Calcium-Stimulated Proteolysis in Myelin: Evidence for a Ca2+-Activated Neutral Proteinase Associated with Purified Myelin of Rat CNS

Incubation of myelin purified from rat spinal cord with CaCl2 (1-5 mM) in 10-50 mM Tris-HCl buffer at pH 7.6 containing 2 mM dithiothreitol resulted in the loss of both the large and small myelin basic proteins (MBPs), whereas incubation of myelin with Triton X-100 (0.25-0.5%) and 5 mM EGTA in the absence of calcium produced preferential extensive loss of proteolipid protein (PLP) relative to MBP. Inclusion of CaCl2 but not EGTA in the medium containing Triton X-100 enhanced degradation of both PLP and MBPs. The Ca2+-activated neutral proteinase (CANP) activity is inhibited by EGTA (5 mM) and partially inhibited by leupeptin and/or E-64c. CANP is active at pH 5.5-9.0, with the optimum at 7-8. The threshold of Ca2+ activation is approximately 100 microM. The 150K neurofilament protein (NFP) was progressively degraded when incubated with purified myelin in the presence of Ca2+. These results indicate that purified myelin is associated with and/or contains a CANP whose substrates include MBP, PLP, and 150K NFP. The degradation of PLP (trypsin-resistant) in the presence of detergent suggests either release of enzyme from membrane and/or structural alteration in the protein molecule rendering it accessible to proteolysis. The myelin-associated CANP may be important not only in the turnover of myelin proteins but also in myelin breakdown in brain diseases.     

The amino-terminal hydrophobic region of the small subunit of calcium-activated neutral protease (CANP) is essential for its activation by phosphatidylinositol

Ca2+-Activated neutral protease (CANP), that consists of 80K and 30K subunits, is converted to a low-Ca2+-requiring form by autolysis in the presence of Ca2+. Phosphatidylinositol greatly reduces the Ca2+-requirement for the autolysis of native CANP. However, this effect was not observed for CANP with a trimmed 30K subunit lacking the NH2-terminal hydrophobic and glycine-rich region. This suggests that the NH2-terminal hydrophobic region of the 30K subunit is important for the interaction of CANP with the cell membrane and that the calcium sensitivity of CANP is increased at the cell membrane through the effect of phosphatidylinositol.     

Purification and characterization of a calcium-activated neutral protease from rabbit skeletal muscle which requires calcium ions of microM order concentration

One form of calcium-activated neutral protease (CANP) highly sensitive to calcium ions was purified by column chromatographic procedures to homogeneity. The purified enzyme required microM order Ca2+ (mu CANP), and the half-maximum activity was attained at 50 microM Ca2+. The electrophoretic mobility in a non-denaturing buffer showed that this enzyme is less acidic than another CANP which required mM order Ca2+ (mCANP). On SDS-polyacrylamide gel electrophoresis, the enzyme separated into two components with molecular weights of 79,000 and 28,000, respectively. Of these, the former was slightly larger than the counterpart of mCANP (Mr 76,000). Thus, mu CANP cannot be derived from mCANP by limited autolysis.     

Calcium-induced localization of calcium-activated neutral proteinase on plasma membranes

The location of calcium-activated neutral proteinase (CANP) was determined in human erythrocytes by crosslinking CANP to co-localizing proteins using a photolabeling bifunctional reagent, 4,4'-dithiobisphenylazide (DTBPA). The crosslinked products were selectively isolated by immunoprecipitation with a polyclonal anti-CANP antibody and analyzed by SDS-polyacrylamide gel electrophoresis after cleavage of the crosslinkage. In the calcium-free incubation medium the main proteins crosslinked with CANP were cytosolic proteins such as hemoglobin. In the presence of calcium ions, on the other hand, membrane skeletal proteins such as spectrin, band 4.1, 4.2 and 6 proteins as well as band 3 were crosslinked with CANP. Addition of calcium ionophore further increased the amount of crosslinked membrane proteins. These results suggest that in the absence of calcium ions CANP exists diffusely in the cytoplasm and is crosslinked with cytoplasmic hemoglobin nonspecifically while in the presence of calcium ions CANP associated with membrane where it is crosslinked specifically with the lining proteins. Thus it is demonstrated biochemically that the localization of CANP is dynamic depending on the presence of calcium ions.     

