Proteolytic activity associated with human erythrocyte membranes. Self-digestion of isolated human erythrocyte membranes

At least two kinds of enzymes are active in the proteolytic self-digestion of erythrocyte membranes. The specific activities of these enzymes do not decrease with repeated washings of purified stroma. The effects of a variety of inhibitors on the membrane preparation's capacity to digest ¹²⁵I-labelled casein, covalently linked to latex beads, have been examined.Pepstatin-inhibitable enzyme, active at low pH, digests the membrane extensively to small polypeptide fragments. Spectrin, located at the internal part of the membrane, is readily degraded. Diisopropylfluorophosphate-inhibitable enzyme, active at pH 8–9, has only limited digestive capacity. Some of the membrane components, such as the small molecular weight glycoproteins, are resistant to digestion. The restricted capacity of digestion is due to the membrane molecular arrangement; increased disaggregation removes the restriction and increases the activity. Spectrin is not digested unless the membrane topography is disrupted by NP-40 neutral detergent. These observations suggest that the enzymes active at basic pH are located external to the cell. Intact cells do possess a limited capacity to degrade ¹²⁵I-labelled casein when their surfaces are brought into contact with substrate-coated beads.     

Carboxypeptidase Y digestion of band 3, the anion transport protein of human erythrocyte membranes

The exposure of the carboxyl-terminal of the Band 3 protein of human erythrocyte membranes in intact cells and membrane preparations to proteolytic digestion was determined. Carboxypeptidase Y digestion of purified Band 3 in the presence of non-ionic detergent released amino acids from the carboxyl-terminal of Band 3. The release of amino acids was very pH dependent, digestion being most extensive at pH 3, with limited digestion at pH 6 or above. The 55,000 dalton carboxyl-terminal fragment of Band 3, generated by mild trypsin digestion of ghost membranes, had the same carboxyl-terminal sequence as intact Band 3, based on carboxypeptidase Y digestion. Treatment of intact cells with trypsin or carboxypeptidase Y did not release any amino acids from the carboxyl-terminal of Band 3. In contrast, carboxypeptidase Y readily digested the carboxyl-terminal of Band 3 in ghosts that were stripped of extrinsic membrane proteins by alkali or high salt. This was shown by a decrease in the molecular weight of a carboxyl-terminal fragment of Band 3 after carboxypeptidase Y digestion of stripped ghost membranes. No such decrease was observed after carboxypeptidase Y treatment of intact cells. In addition, Band 3 purified from carboxypeptidase Y-treated stripped ghost membranes had a different carboxyl-terminal sequence from intact Band 3. Cleavage of the carboxyl-terminal of Band 3 was also observed when non-stripped ghosts or inside-out vesicles were treated with carboxypeptidase Y. However, the digestion was less extensive. These results suggest that the carboxyl-terminal of Band 3 may be protected from digestion by its association with extrinsic membrane proteins. We conclude, therefore, that the carboxyl-terminal of Band 3 is located on the cytoplasmic side of the red cell membrane. Since the amino-terminal of Band 3 is also located on the cytoplasmic side of the erythrocyte membrane, the Band 3 polypeptide crosses the membrane an even number of times. A model for the folding of Band 3 in the erythrocyte membrane is presented.     

Selective association of spectrin with the cytoplasmic surface of human erythrocyte plasma membranes. Quantitative determination with purified (32P)spectrin.

