecules. This model predicts that high specific activity should occur at myosin:actin ratios below that required for cooperative interactions if the actin filaments are cross-linked by catalytically inert cross-linking proteins. This prediction has been confirmed by cross-linking actin filaments with either of three gelation factors isolated from Acanthamoeba, one of which has not been previously described, or by enzymatically inactive unphosphorylated Acanthamoeba myosin I.     

Effect of actin on the tryptic digestion of myosin subfragment 1 in the weakly attached state.

The structure of myosin subfragment 1 (S1) in the weakly attached complex with actin was studied at three specific sites, at the 50-kDa/20-kDa and 27-kDa/50-kDa junctions, and at the N-terminal region, using tryptic digestion as a structure-exploring tool. The structure of S1 at the vicinity of the 50-kDa/20-kDa junction is pH dependent in the weakly attached state because the tryptic cleavage at this site was fully protected by actin at pH 6.2, but the protection was only partial at pH 8.0. Since the actin protection is complete in rigor at both pH values, the results indicate that the structure of S1 at the 50-kDa/20-kDa junction differs in the two states at pH 8.0, but not at pH 6.2. Actin restores the ADP-suppressed tryptic cleavage after Lys213 at the 27-kDa/50-kDa junction in the strongly attached state, but not in the weakly attached state, which indicates structural difference between the two states at this site. ATP and ADP open a new site for tryptic cleavage in the N-terminal region of the S1 heavy chain between Arg23 and Ile24. Actin was found to suppress this cleavage in both weakly and strongly attached states, which shows that, in the vicinity of this site, the structure of S1 is similar in both states. The results indicate that the binding of S1 to actin induces localized changes in the S1 structure, and the extent of these changes is different in the various actin-S1 complexes.     

Subtilisin cleavage of actin inhibits in vitro sliding movement of actin filaments over myosin

Subtilisin cleaved actin was shown to retain several properties of intact actin including the binding of heavy meromyosin (HMM), the dissociation from HMM by ATP, and the activation of HMM ATPase activity. Similar Vmax but different Km values were obtained for acto-HMM ATPase with the cleaved and intact actins. The ATPase activity of HMM stimulated by copolymers of intact and cleaved actin showed a linear dependence on the fraction of intact actin in the copolymer. The most important difference between the intact and cleaved actin was observed in an in vitro motility assay for actin sliding movement over an HMM coated surface. Only 30% of the cleaved actin filaments appeared mobile in this assay and moreover, the velocity of the mobile filaments was approximately 30% that of intact actin filaments. These results suggest that the motility of actin filaments can be uncoupled from the activation of myosin ATPase activity and is dependent on the structural integrity of actin and perhaps, dynamic changes in the actin molecule.     

The effect of myosin light chain phosphorylation on the actin-stimulated ATPase activity of myosin minifilaments

It has been shown that in the absence of KCl, the actin-stimulated Mg2+-ATPase activity of rabbit skeletal myosin minifilaments with phosphorylated regulatory lights chains (LC2) exceeds 3-4-fold that of myosin minifilaments with dephosphorylated LC2. Addition of KCl leads to a decrease in the difference between the two ATPase activities. LC2 phosphorylation considerably increases the rate of ATPase reaction and only slightly decreases the affinity of myosin minifilaments for F-actin. It is suggested that the unusual effect of LC2 phosphorylation on the kinetic parameters of the actin-stimulated ATPase reaction of myosin minifilaments can be accounted for by its influence on the interaction between myosin heads which results in the ordered self-assembly of minifilaments.     

Light chain phosphorylation regulates the movement of smooth muscle myosin on actin filaments

In smooth muscles there is no organized sarcomere structure wherein the relative movement of myosin filaments and actin filaments has been documented during contraction. Using the recently developed in vitro assay for myosin-coated bead movement (Sheetz, M.P., and J.A. Spudich, 1983, Nature (Lond.)., 303:31-35), we were able to quantitate the rate of movement of both phosphorylated and unphosphorylated smooth muscle myosin on ordered actin filaments derived from the giant alga, Nitella. We found that movement of turkey gizzard smooth muscle myosin on actin filaments depended upon the phosphorylation of the 20-kD myosin light chains. About 95% of the beads coated with phosphorylated myosin moved at velocities between 0.15 and 0.4 micron/s, depending upon the preparation. With unphosphorylated myosin, only 3% of the beads moved and then at a velocity of only approximately 0.01-0.04 micron/s. The effects of phosphorylation were fully reversible after dephosphorylation with a phosphatase prepared from smooth muscle. Analysis of the velocity of movement as a function of phosphorylation level indicated that phosphorylation of both heads of a myosin molecule was required for movement and that unphosphorylated myosin appears to decrease the rate of movement of phosphorylated myosin. Mixing of phosphorylated smooth muscle myosin with skeletal muscle myosin which moves at 2 microns/s resulted in a decreased rate of bead movement, suggesting that the more slowly cycling smooth muscle myosin is primarily determining the velocity of movement in such mixtures.     