Autolytic activation of calcium-activated neutral protease

Degradation of vimentin by native low calcium ion-requiring protease (mu CANP) was compared to that by autodigested mu CANP. On activation with 5 mM barium ions, a lag time was observed for the case of native mu CANP. This provides direct evidence that native mu CANP is inactive as a protease and must be autolyzed to be activated. Most of the protease activity can be accounted for by autodigested mu CANP with a 76 K polypeptide but another species with 50 K polypeptide may also be active.     

Fragmentation of an endogenous inhibitor upon complex formation with high- and low-Ca2+-requiring forms of calcium-activated neutral proteases

The interaction of an endogenous inhibitor for the calcium-activated neutral protease (CANP or calpain EC 3.4.22.17) with CANP was examined by SDS-polyacrylamide gel electrophoresis, immunoblot analysis, and gel filtration. Fragmentation of the inhibitor (Mr 110K) by mCANP, a high-Ca2+-requiring form, was shown only in the presence of Ca2+ ions of millimolar order, with decreased inhibitor activity recovered from gel extracts in the 110-kDa area. This fragmentation took place even when the inhibitor could completely inhibit the caseinolytic activity of mCANP. The fragmented inhibitor retained considerable inhibitor activity after the CANP-inhibitor complex was dissociated by the addition of EDTA, and 69% of the initial activity was recovered from the mixture reacted with excess mCANP lacking the 110-kDa band. A C-terminal fragment of CANP inhibitor produced in Escherichia coli (Mr 40K) was also hydrolyzed by mCANP in the presence of Ca2+. The interaction of both forms of the inhibitor with mu CANP, a low-Ca2+-requiring form, led to the same phenomena in the presence of micromolar levels of Ca2+. CANP inhibitor could not completely inhibit the autolysis of mCANP and mu CANP, indicating that these were intramolecular events. Gel filtration analysis revealed that the mass of the smallest fragment with inhibitor activity was about 15,000 daltons. These results suggest that CANP inhibitor may act in the manner of a suicide substrate.     

Effect of metal ions on the structure and activity of calcium-activated neutral protease (CANP)

To clarify the mechanism of activation of calcium activated neutral protease (CANP, or mCANP: active at mM Ca2+), the structure of mCANP was examined by measuring CD spectra and by titration of SH groups in the presence of Mn2+. Mn2+ significantly increases the sensitivity of CANP to Ca2+ but CANP is not active with Mn2+ alone. The structural changes induced by Mn2+ were compared with those induced by Ca2+, and the structure of muCANP, which is active at microM Ca2+, was also examined for comparison. Mn2+ and Ca2+ induced the same structural changes of CANP. However, specific activation of the active site SH group by Ca2+ was not observed with Mn2+. Six moles of calcium bound to mCANP and the average dissociation constant of Ca2+ was 150 microM. The structure of muCANP was similar to that of mCANP in terms of the CD spectra. The titration of SH groups of muCANP indicated that the structure of muCANP was looser or SH groups were more exposed than in the case of mCANP. A model which can explain the activation of mCANP is proposed and the mechanism of activation is discussed based on the proposed model. The role of Ca2+ can be explained in terms of conformational change and activation of the active-site SH group of CANP.     

Limited autolysis of Ca2+-activated neutral protease (CANP) changes its sensitivity to Ca2+ ions

Ca2+-activated neutral protease (CANP) usually requires mM Ca2+ for activation. The sensitivity of CANP to Ca2+ is greatly enhanced by passing it through a casein-Sepharose column in the presence of Ca2+ ions. This conversion is ascribed to autolysis of CANP. The converted enzyme required 40 microM Ca2+ for 50% activation. Various properties of the converted enzyme were very similar to those of CANP-I, recently found in canine heart muscle. Names of "m-CANP" and "mu-CANP" are proposed for CANPs which require mM and microM order Ca2+ for inactivation, respectively.     

