Structure of the anion-transport protein of the human erythrocyte membrane. Further studies on the fragments produced by proteolytic digestion.

The topology of the human erythrocyte membrane anion-transport protein (band 3) has been investigated by isolation and peptide 'mapping' of the major and minor fragments derived from proteolytic cleavage of the lactoperoxidase 125I-labelled protein in erythrocytes and erythrocyte membranes. The content, in each fragment, of lactoperoxidase 125I-labelled sites (which have a known location in the extracellular or cytoplasmic domain of the protein), together with the location of the sites of proteolytic cleavage yielding the fragments, has allowed us to determine the alignment of the fragments on the linear amino acid sequence and to infer the topology of the polypeptide in the membrane. The results suggest that a region in the C-terminal portion of the polypeptide forms part of the cytoplasmic domain of the protein in addition to a large N-terminal segment. The membrane-bound regions of the protein are located in the C-terminal two-thirds of the molecule. In this region the polypeptide chain traverses the membrane at least four times and an additional loop of polypeptide is either embedded in the membrane or also penetrates through it to the other surface. The location of the lectin receptors on the protein and the site of binding of an anion-transport inhibitor have also been studied.     

Cleavage site specificity of cathepsin K toward cartilage proteoglycans and protease complex formation

Cathepsin K is a potent extracellular matrix-degrading protease that requires interactions with soluble glycosaminolycans for its collagenolytic activity in bone and cartilage. The major sources of glycosaminoglycans in cartilage are aggrecan aggregates. Therefore, we investigated whether cathepsin K activity is capable to hydrolyze aggrecan into fragments allowing the formation of glycosaminoglycan-cathepsin K complexes and determined the cleavage site specificity of cathepsin K toward the cartilage-resident link protein and aggrecan. The cleavage site specificity was compared with those of cathepsins S and L. All three cathepsins released glycosaminoglycans from native bovine cartilage at lysosomal pH and to a lesser degree at neutral extracellular pH. Cathepsin-predigested aggrecan complexes and cartilage provided suitable glycosaminoglycan fragments that allowed the formation of collagenolytically active cathepsin K complexes. A detailed analysis of the degradation of aggrecan aggregates revealed two cathepsin K cleavage sites in the link protein and several sites in aggrecan, including one site within the interglobular domain E1. In summary, these results demonstrate that cathepsin K is capable to degrade aggrecan complexes at specific cleavage sites and that cathepsin K activity alone is sufficient to self-provide the glycosaminoglycan fragments required for the formation of its collagenolytically active complex.     

Cleavage specificities of aspartic proteinases toward oxidized insulin B chain at different pH values

The cleavage specificities of typical aspartic proteinases: pepsin A, gastricsin, cathepsin D and rhizopuspepsin, were examined at different pH values with oxidized insulin B chain as a substrate with special attention to the specificities near neutral pH. Significant differences in relative specificity for scissile bonds were observed between pH 2.0 and 5.5-6.5, which may be partly related with the changes in dissociation states of the His and Glu residues in the substrate and the ionizable residues in the active site of each enzyme.     

Human renin inhibition by a diazoacyl reagent: Relationship of the enzyme to other proteinases

Human renin is inactivated by a diazoacyl compound (diazoacetylglycine ethyl ester; N₂CHCO-Gly-OEt) in the presence of Cu(II). The mechanism of the inactivation is presumably identical to that which has been determined for pepsin and several other proteinases: esterification of the β-carboxyl of an aspartic acid residue at the active site of the enzyme. Renin's inhibition by the diazoacyl reagent, its specificity toward a hydrophobic sequence, and its inhibition by pepstatin, all suggest a close relationship to the acid proteinases, especially pepsin and cathepsin D. However, renin, a neutral proteinase, would be better classified together with other diazoacyl-inhibited enzymes by active site rather than pH optimum. The term “aspartic proteinase” is suggested for this group of enzymes.     

Synthesis of the erythrocyte anion-transport protein. Immunochemical study of its incorporation into the plasma membrane of erythroid cells.

We studied the surfaces of maturing rabbit bone-marrow erythroid cells for the presence of the erythrocyte anion-transport protein by using an immunochemical method. An antibody was raised against the purified anion-transport protein. The antibody was shown to react specifically with the anion-transport protein and it recognized determinants in the extracellular as well as the cytoplasmic or intramembranous domains of the protein. The binding of the antibody to the surface of intact rabbit bone-marrow erythroid cells was studied by using the Staphylococcus aureus 'rosette' technique described by Gahmberg, Jokinen & Andersson [(1978) Blood 52, 379-386]. Although pronormoblasts had little of the protein, there was a progressive increase in the amount of the protein at the surface of cells of increasing maturity up to the reticulocyte stage. Most of the protein is inserted into the plasma membrane between the polychromatic-normoblast and reticulocyte stage of the cell.     