Effect of actin filament length and filament number concentration on the actin-activated ATPase activity of Acanthamoeba myosin I

The actin-activated Mg2+-ATPase activities of phosphorylated Acanthamoeba myosins IA and IB were previously found to have a highly cooperative dependence on myosin concentration (Albanesi, J. P., Fujisaki, H., and Korn, E. D. (1985) J. Biol. Chem. 260, 11174-11179). This behavior is reflected in the requirement for a higher concentration of F-actin for half-maximal activation of the myosin Mg2+-ATPase at low ratios of myosin:actin (noncooperative phase) than at high ratios of myosin:actin (cooperative phase). These phenomena could be explained by a model in which each molecule of the nonfilamentous myosins IA and IB contains two F-actin-binding sites of different affinities with binding of the lower affinity site being required for expression of actin-activated ATPase activity. Thus, enzymatic activity would coincide with cross-linking of actin filaments by myosin. This theoretical model predicts that shortening the actin filaments and increasing their number concentration at constant total F-actin should increase the myosin concentration required to obtain the cooperative increase in activity and should decrease the F-actin concentration required to reach half-maximal activity at low myosin:actin ratios. These predictions have been experimentally confirmed by shortening actin filaments by addition of plasma gelsolin, an F-actin capping/severing protein. In addition, we have found that actin "filaments" as short as the 1:2 gelsolin-actin complex can significantly activate Acanthamoeba myosin I.     

The effect of heavy chain phosphorylation and solution conditions on the assembly of Acanthamoeba myosin-II

At low ionic strength, Acanthamoeba myosin-II polymerizes into bipolar minifilaments, consisting of eight molecules, that scatter about three times as much light as monomers. With this light scattering assay, we show that the critical concentration for assembly in 50-mM KCl is less than 5 nM. Phosphorylation of the myosin heavy chain over the range of 0.7 to 3.7 P per molecule has no effect on its KCl dependent assembly properties: the structure of the filaments, the extent of assembly, and the critical concentration for assembly are the same. Sucrose at a concentration above a few percent inhibits polymerization. Millimolar concentrations of MgCl2 induce the lateral aggregation of fully formed minifilaments into thick filaments. Compared with dephosphorylated minifilaments, minifilaments of phosphorylated myosin have a lower tendency to aggregate laterally and require higher concentrations of MgCl2 for maximal light scattering. Acidic pH also induces lateral aggregation, whereas basic pH leads to depolymerization of the myosin- II minifilaments. Under polymerizing conditions, millimolar concentrations of ATP only slightly decrease the light scattering of either phosphorylated or dephosphorylated myosin-II. Barring further modulation of assembly by unknown proteins, both phosphorylated and dephosphorylated myosin-II are expected to be in the form of minifilaments under the ionic conditions existing within Acanthamoeba.     

The role of caldesmon and its phosphorylation by ERK on the binding force of unphosphorylated myosin to actin

Background

Studies conducted at the whole muscle level have shown that smooth muscle can maintain tension with low Adenosine triphosphate (ATP) consumption. Whereas it is generally accepted that this property (latch-state) is a consequence of the dephosphorylation of myosin during its attachment to actin, free dephosphorylated myosin can also bind to actin and contribute to force maintenance. We investigated the role of caldesmon (CaD) in regulating the binding force of unphosphorylated tonic smooth muscle myosin to actin.

Methods

To measure the effect of CaD on the binding of unphosphorylated myosin to actin (in the presence of ATP), we used a single beam laser trap assay to quantify the average unbinding force (F_unb) in the absence or presence of caldesmon, extracellular signal-regulated kinase (ERK)-phosphorylated CaD, or CaD plus tropomyosin.

Results

F_unb from unregulated actin (0.10 ± 0.01 pN) was significantly increased in the presence of CaD (0.17 ± 0.02 pN), tropomyosin (0.17 ± 0.02 pN) or both regulatory proteins (0.18 ± 0.02 pN). ERK phosphorylation of CaD significantly reduced the F_unb (0.06 ± 0.01 pN). Inspection of the traces of the F_unb as a function of time suggests that ERK phosphorylation of CaD decreases the binding force of myosin to actin or accelerates its detachment.

Conclusions

CaD enhances the binding force of unphosphorylated myosin to actin potentially contributing to the latch-state. ERK phosphorylation of CaD decreases this binding force to very low levels.

General significance

This study suggests a mechanism that likely contributes to the latch-state and that explains the muscle relaxation from the latch-state.     

Effect of tryptic cleavage on the stability of myosin subfragment 1. Isolation and properties of the severed heavy-chain subunit

The procedure of thermal ion-exchange chromatography has been used to examine the effect of prior tryptic cleavage on the stability of myosin subfragment 1 (SF1). Although it is found that digestion does destabilize the subunit interactions at physiological temperatures, the heavy-chain subunit can be isolated either as an equimolar complex comprised of 50K, 27K, and 21K fragments or as one comprised of 50K, 27K, and 18K peptides. Thus, the interactions within the heavy chain are considerably more stable than those between the two subunits. Both forms of the free severed heavy chain exhibit ATPase properties similar to those of the parent tryptic SF1. The Vmax for the actin-activated MgATPase of the free severed heavy chain is the same as that for both undigested and tryptic SF1 (A2). Since its Km for actin is similar to that of tryptic SF1(A2), it may be concluded that changes in the affinity of SF1 for actin induced by trypsin [Botts, J., Muhlrad, A., Takashi, R., & Morales, M. F. (1982) Biochemistry 21, 6903-6905] are not dependent on the presence of the associated alkali light chain. Furthermore, the communication between the SH1 site and the ATPase site is also shown to be independent of the associated alkali light chain, and it persists despite the cleavages present in the free heavy chain. Studies on the ability of these severed heavy chains to reassociate with free A1 and A2 chains indicate that the binding site is retained in the 21K-severed heavy chain but is lost in the 18K form.     