Identification of Ca2+-Activated Neutral Protease in the Peripheral Nerve and Its Effects on Neurofilament Degeneration

Rat sciatic nerve segments were incubated in five different media. Disappearance of neurofilament (NF) triplet proteins (200K, 160K, and 68K MW) occurred in medium containing Ca²⁺ and was inhibited by the addition of E-64-c or leupeptin. Therefore, the presence in the peripheral nerve of an enzyme whose properties are similar to those of Ca²⁺-activated neutral protease (CANP) is suggested. The extraction of crude CANP from rat sciatic nerve was performed. CANP activity was completely recovered (0.129 ± 0.008 U/g) in the precipitate salted out by the addition of 0 to 50% saturated ammonium sulfate to the soluble fraction of the peripheral nerve (crude CANP). Properties of the crude CANP were examined using NF as a substrate and were found to be similar to those of the CANP extracted from skeletal muscle. Identification of the crude CANP with the CANP extracted from rat skeletal muscle was performed using the immunoreplica method. Bands corresponding to 73K were detected in both CANPs.     

Comparison of calcium-activated neutral proteases from skeletal muscle of rabbit and chicken

Calcium-activated neutral proteases (CANPs) were purified from rabbit skeletal muscle and chicken skeletal muscle, and compared as to their electrophoretic properties, metal requirements, subunit amino acid compositions and immunological cross-reactivities. Two kinds of CANPs (mu CANP and mCANP) were isolated from rabbit but the chicken tissue lacked one corresponding to mu CANP. They were acidic in the order of chicken mCANP, rabbit mCANP, and rabbit mu CANP but the difference between the former two was very small. All of them were composed of two subunits, so-called 80K and 30K subunits. The molecular weight of the 30K subunit was the same for these CANPs (28K) but those of the 80K subunit were different (79K for rabbit mu CANP, 75K for rabbit mCANP and 81K for chicken mCANP). The calcium-sensitivity of chicken mCANP was very high when compared with that of rabbit mCANP and close to that of rabbit mu CANP. Antisera against chicken CANP and those against rabbit CANP cross-reacted with rabbit CANP and chicken CANP, respectively, when examined by immunoelectrotransfer blot techniques.     

Comparison of low and high calcium requiring forms of the calcium-activated neutral protease (CANP) from rabbit skeletal muscle

Two distinct calcium-dependent neutral proteases (CANPs) with different sensitivities to calcium ions were purified concurrently by almost the same procedures from rabbit skeletal muscle and their enzymatic properties were compared (sensitivity to various divalent metal ions, the pH dependency and heat-stability of the activity, and the hydrolytic activity towards various substrates). They were further compared chemically in terms of the state of thiol groups, the amino acid compositions of subunits and the peptide fragments by digestion with S. aureus V8 protease. The low calcium requiring form of CANP (microCANP) was more sensitive to other divalent metal ions such as Sr2+ and Ba2+ than the high calcium requiring form of CANP (mCANP). The comparison of the pH dependency of these CANP activities showed that microCANP was active in a broader pH range than mCANP and the former was more heat-stable than the latter. Both CANPs had similar affinity to various substrates, but the hydrolytic velocity was several times higher with microCANP than with mCANP. Although they were inhibited by thiol protease inhibitors to the same extent, the states of thiol groups in them were quite different. The thiol group involved in the catalytic activity of the enzyme was exposed without adding Ca2+ in microCANP, whereas the group in mCANP became exposed only when sufficient Ca2+ was added. The large subunits of these two CANPs were different in their amino acid compositions and in the peptide fragment patterns produced by S. aureus V8 protease but the small subunits were indistinguishable from each other. These results led us to conclude that these two CANPs are quite different in nature and are not in a simple relationship, i.e., one of them is not derived from the other by autolysis or modification.     