A specific association between spectrin and the inner surface of the human erythrocyte membrane has been examined by measuring the binding of purified [32P]spectrin to inside out, spectrin-depleted vesicles and to right side out ghost vesicles. Spectrin was labeled by incubating erythrocytes with 32Pi, and eluted from the ghost membranes by extraction in 0.3 mM NaPO4, pH 7.6. [32P]Spectrin was separated from actin and other proteins and isolated in a nonaggregated state as a So20,w = 7 S (in 0.3 mM NaPO4) or So20,w = 8 S (in 20 mM KCl, 0.3 mM NaPO4) protein after sedimentation on linear sucrose gradients. Binding of [32P]spectrin to inverted vesicles devoid of spectrin and actin was at least 10-fold greater than to right side out membranes, and exhibited different properties. Association with inside out vesicles was slow, was decreased to the value for right side out vesicles at high pH, or after heating spectrin above 50 degrees prior to assay, and was saturable with increasing levels of spectrin. Binding to everted vesicles was rapid, unaffected by pH or by heating spectrin, and rose linearly with the concentration of spectrin. Scatchard plots of binding to inverted vesicles were linear at pH 7.6, with a KD of 45 microng/ml, while at pH 6.6, plots were curvilinear and consistent with two types of interactions with a KD of 4 and 19 microng/ml, respectively. The maximal binding capacity at both pH values was about 200 microng of spectrin/mg of membrane protein. Unlabeled spectrin competed for binding with 50% displacement at 27 microng/ml. [32P]Spectrin dissociated and associated with inverted vesicles with an identical dependence on ionic strength as observed for elution of native spectrin from ghosts. MgCl2, CaCl2 (1 to 4 mM) and EDTA (0.5 to 1 mM) had little effect on binding in the presence of 20 mM KCl, while at low ionic strength, MgCl2 (1 mM) increased binding and inhibited dissociation to the same extent as 10 to 20 mM KCl. Binding was abolished by pretreatment of vesicles with 0.1 M acetic acid, or with 0.1 microng/ml of trypsin. The periodic acid-Schiff-staining bands were unaffected by trypsin digestion which destroyed binding; mild digestion, which decreased binding only 50%, converted Band 3 almost completely to a membrane-bound 50,000-dalton fragment resistant to further proteolysis. These experiments suggest that attachment of spectrin to the cytoplasmic surface of the membrane results from a selective protein-protein interaction which is independent of erythrocyte actin. A direct role of the major sialoglycoprotein or Band 3 as a membrane binding site appears unlikely.     

Protein kinases of rabbit and human erythrocyte membranes. Solubilization and characterization.

Two protein kinases (EC 2.7.1.37) from rabbit and one from human erythrocyte membranes have been solubilized with 0.5 M NaCl. These enzymes have been partially purified by (NH4)2SO4 fractionation and gel filtration. The rabbit membrane enzymes have apparent Mr values of 100 000 and 30 000, as determined in the presence of 0.4 M NaCl. In the absence of salt, these enzymes aggregate into high molecular weight species. The kinase from human erythrocyte membranes has an apparent Mr of 30 000 and appears to have properties similar to those of the 30 000-dalton rabbit kinase. All three enzymes catalyze the phosphorylation of casein and phosvitin in salt-stimulated reactions. None of these enzymes appears to be related to cyclic AMP-dependent protein kinases.     

Specific fragmentation of human erythrocyte spectrin by chemical cleavage at cysteine residues.

Spectrin, isolated from human erythrocyte membrane, was specifically cleaved at the amino side of its cysteine residues by reacting it with 2-nitro-5-thiocyanobenzoic acid at pH 8.0 and incubating the product at pH 9.0. Conditions were developed to obtain quantitative cleavage, with virtually no side reactions due to exposure to the alkaline pH. The solubility and aggregation state of the spectrin fragments in 0.2 M sodium chloride, in 7 M guanidine hydrochloride or in 10 M urea, at pH 8.0, allow separation and partial purification of the fragments by gel filtration or by ion-exchange chromatography. Our results strongly suggest that various parts of the spectrin molecules have similar amino acid compositions. Due to the relatively limited number of fragments, this cleavage method is a promising tool for further elucidation of the structure of spectrin and for understanding its role in the erythrocyte membrane.     

Guanosine triphosphatase activity in human erythrocyte membranes

Human red cell membranes have the capacity to hydrolyze enzymatically GTD to GDP. The reaction requires magnesium, is not appreciably affected by sodium, potassium or calcium, and is not inhibited by ouabain. Kinetic analysis suggests that there are two separate enzymes in membranes which cleave GTP, a 'high Km' GTPase and a 'low Km' GTPase. Both enzymes are also ATPases, with an approximately equal affinity for GTP and ATP. GTPase activity did not extract from the membrane with spectrin and was not inactivated by antispectrin antibody. Activity was partially destroyed by 0.5% Triton X-100. It seems probable that the low Km GTPase is the sodium- and potassium-independent ATPase of red cell membranes. The identity of the high Km enzyme is not clear.     