Enzymatic cleavage of Clostridium pasteurianum apoferredoxin and reconstitution of the cleaved products

Native ferredoxin from Clostridium pasteurianum proved to be resistant to proteolytic cleavage under anaerobic conditions, but was digested in the presence of air. Apoferredoxin was hydrolyzed by the proteinases used, while cobalt-substituted ferredoxin was resistant both under anaerobic and aerobic conditions. These studies indicate that metal binding of the protein stabilizes the folded state, which is extremely resistant to proteolytic attack. Sulfitolyzed apoferredoxin was subjected to specific cleavage by pepsin at pH 3.2, yielding two fragments. The fragments could be reconstituted to an unstable holoprotein with UV-visible absorption features like that of the native form.     

Characterization of fragments of human albumin purified by Cibacron blue F3GA affinity chromatography.

Controlled limited proteolysis of human plasma albumin (0.3 mM; 37 degrees C; 15 min; pH 3.7) with pepsin [pepsin/albumin, 1:1000 (w/w)] in the presence of octanoic acid (4.2 mM) yields at least 14 fragments in the range of 5000--56000 Da. By utilizing a combination of conventional and affinity-chromatographic procedures, two fragments with mol. wts. 25000 and 27000 were purified to more than 99% homogeneity. The larger fragment consists of a continuous polypeptide chain and has been shown to contain the primary bilirubin-binding site. The small fragment contains an internal cleavage site. On the basis of amino acid compositions, N-terminal sequences, C-terminal sequences, molecular weights and other internal markers the locations of these fragments within the known sequence of human albumin were determined to be residues 49--308 for the 27000 Da peptide and 309--585 for the 25000 Da peptide. Peptide 309--585 contains an internal cleavage site and appears to be missing residues 408--423. These non-overlapping fragments should be useful for investigations of individual ligand-binding sites and for the determination of antigenic sites.     

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.     

The human erythrocyte anion-transport protein. Further amino acid sequence from the integral membrane domain homologous with the murine protein.

Sequences from the human erythrocyte anion-transport protein homologous with residues 417-449 and 794-813 of the murine erythrocyte anion-transport protein have been determined. The former sequence includes the putative transmembrane helix closest to the N-terminus of the protein. The latter sequence traverses almost all of the lipid bilayer and is located towards the C-terminus of the protein. Sites have been identified by alignment with the murine sequence in the integral membrane domain that are accessible to proteolytic enzymes. Sequences from the integral membrane domain of the erythrocyte anion-transport protein are highly conserved.     

Proteolysis of human reticulocyte membrane proteins: Evidence for a physiological role of the acid endopeptidases

Endogenous membrane proteins, labeled by incubating human reticulocytes with l-[¹⁴C]leucine, are degraded at pH 7.3 by membrane-bound acid proteinases. Solubilized membrane proteins are also degraded at neutral pH by the purified membrane acid proteinases. Exogenous proteins are not degraded by intact membranes and therefore association with the membrane seems to be an essential requirement for protein degradation in the physiological pH range. These findings provide evidence for a physiological function of the enzymes previously characterized as acid proteinases.     

Proteolysis of isolated mitochondria by myocardial lysosomal enzymes.

1. Solubilized mitochondria and lysosomal fractions were obtained from guinea-pig heart by differential centrifugation and selective membrane disruption. 2. Mitochondria incubated at 37 degrees C in the presence of lysosomal enzymes underwent proteolysis. The rate of protein degradation was inversely dependent on pH. 3. The use of proteinase inhibitors showed that at low pH the major enzyme involved in mitochondrial digestion was cathepsin D. 4. At neutral pH carboxyl proteinases were still active, but thiol proteinases accounted for most of the protein breakdown. 5. The role of lysosomal enzymes as mediators of mitochondrial damage in ischaemic myocardium is discussed.     

