Limited proteolysis of human erythrocyte Ca2+-ATPase in membrane-bound form. Identification of calmodulin-binding fragments

Water-soluble and membrane-bound calmodulin-binding polypeptides formed upon limited proteolysis of erythrocyte ghosts were isolated by means of affinity chromatography. Immune blotting revealed that all isolated fragments originated from Ca2+-ATPase. Among the fragments obtained those having formed an acylphosphate intermediate were identified. The N-terminal residue of purified intact Ca2+-ATPase was shown to be blocked (probably acylated).     

Limited proteolysis of streptokinase and properties of some fragments.

Limited proteolysis of streptokinase (Sk) by trypsin and thermolysin was performed under various incubation conditions and analysed by polyacrylamide gel electrophoresis. Several fragments (Sk1, Tr27, Tr17, Th26, and Th16) were isolated and characterized further. The N-terminal sequences of Tr27, Tr17, Th26, Th16 and the C-terminal sequences of Tr27 and Th26 were determined by partial sequencing. The evidence available allows the positioning of these fragments within the Sk sequence. Fragment Sk1 is obtained by carefully standardized tryptic digestion of Sk and gel chromatography under non-denaturing conditions. Sk1 is formed by a large polypeptide Ser60-Lys293 and non-covalently bonded smaller polypeptides composed of amino acids from the N-terminal region Ile1-Lys59 of Sk. Fragment Tr27 consists of the large polypeptide Ser60-Lys293 of Sk1, and can be obtained from Sk1 by removal of the smaller N-terminal polypeptides under denaturing conditions. Fragment Th26 is composed of amino acids Phe63-His291. The N-termini of fragments Tr17 and Th16 start with Glu148 and Ile151. From their electrophoretically-determined sizes it can be concluded that they most probably have the same C-terminal amino acids, Lys293 and His291, as fragments Tr27 and Th26, respectively. Secondary structure elements of similar composition were found in all the fragments studied using circular dichroism (c.d.) and infrared (i.r.) measurements. Differential scanning calorimetric (d.s.c.) measurements were performed in order to correlate the sequence regions of Sk to energetic folding units of the protein. Fragments Sk1, Tr27, Th26, Tr17, and Th16 show one melting peak in the temperature range from 42.8 to 46.1 degrees C (thermal unfolding stage). For fragment Sk1, this melting peak can be separated by deconvolution into two transitions at T1 = 46.1 degree C and T2 = 47.3 degrees C with delta H1 = 450 kJ/mol and delta H2 = 219 kJ/mol, respectively. Fragments Tr17 and Th16 show one two-state transition at T = 42.8 degrees C with delta H = 326 kJ/mol.     

Characterization of proteolytic fragments of the laminin-nidogen complex and their activity in ligand-binding assays

Some 12 new nidogen and laminin fragments were purified from elastase, thrombin and trypsin digests and characterized by their sizes (22 kDa to greater than 300 kDa), subunit patterns on electrophoresis, partial amino acid sequences, content of specific epitopes and their binding to laminin or nidogen structures in radioligand assays. This permitted the various fragments to be ordered along the dumbbell-shaped structure of nidogen and to compare them with previously described nidogen fragments arising by endogenous proteolysis. Two nidogen fragments (E-50, E-90; 50 kDa and 90 kDa) remain associated with a large laminin fragment in elastase digests of the complex and could be dissociated with 2 M guanidine.HCl. Recombination studies demonstrated Kd = 10-20 nM for this interaction. Nidogen fragments devoid of binding activity included the tryptic peptide T-40 (40 kDa) corresponding to the rod-like domain and several larger fragments extending more to the N-terminus of nidogen. An N-terminal thrombin fragment of about 50 kDa was also inactive. Together the data show a lack of laminin binding to the N-terminal globule and rod of nidogen and provide indirect evidence that this activity is located within or close to its C-terminal globular domain. Nidogen-binding structures of laminin were obtained as two large fragments (greater than 300 kDa), P1X and E1X. They correspond to the short arm structure of laminin with one (E1X) or two (P1X) arms decreased in size to the inner rod-like segment. Shortening in E1X is mainly due to the B1 chain segment including the central globular domain which was identified as a new laminin fragment E10. Binding of E1X and P1X to nidogen was comparable to that of laminin while much lower activity was found for other laminin fragments. A 10-fold lower binding potential was also observed for the laminin-nidogen complex whose structure can now be defined in more precise molecular terms.     