Identification of two new calcium dependent hydrolases in the human heart

We have identified and isolated two new calcium-activated neutral hydrolases from human ventricular muscles. The one is an esterase, of which molecular weight was 300,000, required millimolar concentration of Ca2+, hydrolyzed Ac-Tyr-OEt X H2O, optiaml pH at 7.0. The other is an amidase, of which molecular weight was 70,000, also required millimolar concentration of Ca2+, hydrolyzed a synthetic substrate for chymotrypsin, Suc-Leu-Leu-Val-Tyr-MCA, with optimal pH at 7.2. Both enzymes did not degrade casein or contractile proteins (myosin, actin, troponin and tropomyosin). Their activities were not inhibited by exogenous protease inhibitors, leupeptin, antipain, monoiodoacetic acid and chymostatin, while the amidase activity was blocked by the endogenous inhibitor against calcium-activated neutral protease (CANP). Thus, their characters are different from chymotrypsin or CANP and they seems to be new hydrolases in the human heart.     

Calcium-activated neutral protease effects upon skeletal muscle sarcoplasmic reticulum protein structure and calcium release.

In this study, the effects of Ca(2+)-activated neutral protease (CANP) upon skeletal muscle heavy sarcoplasmic reticulum (HSR) structure and function were investigated. CANP was immunolocalized to the 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid detergent-insoluble fraction of purified HSR membranes. Ca2+ activation of the endogenous membrane-bound CANP produced a characteristic partial fragmentation of the HSR 565-kDa Ca2+ release channel. Similarly, the major substrate for both micromolar and millimolar Ca(2+)-sensitive isoforms of exogenous CANP was the Ca2+ release channel with proteolysis of a 88-kDa HSR protein also observed. Ca2+ release channel proteolysis was initiated at a single cleavage site with coincidental production of 410- and 150-kDa peptide fragments. Appearance of 160- and 137-kDa limiting peptides accompanied secondary proteolysis of the primary 410- and 150-kDa fragments, respectively. Despite extensive proteolysis of the Ca2+ release channel, CANP did not dramatically alter the Ca2+ handling and ryanodine binding properties of HSR membranes. The association of CANP with isolated HSR membranes suggests that, in vivo, this protease may modify an additional property of the Ca2+ release channel. This may be related to the CANP-susceptible structural association of the Ca2+ release channel with dihydropyridine receptors at T-tubule/sarcoplasmic reticulum junctions.     

Ba2+ ions block K+-induced contractures by antagonizing K+-induced membrane depolarization in frog skeletal muscle fibres

The effects of Ba2+ ions on twitches, K+-induced contractures, and on intracellularly recorded membrane potentials (Em) and depolarizations of frog skeletal muscle fibres were investigated. Exposure of toe muscles to choline--Ringer's solution with 10(-3) M Ba2+ with Ca2+ (1.08 mM) eliminated or very greatly reduced contractures produced by 60 mM K+. In contrast, not only did the same concentration of Ba2+ ions fail to depress the twitch tension of isolated semitendinosus fibres when added to Ringer's with Ca2+, but it even restored twitches that had been eliminated in a zero Ca2+ Ringer's solution. The resting Em of sartorius muscle fibres in choline--Ringer's solution was reduced about 20 mV by 10(-3) M Ba2+. This Ba2+ ion concentration also antagonized the K+-induced depolarization. Thus in the presence of 1 mM Ba2+, 20 mM K+ hyperpolarized rather than depolarized the fibres and 60 or 123 mM K+ produced only very slowly developing, small depolarizations. These results suggest that the loss of the K+-induced contracture in choline-Ringer's caused by Ba2+ ions is due to an inhibition of the K+-induced depolarization. The latter result is consistent with previous findings of other workers that Ba2+ ions block membrane K+ channels.     