Interactions of glycolytic enzymes with erythrocyte membranes

Partition equilibrium experiments have been used to characterize the interactions of erythrocyte ghosts with four glycolytic enzymes, namely aldolase, glyceraldehyde-3-phosphate dehydrogenase, phosphofructokinase and lactate dehydrogenase, in 5 mM sodium phosphate buffer (pH 7.4). For each of these tetrameric enzymes a single intrinsic association constant sufficed to describe its interaction with erythrocyte matrix sites, the membrane capacity for the first three enzymes coinciding with the band 3 protein content. For lactate dehydrogenase the erythrocyte membrane capacity was twice as great. The membrane interactions of aldolase and glyceraldehyde-3-phosphate dehydrogenase were mutually inhibitory, as were those involving either of these enzymes and lactate dehydrogenase. Although the binding of phosphofructokinase to erythrocyte membranes was inhibited by aldolase, there was a transient concentration range of aldolase for which its interaction with matrix sites was enhanced by the presence of phosphofructokinase. In the presence of a moderate concentration of bovine serum albumin (15 mg/ml) the binding of aldolase to erythrocyte ghosts was enhanced in accordance with the prediction of thermodynamic nonideality based on excluded volume. At higher concentrations of albumin, however, the measured association constant decreased due to very weak binding of the space-filling protein to either the enzyme or the erythrocyte membrane. The implications of these findings are discussed in relation to the likely subcellular distribution of glycolytic enzymes in the red blood cell.     

Identification of a kallikrein-like latent serine protease in human erythrocyte membranes

We have discovered and characterized a kallikrein-like latent serine protease in intact human erythrocytes and ghosts. The enzyme is activatable by trypsin. The solubilized enzyme has esterolytic activity with a pH optimum of 9; but the membrane-associated activity increases almost linearly up to pH 10. The activated enzyme releases kinin from bovine low molecular weight kininogen. Enzyme activity is inhibited by TosLysCH2Cl , phenylmethylsulfonyl fluoride, aprotinin and amiloride, and weakly by soybean or lima bean trypsin inhibitor. It is inhibited by Co2+, Zn2+ and Mn2+ but is stimulated by Fe2+, deoxycholate and phospholipase A2. An erythrocyte membrane protein (Mr = 88,000) with an active site serine residue was identified with [14C]-diisopropylphosphorofluoridate labeling. Consistent with the finding of tryptic activation of the latent erythrocyte serine protease, trypsin treatment reduced the density of labeling of this protein and revealed a lower molecular weight form (Mr = 64,000). Possible relationships between the activity of this newly identified serine protease and events such as erythrocyte membrane ion fluxes might be of interest.     

Association between human erythrocyte calmodulin and the cytoplasmic surface of human erythrocyte membranes

This report describes Ca2+-dependent binding of 125I-labeled calmodulin (125I-CaM) to erythrocyte membranes and identification of two new CaM-binding proteins. Erythrocyte CaM labeled with 125I-Bolton Hunter reagent fully activated erythrocyte (Ca2+ + Mg2+)-ATPase. 125I-CaM bound to CaM depleted membranes in a Ca2+-dependent manner with a Ka of 6 x 10(-8) M Ca2+ and maximum binding at 4 x 10(-7) M Ca2+. Only the cytoplasmic surface of the membrane bound 125I-CaM. Binding was inhibited by unlabeled CaM and by trifluoperazine. Reduction of the free Ca2+ concentration or addition of trifluoperazine caused a slow reversal of binding. Nanomolar 125I-CaM required several hours to reach binding equilibrium, but the rate was much faster at higher concentrations. Scatchard plots of binding were curvilinear, and a class of high affinity sites was identified with a KD of 0.5 nM and estimated capacity of 400 sites per cell equivalent for inside-out vesicles (IOVs). The high affinity sites of IOVs most likely correspond to Ca2+ transporter since: (a) Ka of activation of (Ca2+ + Mg2+)-ATPase and KD for binding were nearly identical, and (b) partial digestion of IOVs with alpha-chymotrypsin produced activation of the (Ca2+ + Mg2+)-ATPase with loss of the high affinity sites. 125I-CaM bound in solution to a class of binding proteins (KD approximately 55 nM, 7.3 pmol per mg of ghost protein) which were extracted from ghosts by low ionic strength incubation. Soluble binding proteins were covalently cross-linked to 125I-CaM with Lomant's reagent, and 2 bands of 8,000 and 40,000 Mr (Mr of CaM subtracted) and spectrin dimer were observed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis autoradiography. The 8,000 and 40,000 Mr proteins represent a previously unrecognized class of CaM-binding sites which may mediate unexplained Ca2+-induced effects in the erythrocyte.     