Characterization of human red cell Rh (rhesus-)specific polypeptides by limited proteolysis

Human red cells of various Rh phenotypes were surface-labelled with 125I and the Rh-specific labelled polypeptides were isolated by preparative SDS-PAGE. The polypeptides were subjected to limited proteolysis and the resulting fragments were analysed by SDS-PAGE and autoradiography. Chymotryptic peptide maps of proteins obtained from Rh(D)-positive and -negative types appeared completely identical, whereas tryptic peptide maps revealed a difference: a fragment of Mr 17,500 was associated with the Rh(D) antigen, and one of Mr 19,000 with the Rh(C/c,E/e) antigens. Treatment of Rh polypeptides with carboxypeptidase Y prior to tryptic digestion resulted in a shift of nearly all tryptic fragments, including a fragment of Mr 8,000, indicating that the surface label was incorporated into the C-terminal part of the molecule.     

Molecular cloning of monkey liver cytochrome P-450 cDNAs: similarity of the primary sequences to human cytochromes P-450.

Three cDNAs coding for monkey cytochrome P-450 (P450) 2C, 2E and 3A (MKmp13, MKj1 and MKnf2, respectively) were isolated from a lambda gt11 cDNA library of a liver from a 3-methylcholanthrene (3MC)-treated crab-eating monkey, using cDNA fragments for human P450 2C, 2E and 3A as respective probes. MKmp13 and MKnf2 were 1901 and 2032 bp long, containing entire coding regions for polypeptides of 490 and 503 residues, respectively. The deduced N-terminal amino acid sequences of MKmp13 and MKnf2 were identical with those of P450-MK1 and P450-MK2, which had been purified from liver microsomes of untreated and polychlorinated biphenyl (PCB)-treated crab-eating monkeys, respectively. MKj1 was 1508 bp long, encoding a polypeptide of 449 residues, which is presumed to lack N-terminal 45 residues as compared with the sequence for human P450 2E1. Northern blot analysis indicated that monkey P450 2C, 2E and 3A mRNAs were expressed constitutively in monkey livers. P450 2E and 3A mRNAs were induced by both 3MC and PCB, while P450 2C mRNA was induced only by PCB. The deduced amino acid sequences of four monkey cytochrome P-450 cDNAs, including P450 1A1 (MKah1) which we isolated previously, were more than 92% identical with those of corresponding human cytochrome P-450 cDNAs.     

Expression, purification, and crystallography of the conserved methionine-rich domain of human signal recognition particle 54 kDa protein.

Protein SRP54 is an essential component of eukaryotic signal recognition particle (SRP). The methionine-rich M-domain (SRP54M or 54M) interacts with the SRP RNA and is also involved in the binding to signal peptides of secretory proteins during their targeting to cellular membranes. To gain insight into the molecular details of SRP-mediated protein targeting, we studied the human 54M polypeptide. The recombinant human protein was expressed successfully in Escherichia coli and was purified to homogeneity. Our studies determined the sites that were susceptible to limited proteolysis, with the goal to design smaller functional mutant derivatives that lacked nonessential amino acid residues from both termini. Of the four polypeptides produced by V8 protease or chymotrypsin, 54MM-2 was the shortest (120 residues; Mr = 13,584.8), but still contained the conserved amino acids suggested to associate with the signal peptide or the SRP RNA. 54MM-2 was cloned, expressed, purified to homogeneity, and was shown to bind human SRP RNA in the presence of protein SRP19, indicating that it was functional. Highly reproducible conditions for the crystallization of 54MM-2 were established. Examination of the crystals by X-ray diffraction showed an orthorhombic unit cell of dimensions a = 29.127 A, b = 63.693 A, and c = 129.601 A, in space group P2(1)2(1)2(1), with reflections extending to at least 2.0 A.     

Evidence of Native-like Substructure(s) in Polypeptide Chains of Carbonic Anhydrase Deposited into Insoluble Aggregates During Thermal Unfolding

A non-specific protease, subtilisin, was used to probe the existence of folded structure in thermal aggregates of bovine carbonic anhydrase-II (BCA). BCA aggregates and native BCA were subjected to proteolysis and electrophoretic analyses which revealed the accumulation of polypeptide fragments of similar size, indicating survival of similar sections of folded structure burying peptide bonds away from scission in the two samples. N-terminal sequencing revealed that the termini of size-matched fragments from the two samples were either identical, or located very close to each other, and predominantly on the surface of the 3-dimensional structure of native BCA. The susceptibility to proteolysis of very nearly the same sites in the two samples suggests that native-like elements of structure survive within BCA aggregates. The finding that thermal aggregation can involve interactions among molecules retaining elements of native-like structure, suggests that complete chain unfolding may not be a necessary prerequisite for all aggregation.     