Degradation of myelin basic protein by calcium-activated neutral protease (CANP) in human brain and inhibition by E-64 analogue

A calcium-activated neutral protease (CANP) was extracted from human brain and partially purified. The activity was measured using alkali-denatured casein (Hammersten) as a substrate. The optimum pH was around 7.0. The activity required the presence of calcium ions, maximum activity was obtained with over 5 mM calcium ions. TheK _m for the casein concentration was about 1.62 mg/ml. The activity of CANP was inhibited by one of the thiol protease inhibitors, E-64 analogue (E-64-a). The rate of inhibition was about 50% at an E-64-a concentration of 10^–5M. This CANP degraded selectively basic protein in myelin proteins and the degradation was inhibited by E-64-a or EGTA. The role of the brain CANP in the process of demyelination was suggested by this study.     

A low-calcium-requiring calcium-activated neutral proteinase from human placenta

A low-calcium-requiring calcium-activated neutral proteinase (mu CANP) has been purified to homogeneity from human placenta. The purification procedure includes chromatography on DEAE-cellulose, Ultrogel AcA-22 and DEAE-Sephadex in succession. The purified mu CANP is a thiol proteinase and requires calcium for activity. Half-maximal activation occurs at 40 microM calcium. It is a heterodimer with subunits of 74 kDa and 32 kDa. (The placental mCANP has subunits of 70 kDa and 32 kDa.) Mn2+ or Sr2+, in combination with Ca2+, activates the enzyme synergistically. The presence of both mCANP and mu CANP in equal proportion in human placenta is reported for the first time. This will facilitate a comparative study of these two forms of human calcium-activated neutral proteinase, especially their physiological structural and functional interrelationship. Maximal activation of the autolysed mCANP occurs at a calcium concentration much higher than that for mu CANP; and this autolysed mCANP does not cross-react with antiserum against mu CANP, suggesting that the two forms of proteinase are independent species.     

Regulation of the calcium-activated neutral proteinase (CANP) of bovine brain by myelin lipids

Since calcium-activated neutral proteinase (CANP; calpain) activation occurs at the plasmalemma and the enzyme is found in myelin, we examined myelin lipid activation of brain CANP. Purified lipids were dried, sonicated and incubated with purified myelin CANP. The CANP was assayed using [14C]azocasein as substrate and the Ca2+ concentration ranged from 2 microM for muCANP to 5 mM for mCANP. Phosphatidylinositol (PI), phosphatidylserine (PS) and dioleoylglycerol stimulated the mCANP activity by 193, 89 and 78%, respectively. PI stimulated both m- and muCANP in a concentration-dependent manner, while phosphatidylcholine was least effective. Cerebroside and sulfatide at higher concentrations (750 microM) were stimulatory. The phospholipid (PL)-mediated activation was inhibited by the PL-binding drug trifluoperazine. PI reduced the Ca2+ requirement for CANPs significantly (20-fold). These results suggest that acidic lipids and particularly acidic phospholipids activate membrane CANP.     

Purification of a calcium-activated neutral proteinase from bovine brain

A calcium-activated neutral proteinase (CANP) resolved into three components has been partially purified from bovine brain. The method of isolation has resulted in 22,000, 7,100, and 8,000-fold purification for CANP I, II and III respectively. All three fractions require Ca2+ for activation. The characterization of the purified CANP I has shown that it is activated by 250 microM Ca2+ and the enzyme loses its activity when incubated in the presence of Ca2+ without substrate. Mg2+ is ineffective. The enzyme degrades neurofilament triplet proteins, tubulin and casein efficiently. The myelin basic protein is hydrolyzed after longer incubation. Bovine serum albumin and histones are unaffected. The enzyme is active at pH 5.5 to 9.0 with optimum between pH 7.5 and 8.5. It has a Km of 1.8 X 10(-7) M for the 69,000 dalton neurofilament protein. The enzyme is inhibited by sulphydryl blocking reagents and also by EGTA, leupeptin and E-64c. The SDS-PAGE analysis of the enzyme fractions has shown a major band at 66-68,000 daltons and two minor bands at 60,000 and 48-50,000 daltons for CANP I; a major band at 48-50,000 daltons and a minor band at 30-32,000 daltons for CANP II and a predominant doublet at 30-32,000 daltons with a minor band at 48-50,000 daltons for CANP III. The degradation of neurofilament proteins suggests that the CANP(s) may be involved in the turnover of these proteins.     