Phosphorylation of rabbit and human erythrocyte membranes by soluble adenosine 3':5'-monophosphate-dependent and -independent protein kinases.

Previous reports from this laboratory and others have established that both the rabbit and human erythrocyte membranes contain multiple protein kinase and phosphate acceptor activities. We now report that these membranes also contain phosphoryl acceptor sites for the soluble cyclic AMP-dependent and -independent protein kinases from rabbit erythrocytes. The rabbit erythrocyte membrane, which does not contain a cyclic AMP-dependent protein kinase, has at least four polypeptides (Bands 2.1, 2.3, 4.5, and 4.8) which are phosphorylated in the presence of the soluble cyclic AMP-dependent protein kinases I, IIa, and IIb isolated from rabbit erythrocyte lysates. The resulting phosphoprotein profile is very similar to that obtained for the cyclic AMP-mediated autophosphorylation of human erythrocyte membranes. The activities of the soluble cyclic AMP-dependent protein kinases toward the membranes have been studied at several pH values. Although the substrate specificity of the three kinases is similar, polypeptide 2.3 appears to be phosphorylated to a greater extent by kinase IIa than by I or IIb. This occurs at all pH values studied. Also apparent is that the pH profile for membrane phosphorylation is different from that of histone phosphorylation. The phosphorylation of membrane proteins can also be catalyzed by the soluble erythrocyte casein kinases. These enzymes are not regulated by cyclic nucleotides and can use either ATP or GTP as their phosphoryl donor. Polypeptides 2.1, 2.9, 4.1, 4.5, 4.8, and 5 of both human and rabbit erythrocyte membranes are phosphorylated in the presence of GTP and the casein kinases. This reaction is optimal at pH 7.5. Experiments were performed to determine whether the phosphorylation of the membranes by the soluble and membrane-bound kinases is additive or exclusive. Our results indicate that after maximal autophosphorylation of the erythrocyte membranes, phosphoryl acceptor sites are available to the soluble cyclic AMP-dependent and -independent protein kinases. Furthermore, after maximal phosphorylation of the membranes with one type of soluble kinase, further 32P incorporation can occur as a result of exposure to the other type of soluble kinase.     

A small hydrophobic domain that localizes human erythrocyte acetylcholinesterase in liposomal membranes is cleaved by papain digestion

A small hydrophobic domain in isolated human erythrocyte acetylcholinesterase is responsible for the interaction of this enzyme with detergent micelles and the aggregation of the enzyme on removal of detergent. Papain has been shown to cleave this hydrophobic domain and to generate a fully active hydrophilic enzyme that shows no tendency to interact with detergents or to aggregate [Dutta-Choudhury, T.A., & Rosenberry, T.L. (1984) J. Biol. Chem. 259, 5653-5660]. We report here that the intact enzyme could be reconstituted into phospholipid liposomes while the papain-disaggregated enzyme showed no capacity for reconstitution. More than 80% of the enzyme reconstituted into small liposomes could be released by papain digestion as the hydrophilic form. Papain was less effective in releasing the enzyme from large liposomes that were probably multilamellar. In a novel application of affinity chromatography on acridinium resin, enzyme reconstituted into small liposomes in the presence of excess phospholipid was purified to a level of 1 enzyme molecule per 4000 phospholipid molecules, a ratio expected if each enzyme molecule was associated with a small, unilamellar liposome. Subunits in the hydrophilic enzyme form released from reconstituted liposomes by papain digestion showed a mass decrease of about 2 kilodaltons relative to the intact subunits according to acrylamide gel electrophoresis in sodium dodecyl sulfate, a difference similar to that observed previously following papain digestion of the soluble enzyme aggregates. The data were consistent with the hypothesis that the same hydrophobic domain in the enzyme is responsible for the interaction of the enzyme with detergent micelles, the aggregation of the enzyme in the absence of detergent, and the incorporation of the enzyme into reconstituted phospholipid membranes.     