Cathepsin D processes human prolactin into multiple 16K-like N-terminal fragments: study of their antiangiogenic properties and physiological relevance

16K prolactin (PRL) is the name given to the 16-kDa N-terminal fragment obtained by proteolysis of rat PRL by tissue extracts or cell lysates, in which cathepsin D was identified as the candidate protease. Based on its antiangiogenic activity, 16K PRL is potentially a physiological inhibitor of tumor growth. Full-length human PRL (hPRL) was reported to be resistant to cathepsin D, suggesting that antiangiogenic 16K PRL may be physiologically irrelevant in humans. In this study, we show that hPRL can be cleaved by cathepsin D or mammary cell extracts under the same conditions as described earlier for rat PRL, although with lower efficiency. In contrast to the rat hormone, hPRL proteolysis generates three 16K-like fragments, which were identified by N-terminal sequencing and mass spectrometry as corresponding to amino acids 1-132 (15 kDa), 1-147 (16.5 kDa), and 1-150 (17 kDa). Biochemical and mutagenetic studies showed that the species-specific digestion pattern is due to subtle differences in primary and tertiary structures of rat and human hormones. The antiangiogenic activity of N-terminal hPRL fragments was assessed by the inhibition of growth factor-induced thymidine uptake and MAPK activation in bovine umbilical endothelial cells. Finally, an N-terminal hPRL fragment comigrating with the proteolytic 17-kDa fragment was identified in human pituitary adenomas, suggesting that the physiological relevance of antiangiogenic N-terminal hPRL fragments needs to be reevaluated in humans.     

Squid neurofilaments. Phosphorylation and Ca2+-dependent proteolysis in situ.

Three major polypeptides co-purify with neurofilaments from squid (Loligo forbesi) axoplasm: P60 (apparent Mr 60,000), P200 (apparent Mr 200,000) and Band 1 (apparent Mr 400,000). Anti-IFA, a monoclonal antibody that recognizes an epitope common to all classes of intermediate filaments, binds to P200 and P60. When axoplasm is incubated with [32P]Pi, the major phosphorylated polypeptides are P200 and Band 1. We have investigated Ca2+-dependent proteolysis of [32P]phosphorylated axoplasm in order to localize the major sites of phosphorylation and to probe the arrangement of the polypeptides in the filament. The proteinase preferentially cleaves P200 and Band 1, liberating the phosphorylated domains. Analysis of proteolysed filaments by electron microscopy and gel electrophoresis shows that most of P200 and Band 1 can be cleaved while still maintaining intact filaments. We suggest that P200 is initially cleaved within a single highly sensitive region, generating two major fragments called P100p (apparent Mr 100,000) and P110s (apparent Mr 110,000). P100p contains the Anti-IFA epitope and co-sediments with filaments, whereas P110s is highly phosphorylated and does not sediment with filaments. Band 1 is cleaved to produce a soluble high-Mr fragment that is phosphorylated and that represents a major portion of the undigested component, whereas P60 is relatively resistant to limited proteolysis. Thus proteolysis appears to define two major filament domains: a conserved core that forms the backbone of the filament, and a highly phosphorylated peripheral region that is not essential for filament integrity.     

Secretion of intact proteins and peptide fragments by lysosomal pathways of protein degradation

We report that degradation of proteins microinjected into human fibroblasts is accompanied by release into the culture medium of peptide fragments and intact proteins as well as single amino acids. For the nine proteins and polypeptides microinjected, acid-precipitable radioactivity, i.e. peptide fragments and/or intact proteins, ranged from 10 to 67% of the total released radioactivity. Peptide fragments and/or intact protein accounted for 60% of the radioactivity released into the medium by cells microinjected with ribonuclease A. Two major radiolabeled peptide fragments were found, and one was of an appropriate size to function as an antigen in antigen-presenting cells. The peptides released from microinjected ribonuclease A were derived from lysosomal pathways of proteolysis based on several lines of evidence. Previous studies have shown that microinjected ribonuclease A is degraded to single amino acids entirely within lysosomes (McElligott, M. A., Miao, P., and Dice, J. F. (1985) J. Biol. Chem. 260, 11986-11993). We show that release of free amino acids and peptide fragments and/or intact protein was equivalently stimulated by serum deprivation and equivalently inhibited by NH4Cl. We also show that lysosomal degradation of endocytosed [3H]ribonuclease A was accompanied by the release of two peptide fragments similar in size and charge to those from microinjected [3H]ribonuclease A. These findings demonstrate that degradation within lysosomes occurs in a manner that spares specific peptides; they also suggest a previously unsuspected pathway by which cells can secrete cytosol-derived polypeptides.     