Calcium-activated neutral protease purified from beef lung: properties and use in defining structure of epidermal growth factor receptors

Ca2+-Requiring proteases degrade cytosolic and integral membrane proteins as well as alter, by limited proteolysis, the activity of certain protein kinases. When cells are lysed, a Ca2+-requiring protease degrades the epidermal growth factor (EGF) receptor, an integral membrane protein with an intrinsic kinase activity, from its 170-kDa form to a 150-kDa form. This Ca2+-requiring protease has all of the characteristics of calcium-activated neutral protease (CANP). To show that CANP is the protease uniquely responsible for the degradation of the native EGF receptor in vitro, CANP was highly purified from beef lung. This affinity purified CANP had properties previously described for other CANPs: heterodimer of 80 and 30 kDa; neutral pH optimum; activation by millimolar Ca2+; and inhibition by an endogenous, heat-stable proteinaceous inhibitor, by leupeptin, and by sulfhydryl alkylating agents. Using the EGF receptor labeled by covalent attachment to 125I-EGF, this purified CANP quantitatively generated the 150-kDa form from the native receptor in A-431 cell membranes. As with the native receptor, the 150-kDa receptor forms produced by the endogenous Ca2+-requiring protease, by CANP, by chymotrypsin, and by elastase were all capable of EGF-stimulated autophosphorylation. When the 150-kDa receptor forms were generated by the three exogenously added proteases, autophosphorylation with [gamma-32P]ATP followed by trypsinization produced 32P-labeled peptides that were not the same. However, the tryptic 32P-labeled peptides from the autophosphorylated 150-kDa receptor form produced by CANP or by the endogenous Ca2+-requiring protease were identical. These data indicate that CANP is identical to the endogenous Ca2+-requiring protease responsible for producing the autophosphorylating 150-kDa receptor form from the native EGF receptor when cells are lysed.     

Acetyl phosphate as a substrate for the calcium ATPase of sarcoplasmic reticulum

Acetyl phosphate is hydrolyzed by the calcium ATPase of leaky sarcoplasmic reticulum vesicles from rabbit skeletal muscle with Km = 6.5 mM and kcat = 7.9 s-1 in the presence of 100 microM calcium (180 mM K+, 5 mM MgSO4, pH 7.0, 25 degrees C). In the absence of calcium, hydrolysis is 6% of the calcium-dependent rate at low and 24% at saturating concentrations of acetyl phosphate. Values of K0.5 for calcium are 3.5 and 2.2 microM (n = 1.6) in the presence of 1 and 50 mM acetyl phosphate, respectively; inhibition by calcium follows K0.5 = 1.6 mM (n approximately 1.1) with 50 mM acetyl phosphate and K0.5 = 0.5 mM (n approximately 1.3) with 1.5 mM ATP. The calcium-dependent rate of phosphoenzyme formation from acetyl phosphate is consistent with Km = 43 mM and kf = 32 s-1 at saturation; decomposition of the phosphoenzyme occurs with kt = 16 s-1. The maximum fraction of phosphoenzyme formed in the steady state at saturating acetyl phosphate concentrations is 43-46%. These results are consistent with kc congruent to 30 s-1 for binding of Ca2+ to E at saturating [Ca2+], to give cE.Ca2, in the absence of activation by ATP. Phosphoenzyme formed from ATP and from acetyl phosphate shows the same biphasic reaction with ADP, rate constants for decomposition that are the same within experimental error, and similar or identical activation of decomposition by ATP. It is concluded that the reaction pathways for acetyl phosphate and ATP in the presence of Ca2+ are the same, with the exception of calcium binding and phosphorylation; an alternative, faster route that avoids the kc step is available in the presence of ATP. The existence of three different regions of dependence on ATP concentration for steady state turnover is confirmed; activation of hydrolysis at high ATP concentrations involves an ATP-induced increase in kt.