Ankyrin-independent membrane protein-binding sites for brain and erythrocyte spectrin

Brain spectrin reassociates in in vitro binding assays with protein(s) in highly extracted brain membranes quantitatively depleted of ankyrin and spectrin. These newly described membrane sites for spectrin are biologically significant and involve a protein since (a) binding occurs optimally at physiological pH (6.7-6.9) and salt concentrations (50 mM), (b) binding is abolished by digestion of membranes with alpha-chymotrypsin, (c) Scatchard analysis is consistent with a binding capacity of at least 50 pmol/mg total membrane protein, and highest affinity of 3 nM. The major ankyrin-independent binding activity of brain spectrin is localized to the beta subunit of spectrin. Brain membranes also contain high affinity binding sites for erythrocyte spectrin, but a 3-4 fold lower capacity than for brain spectrin. Some spectrin-binding sites associate preferentially with brain spectrin, some with erythrocyte spectrin, and some associate with both types of spectrin. Erythrocyte spectrin contains distinct binding domains for ankyrin and brain membrane protein sites, since the Mr = 72,000 spectrin-binding fragment of ankyrin does not compete for binding of spectrin to brain membranes. Spectrin binds to a small number of ankyrin-independent sites in erythrocyte membranes present in about 10,000-15,000 copies/cell or 10% of the number of sites for ankyrin. Brain spectrin binds to these sites better than erythrocyte spectrin suggesting that erythrocytes have residual binding sites for nonerythroid spectrin. Ankyrin-independent-binding proteins that selectively bind to certain isoforms of spectrin provide a potentially important flexibility in cellular localization and time of synthesis of proteins involved in spectrin-membrane interactions. This flexibility has implications for assembly of the membrane skeleton and targeting of spectrin isoforms to specialized regions of cells.     

A transmembranous NADH-dehydrogenase in human erythrocyte membranes

Evidence is presented for a transmembranous NADH-dehydrogenase in human erythrocyte plasma membrane. We suggest that this enzyme is responsible for the ferricyanide reduction by intact cells. This NADH-dehydrogenase is distinctly different from the NADH-cytochromeb ₅ reductase on the cytoplasmic side of the membrane. Pretreatment of erythrocytes with the nonpenetrating inhibitor diazobenzene sulfonate (DABS) results in a 35% loss of NADH-ferricyanide reductase activity in the isolated plasma membrane. Since NADH and ferricyanide are both impermeable, the transmembrane enzyme can only be assayed in open membrane sheets with both surfaces exposed, and not in closed vesicles. The transmembrane dehydrogenase has affinity constants of 90 µM for NADH and 125 µM for ferricyanide. It is inhibited byp-chloromercuribenzoate, bathophenanthroline sulfonate, and chlorpromazine.     

Mapping of glycolytic enzyme-binding sites on human erythrocyte band 3

Previous work has shown that GAPDH (glyceraldehyde-3-phosphate dehydrogenase), aldolase, PFK (phosphofructokinase), PK (pyruvate kinase) and LDH (lactate dehydrogenase) assemble into a GE (glycolytic enzyme) complex on the inner surface of the human erythrocyte membrane. In an effort to define the molecular architecture of this complex, we have undertaken to localize the binding sites of these enzymes more accurately. We report that: (i) a major aldolase-binding site on the erythrocyte membrane is located within N-terminal residues 1-23 of band 3 and that both consensus sequences D6DYED10 and E19EYED23 are necessary to form a single enzyme-binding site; (ii) GAPDH has two tandem binding sites on band 3, located in residues 1-11 and residues 12-23 respectively; (iii) a PFK-binding site resides between residues 12 and 23 of band 3; (iv) no GEs bind to the third consensus sequence (residues D902EYDE906) at the C-terminus of band 3; and (v) the LDH- and PK-binding sites on the erythrocyte membrane do not reside on band 3. Taken together, these results argue that band 3 provides a nucleation site for the GE complex on the human erythrocyte membrane and that other components near band 3 must also participate in organizing the enzyme complex.     