Analysis of Serotonin Transporter in Human Platelets by Immunoblotting Using Site-Specific Antibodies

We have produced a panel of site-specific antibodies recognizing different regions of the human serotonin transporter (SERT). This panel included: 1) monoclonal antibodies 23C5 (mAbs 23C5) to the C-terminal region (amino acid residues 597-630); 2) polyclonal antibodies (pAbs) to the N-terminal region (amino acid residues 69-83); 3) pAbs to the region (amino acid residues 86-100) in the beginning of the first transmembrane domain (TMD). The antibodies were produced using recombinant proteins and synthetic peptides (containing certain sequences of SERT) as antigens. These antibodies were purified by affinity chromatography, conjugated to horseradish peroxidase (HRP), and used for immunoblotting analysis of SERT in extracts of human platelets. Sodium dodecyl sulfate extracts were prepared under conditions preventing non-specific proteolytic degradation of the proteins. In platelet extracts, all antibodies were able to detect the 67 kD protein, apparently corresponding to full-length SERT molecule (its theoretical mass is about 70 kD). These antibodies also detected several polypeptides of smaller size (56, 37, 35, 32, 22, and 14 kD), apparently corresponding to N-terminal, C-terminal, and non-terminal SERT fragments. Specificity of immunostaining was confirmed by preincubation of HRP-labeled anti-SERT antibodies with excess of corresponding antigen, which resulted in disappearance of protein band staining. It is suggested that SERT undergoes a programmed proteolytic cleavage (processing) resulting in formation of several SERT-derived polypeptides of smaller size. It is possible that one of the cleaved SERT species is required for serotonin transport activity. Possible sites for specific proteolysis may be located in the region near TMD1 and in the intracellular loop between TMD4 and TMD5.     

Determination of antigenic domain in GST fused major surface protein (Nc-p43) of Neospora caninum

The antigenic domain of the major surface protein (Nc-p43) of Neospora caninum was examined by polymerase chain reaction of its gene fragments and recombinant expression as GST fusion proteins. The fragments of Nc-p43 were as follow: a total open reading frame (OFR), T; OFR without signal sequence and C-terminal hydrophobic sequence, S; N-terminal 2/3 parts of S, A; C-terminal 2/3 parts, P; N-terminal 1/3 part, X; middle 1/3 part, Y; and C-terminal 1/3 part, Z, respectively. The DNA fragments were cloned into pGEX-4T vector. Recombinant plasmids transformed into Escherichia coli of BL21 pLysS (DE3) strain were induced to express GST or GST fused fragments of Nc-p43 such as 69 kDa protein for T, 66 kDa for S, 52 kDa for A, 53 kDa for P, and 40 kDa proteins for X, Y, and Z, respectively in SDS-PAGE. The Nc-p43 fragments of T, S, and P reacted with a bovine serum of neosporosis while those of A, X, Y, and Z together with GST did not in the western blot. These findings suggest that the antigenic domain of Nc-p43 of N. caninum may be localized in the C-terminal 2/3 parts. Together with A19 clone in SAG1 of Toxoplasma gondii (Nam et al., 1996), the P fragment of Nc-p43 could be used as efficient antigens to diagnose and differentiate those infections with both species.     

Impact of microencapsulated peptidase (Aspergillus oryzae) on cheddar cheese proteolysis and its biologically active peptide profile

We investigated the delivery of calcium-alginate encapsulated peptidase (Flavourzyme(?), Aspergillus oryzae) on proteolysis of Cheddar cheese. Physical and chemical characteristics such as moisture, pH and fat content were measured, and no differences were found between control and experimental cheese at day 0. SDS-PAGE analysis clearly showed that proteolysis of α and k casein was significantly accelerated after three months of maturity in the experimental cheese. A large number of low molecular weight peptides were found in the water soluble fraction of the experimental cheeses and some of these peptides were new. N-terminal amino acid sequence analysis identified these as P(1), Leu-Thu-Glu; P(3), Asp-Val-Pro-Ser-Glu) and relatively abundant stable peptides P(2), P(4), Arg-Pro-Lys-His-Pro-Ile; P(5), Arg-Pro-Lys-His-Pro-Ile-Lys and P(6). These peptides were mainly originated from αs1-CN and β-CN. Three of the identified peptides (P(1), P(2), P(3) and P(4)) are known to biologically active and P(1) and P(3) were only present in experimental cheese suggesting that experimental cheese has improved health benefits.     