Quantitative analysis of the effect of Acanthamoeba profilin on actin filament nucleation and elongation

The current view of the mechanism of action of Acanthamoeba profilin is that it binds to actin monomers, forming a complex that cannot polymerize [Tobacman, L. S., & Korn, E. D. (1982) J. Biol. Chem. 257, 4166-4170; Tseng, P., & Pollard, T. D. (1982) J. Cell Biol. 94, 213-218; Tobacman, L. S., Brenner, S. L., & Korn, E. D. (1983) J. Biol. Chem. 258, 8806-8812]. This simple model fails to predict two new experimental observations made with Acanthamoeba actin in 50 mM KC1, 1 mM MgCl2, and 1 mM EGTA. First, Acanthamoeba profilin inhibits elongation of actin filaments far more at the pointed end than at the barbed end. According, to the simple model, the Kd for the profilin-actin complex is less than 5 microM on the basis of observations at the pointed end and greater than 50 microM for the barbed end. Second, profilin inhibits nucleation more strongly than elongation. According to the simple model, the Kd for the profilin-actin complex is 60-140 microM on the basis of two assays of elongation but 2-10 microM on the basis of polymerization kinetics that reflect nucleation. These new findings can be explained by a new and more complex model for the mechanism of action that is related to a proposal of Tilney and co-workers [Tilney, L. G., Bonder, E. M., Coluccio, L. M., & Mooseker, M. S. (1983) J. Cell Biol. 97, 113-124]. In this model, profilin can bind both to actin monomers with a Kd of about 5 microM and to the barbed end of actin filaments with a Kd of about 50-100 microM. An actin monomer bound to profilin cannot participate in nucleation or add to the pointed end of an actin filament. It can add to the barbed end of a filament. When profilin is bound to the barbed end of a filament, actin monomers cannot bind to that end, but the terminal actin protomer can dissociate at the usual rate. This model includes two different Kd's--one for profilin bound to actin monomers and one for profilin bound to an actin molecule at the barbed end of a filament. The affinity for the end of the filament is lower by a factor of 10 than the affinity for the monomer, presumably due to the difference in the conformation of the two forms of actin or to steric constraints at the end of the filament.     

Effect of pressure and calcium on the reversible inhibition of the sarcoplasmic-reticulum calcium-transport enzyme and on its tryptic cleavage pattern

The reversible inhibition of the sarcoplasmic-reticulum calcium-transport enzyme by pressure at room temperature is accompanied by a significant enhancement of the accessibility of the enzyme to tryptic cleavage dependent on the presence of calcium. The calcium-transport enzyme activity was monitored with dinitrophenyl phosphate as substrate. Pressure in the range 0.1-100.0 MPa affects trypsin cleavage of the control substrate N-alpha-benzoyl-L-arginine-4-nitroanilide hydrochloride little in the presence and absence of calcium. In contrast, application of 100.0 MPa to the calcium-transport enzyme at room temperature accelerates subsequent tryptic cleavage at the T2 but not at the T1 cleavage site [C. J. Brandl et al. (1986) Cell 44, 597-607]. Pressure application during tryptic digestion likewise solely affects cleavage at T2 which proceeds slowly in the absence but rapidly in the presence of calcium. At atmospheric pressure in the absence of calcium and at high pressure in the absence and presence of calcium new cleavage sites are exposed giving rise to new subfragments B1-3 in addition to the established peptides A1 and A2. Under pressure and in the presence of calcium, A1 and A2 rapidly disappear indicating the presence of calcium-binding sites in these peptides. In contrast, the B1-3 peptides which are most likely derivates of the B fragment accumulate in the presence and absence of calcium. In contrast to tryptic cleavage at atmospheric pressure, tryptic cleavage of the A as well as the B fragment tends to completion under pressure. In parallel to the disappearance of the A and B fragments calcium-dependent substrate hydrolysis vanishes. Computation of activation volumes for pressure-induced reversible enzyme inhibition and for tryptic cleavage furnished closely related volumes of opposite signs of 20-40 ml/mol and 80-100 ml/mol in the ranges 0.1-40.0 MPa and 40.0-100.0 MPa, respectively. Thus pressure produces reversible changes in the calcium-transport enzyme which activates and modifies tryptic-cleavage patterns at the T2 site of the A segment and at sites in its subfragments in the presence of calcium, i.e. if the enzyme residues in its E1 state. In contrast tryptic cleavage of the B fragment is accelerated by pressure independently of the presence of calcium.