Isolation of human platelet plasma membranes with polylysine beads

Human platelet plasma membranes were isolated with polylysine beads according to the technique developed by Jacobson and Branton (1977, Science [Wash. D. C.] 195:302--304). Lactoperoxidase-catalyzed surface iodination revealed that ninefold greater 125I specific activity was associated with the membranes isolated on beads than with whole platelets. Enrichment in the bead membrane preparation of the activities of membrane marker enzymes, bis(p-nitrophenyl)phosphate phosphodiesterase and Na,K-ATPase, was 8.0 and 4.4, respectively. Contamination with enzymes of other organelles, cytochrome oxidase and beta-glucuronidase, was relatively low as compared with membranes isolated by sucrose gradient centrifugation. Analysis by SDS polyacrylamide gel electrophoresis showed that a full complement of surface glycoproteins was present on the membranes isolated with polylysine beads. The polylysine bead technique is a rapid, reproducible and efficient method for the preparation of relatively pure platelet plasma membranes.     

Proteins of the human erythrocyte membrane as modified by pronase

Pronase degrades proteins on the outer surface of the human erythrocyte membrane which run in polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulfate at a molecular weight of approximately 125,000. Carbohydrate and sialic acid are removed, but fragments of molecular weight 50,000 to 100,000 remain attached to the membrane. The most prominent fragment, one of molecular weight about 73,000, can be labeled with a membrane-impermeable reagent (sulfanilic acid diazonium salt), so it is still accessible from the outside of the cell. Pronase rapidly inactivates membrane-bound acetylcholinesterase, but it has relatively little effect on the facilitated diffusion of glucose; both are inhibited by the diazonium salt. Extensive digestion leads to potassium loss and osmotic lysis. Ghosts prepared in 15 mosm-Tris (pH 7.6) are extensively degraded by pronase: essentially all the protein shifts to low molecular weight. Pronase is even more potent in 3% sodium dodecyl sulfate. Ghosts prepared from intact cells which have been treated with the enzyme hydrolyze when dissolved in the detergent unless steps are taken to inhibit proteolysis.     

Characteristics of a solubilized thyrotropin receptor from bovine thyroid plasma membranes.

The thyrotropin receptor from bovine thyroid plasma membranes has been solubilized using lithium diiodosalicylate, and an assay to measure thyrotropin binding to the solubilized receptor has been developed. Both the solubilized thyrotropin receptor and the thyrotropin receptor on thyroid plasma membranes have effectively identical nonlinear Scatchard plots and negatively sloped Hill plots, i.e. both preparations have receptors which appear to exhibit a similar negatively cooperative relationship. Although the pH optimum of thyrotropin binding to the solubilized receptor is the same as that of the thyroid plasma membrane receptor, pH 6.0, the pH dependency curve of the solubilized receptor is slightly different in its outline. Thyrotropin binding to the solubilized receptor is less sensitive to salt inhibition than is binding to the thyroid plasma membrane receptor; however, optimal binding remains at 0 degrees. The relative affinities of thyrotropin and two glycoprotein hormones which can be considered structural analogs, luteinizing hormone and human chorionic gonadotropin, are 100:10:5, respectively, toward plasma membrane receptors, but 100:25:40 toward the solubilized receptors. The solubilized receptor preparation is heterogeneous in size in that it has binding components with molecular weights of 286,000, 160,000, 75,000, and 15,000 to 30,000. Tryptic digestion converts all three higher molecular weight components to the 15,000 to 30,000 molecular weight species, and the 15,000 to 30,000 molecular weight receptor component has all of the binding properties of the solubilized receptor preparation before tryptic digestion including an identical nonlinear Scatchard plot. It has the same size as and coelutes from Sephadex G-100 with a 15,000 to 30,000 molecular weight receptor released by tryptic digestion of bovine thyroid plasma membranes or tryptic digestion of bovine or dog thyroid cells in culture. The tryptic fragment of the solubilized receptor or preparations has been purified almost 250-fold by affinity chromatography on thyrotropin-Sepharose columns. The binding activity is lost when the solubilized thyrotropin receptor preparation is exposed to beads of neuraminidase-Sepharose or conconavalin A-Sepharose.     