Cooperation between soluble and membrane-bound proteinases in the degradation of β-hemoglobin chains in intact human erythrocytes

Human erythrocytes are shown to contain soluble proteinase(s) that convert excess β-hemoglobin introduced by in vitro entrapment to modified forms that are bound to the erythrocyte membrane. The bound modified hemoglobin chains are degraded in the membrane to yield acid soluble products. Native hemoglobin chains are not bound to the membrane and are not degraded. The cooperative degradation of excess β-hemoglobin chains by soluble and membrane-bound enzymes occurs at neutral pH and does not require energy. The results provide a role for the membrane-bound acid proteinases.     

Characterization and partial sequence of di-iodosulphophenyl isothiocyanate-binding peptide from human erythrocyte anion-transport protein.

We investigated the presumed anion-binding domain of the anion-transport protein from human erythrocyte membranes, using 2,6-di-iodo-4-sulphophenyl isothiocyanate, an inhibitor of anion transport. The 125I-labelled reagent binds covalently to the protein with a half-maximal inhibitory concentration of 86 microM. Treatment of unsealed erythrocyte 'ghosts' with chymotrypsin yielded a membrane-bound fragment (mol.wt. 14 500 +/- 1000) that contained all the protein-bound radioactivity. The binding of the inhibitor to this peptide gave a pattern very similar to that obtained for the effect of the compound on phosphate transport into erythrocytes. The peptide is therefore presumed to be intimately involved in the mediation of anion exchange. Cleavage of the 14 500-mol.wt. transmembrane fragment with CNBr resulted in the production of two peptides with apparent molecular weights of 8800 and 4700. The 4700-mol.wt. peptide is the N-terminal portion of the 14 500-mol.wt. peptide. The attachment site for 2,6-di-iodo-4-sulphophenyl isothiocyanate is situated near the C-terminal of the 8800-mol.wt. peptide. This locates the inhibitor-binding site near the chymotrypsin cleavage point at the extracellular surface of the membrane. A partial sequence (residues 1--38) of the 8800-mol.wt. peptide was obtained.     

Reactive sulfhydryl groups of the band 3 polypeptide from human erythroycte membranes. Location in the primary structure.

Human erythrocyte membranes contain a major transmembrane protein, known as Band 3, that is involved in anion transport. This protein contains a total of five reactive sulfhydryl groups, which can be assigned to either of two classes on the basis of their susceptibility to release from the membrane by trypsin. Two of the groups are located in the region COOH-terminal to the extracellular chymotrypsin-sensitive site of the protein and remain with a membrane-bound 55,000-dalton fragment generated by trypsin treatment. The three sulfhydryl groups NH2-terminal to the extracellular chymotrypsin site are released from the cytoplasmic surface of the membrane by trypsin. All three groups are present in a 20,000-dalton tryptic fragment of Band 3. Two of these groups are located very close to the sites of trypsin cleavage that generate the 20,000-dalton fragment. The third reactve group is probably located about 15,000-daltons from the most NH2-terminal sulfhydryl group. Two other well defined fragments of the protein do not contain reactive sulfhydryl groups. They are a 23,000-dalton fragment derived from the NH2-terminal end that is also released by trypsin from the cytoplasmic surface of the membrane and a 19,000-dalton membrane-bound region of the protein that is produced by treatment with chymotrypsin in ghosts. The 20,000-dalton tryptic fragment may, therefore, constitute a sulfhydryl-containing domain of the Band 3 protein.     

Proteases in malaria-infected red blood cells

The discrimination between erythrocyte and Plasmodium proteases is now made easier by using synthetic fluorogenic substrates, high-pressure liquid chromatography, reliable methods of cell preparation, as well as radiolabeled extracts from in vitro cultures of P. falciparum. The reinvasion process of an erythrocyte by a merozoite involves specific proteinases, which were recently identified using fluorogenic peptidyl-AEC substrates and by analysis of schizont and merozoite extracts with the gelatin-SDS-PAGE method. The biological targets of both host and parasite proteinases are not yet well characterized because Plasmodium-infected red blood cells contain at least four compartments with different pH values, which could modulate the proteinase activities according to their pH range activity. The processing of the precursor for the major merozoite surface antigens involves cleavage of very specific peptidic bonds by, so far unknown, proteinases. The depletion of the erythrocyte cytoskeleton could depend on a 37 kD proteinase, which cleaves spectrin and the 4.1 component, as shown in P. berghei and P. falciparum species. In contrast to leupeptin, which inhibits the merozoite release from schizont-infected erythrocytes, the structural inhibitor analogous to the Val-Leu-Gly-Lys (or Arg) P. falciparum neutral proteinase substrates appears to block the invasion step of erythrocytes by merozoites and may open new trends in chemotherapeutical strategies.     