Purification and characterization of a catalytic subunit of an adenosine 3':5'-monophosphate-dependent protein kinase from human erythrocyte membranes

Protein kinase [EC 2.7.1.37] of human erythrocyte membranes was solubilized with 0.5 M NaCl in 5 mM phosphate buffer, pH 6.7 at 4 degrees C and purified on a CM-Sephadex C-50 column, followed by affinity chromatography on a histone-Sepharose 4B column. The purified protein kinase gave a single band (molecular weight; 41,000) on examination by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The optimum pH of the enzyme was 8.0 and a millimolar range of concentration of Mg2+ was required for its maximum activity. Histone and protamine were well phosphorylated by the protein kinase but casein and phosvitin were poor phosphate acceptors for the enzyme. The enzymic activity was not stimulated by cyclic AMP (cAMP). A cAMP-finding protein from human erythrocyte membranes inhibited the activity of the protein kinase, but the activity was restored with cAMP. A heat stable protein inhibitor from rabbit skeletal muscle also inhibited this enzyme. From these observations, this protein kinase seemed to be a catalytic subunit of the membrane bound cAMP-dependent protein kinase. This enzyme was strongly inhibited with Ca2+ in the presence of 1 mM MgCl2. Various sulfhydryl reagents and polyamines also had inhibitory activity on the protein kinase. Natural substrates of the enzyme were investigated using heat treated membranes and 0.5 M NaCl extracted membrane residues. Band 4.1, 4.2, and 4.5 proteins were phosphorylated but band 2 (spectrin) and band 3 proteins were poor substrates for this protein kinase.     

Identification of elastases associated with purified plasma membranes isolated from human monocytes and lymphocytes

Studies were carried out to understand the pathogenesis of amyloid formation and to localize the elastase-like enzymes postulated to be associated with the surface of human peripheral blood monocytes and lymphocytes. These enzymes are known to degrade serum amyloid A and amyloid A proteins. Pure plasma membrane preparations were obtained by allowing cells to attach to polyacrylamide beads, followed by their disruption. The purity of the membranes was monitored by electron microscopy and enzyme determinations. The extracted membrane enzymes which have molecular weights of 56000 and 30000, respectively, were inhibited by DFP, MeO-Suc-Ala-Ala-Pro-Val-CH2Cl, Ac-Pro-Phe-Arg-CH2Cl . HCl, and elastinal but were not inhibited by EDTA or epsilon-amino caproic acid, thus exhibiting the properties of elastases. These enzymes cleave serum amyloid A to amyloid protein A. In some individuals, cleavage stops at this point, while in others a second step occurs, resulting in complete protein degradation. This activity was comparable whether monocyte or lymphocyte plasma membranes were employed. Since lymphocyte dependent cytotoxicity has also been attributed to surface proteases, it is likely that a spectrum of membrane associated enzymes mediate important physiologic function of these mononuclear leukocytes.     

Characteristics of endogenous proteolysis in preparations of human erythrocyte membranes

Endoproteolytic activity in human erythrocyte membrane preparations has been examined at 37 degrees C by one- and two-dimensional electrophoresis. Two-dimensional mapping has shown that the presence of leukocyte enzymes in erythrocytes prepared in a regular manner (centrifugation) cannot be excluded. Sedimentation in the 1.5% dextran 500,000 with the following erythrocyte purification on HBS-cellulose has made it possible to prepare erythrocyte membranes characterized by low level endoproteolytic activity without leukocyte enzymes. The marker peptide has been found. It is likely to be a specific product of the enzyme activity of membrane localization.