The structure of the major protein of the human erythrocyte membrane. Characterization of the intact protein and major fragments.

Polypeptide 3, the major membrane-penetrating protein of the human erythrocyte membrane, was characterized, together with two major fragments derived by specific proteolysis of the native protein in the membrane. One fragment (fragment 3f) was obtained from thermolysin cleavage in the extracellular region of the protein, and the other (fragment T1) was derived from tryptic cleavage in the intracellular region of the protein. The results of N- and C-terminal group analysis suggest that fragment 3f contains the N-terminal region of polypeptide 3 and fragment T1 contains the C-terminal part of the molecule. The carbohydrate contents of the polypeptides suggest that carbohydrates are present in three regions of the molecule, much of this carbohydrate being present in the C-terminal part of the molecule. This region of the protein also contains the receptors for concanavalin and the lectins from Phaseolus vulgaris and Ricinis communis, and our results suggest that there is heterogeneity in the carbohydrate chains present in the C-terminal region of polypeptide 3. These data are related to the folding of polypeptide 3 in the erythrocyte membrane.     

Ionic-strength-dependent changes in the structure of the major protein of the human erythrocyte membrane.

The effect of ionic strength on the proteolysis by trypsin of the major membrane-penetrating protein (polypeptide 3) in the erythrocyte membrane was studied. Both the intracellular and extracellular regions of the protein are susceptible to trypsin proteolysis under hypo-osmotic conditions, whereas under iso-osmotic conditions the extracellular region of the protein is resistant to trypsin, and the intracellular region yields only two cleavage products with trypsin. Studies of the fragments obtained from polypeptide 3 by trypsin digestion under iso-osmotic conditions of 'ghosts' radioiodinated with lactoperoxidase confirmed our earlier conclusions that the polypeptide chain of polypeptide 3 traverses the membrane twice. Ionic-strength-dependent changes were also observed in the incorporation of iodine by lactoperoxidase into the individual extracellular tyrosine sites of the protein. These results show that polypeptide 3 undergoes ionic-strength-dependent changes in structure.     

A calmodulin and alpha-subunit binding domain in human erythrocyte spectrin

Human erythrocyte spectrin binds calmodulin weakly under native conditions. This binding is enhanced in the presence of urea. The site responsible for this enhanced binding in urea has now been shown to reside in a specific region of the spectrin beta-subunit. Cleavage of spectrin with trypsin, cyanogen bromide or 2-nitro-5-thiocyanobenzoic acid generates fragments of the molecule which retain the ability to bind calmodulin under denaturing conditions. The origin of these fragments, identified by two-dimensional peptide mapping, is the terminal region of the spectrin beta-IV domain. The smallest peptide active in calmodulin binding is a 10 000 Mr fragment generated by cyanogen bromide cleavage. Only the intact 74 000 Mr fragment generated by trypsin (the complete beta-IV domain) retains the capacity to reassociate with the isolated alpha-subunit of spectrin. The position of a putative calmodulin binding site near a site for subunit-subunit association and protein 4.1 and actin binding suggests a possible role in vivo for calmodulin regulation of the spectrin-actin membrane skeleton or for regulation of subunit-subunit associations. This beta-subunit binding site in erythrocyte spectrin is found in a region near the NH2-terminus at a position analogous to the alpha-subunit calmodulin binding site previously identified in a non-erythroid spectrin by ultrastructural studies.     

Pepsin-mediated processing of synthetic precursor-like sequence yields neurotensin-like peptide.

A 15 amino acid synthetic peptide, which spanned the dibasic cleavage site C-terminal to neurotensin (NT), in its 170-residue canine precursor, was synthesized by solid-phase methods. Using this substrate in combination with a radioimmunoassay specific for the C-terminal region of NT, a simple assay was developed to monitor protease-mediated cleavage of the Leu8-Lys9 bond in the substrate. Hog pepsin and the related enzymes, rhizopus pepsin, bovine cathepsin D, and mouse renin, were found to be effective in this assay, pepsin cleaving only this bond to liberate the NT-like sequence. The pH dependence of the reaction indicated that pepsin, cathepsin D, and renin exhibited significant activity at pH's characteristic for secretory vesicles (pH 5.5-6.5). In addition, pepsin and cathepsin D were shown to process the native precursor at pH's as high as 5.5. These results, although not proof, are consistent with the idea that endoproteases with pepsin-like specificity may be involved in the processing of the NT precursor in neural/endocrine cells.