Antral content, secretion and peripheral metabolism of N-terminal progastrin fragments

OBJECTIVES: In addition to the acid-stimulatory gastrins, progastrin also release N-terminal fragments. In order to examine the cellular content, secretion and peripheral metabolism of these fragments, we developed an immunoassay specific for the N-terminal sequence of human progastrin. RESULTS: The concentration of N-terminal progastrin fragments in human antral tissue was 6.7 nmol/g tissue (n=5), which was only half of that of acid-stimulatory gastrins (12 nmol/g tissue). Gel chromatography of antral extracts showed that the progastrin fragment 1-35 and 1-19 constitute the major part of the N-terminal progastrin fragments. The basal concentration of N-terminal fragments in normal human plasma was almost 30-fold higher than that of the amidated, acid-stimulatory gastrins (286 pmol/l versus 9.8 pmol/l, n=26, P<0.001). In contrast, the concentration of N-terminal fragments in hypergastrinemic plasma was only 2.7-fold higher than the concentration of amidated gastrins (540 pmol vs. 198 pmol/l, P=0.02). During meal stimulation, the plasma concentrations of N-terminal progastrin fragments and amidated gastrins increased in a correlated manner (r=0.97, P=0.005). The half life for progastrin 1-35 in circulation was 30 min, and a pig model revealed the kidneys and the vasculature to the head as the primary sites of degradation. CONCLUSION: The cellular and circulatory concentration profiles of N-terminal progastrin fragments differ markedly from those of the acid-stimulatory gastrins. The high basal plasma concentrations of N-terminal progastrin fragments cannot be explained by differences in elimination.     

Mapping of the ATP-binding sites on inositol 1,4,5-trisphosphate receptor type 1 and type 3 homotetramers by controlled proteolysis and photoaffinity labeling

Submillimolar ATP concentrations strongly enhance the inositol 1,4,5-trisphosphate (IP(3))-induced Ca(2+) release, by binding specifically to ATP-binding sites on the IP(3) receptor (IP(3)R). To locate those ATP-binding sites on IP(3)R1 and IP(3)R3, both proteins were expressed in Sf9 insect cells and covalently labeled with 8-azido-[alpha-(32)P]ATP. IP(3)R1 and IP(3)R3 were then purified and subjected to a controlled proteolysis, and the labeled proteolytic fragments were identified by site-specific antibodies. Two fragments of IP(3)R1 were labeled, each containing one of the previously proposed ATP-binding sites with amino acid sequence GXGXXG (amino acids 1773-1780 and 2016-2021, respectively). In IP(3)R3, only one fragment was labeled. This fragment contained the GXGXXG sequence (amino acids 1920-1925), which is conserved in the three IP(3)R isoforms. The presence of multiple interaction sites for ATP was also evident from the IP(3)-induced Ca(2+) release in permeabilized A7r5 cells, which depended on ATP over a very broad concentration range from micromolar to millimolar.     

Conformation and disulfide bond formation of the constant fragment of an immunoglobulin light chain: effect of truncation at the C-terminal region

Constant fragments with different carboxyl terminals, CL(109-211), CL(109-207), and CL-(109-200), were prepared by limited carboxypeptidase P or Y proteolysis of the constant fragment, CL-(109-214), of a type lambda immunoglobulin light chain, and their conformations and stabilities, and formation of the disulfide bond from the reduced fragments, were studied. No change in conformation or stability was observed on removal of three residues from the C-terminal end. Removal of seven or more residues from the C-terminal end destabilized the CL fragment. The rate of disulfide bond formation from reduced CL(109-207) was about 7 times faster than that for CL(109-214). These findings suggest that elongation of the polypeptide chain at least beyond the 207th residue is necessary for folding of the CL fragment into a definite conformation.     

Identification of an epitope in the C terminus of normal prion protein whose expression is modulated by binding events in the N terminus

We have characterized the epitopes of a panel of 12 monoclonal antibodies (Mabs) directed to normal human cellular prion protein (PrP(C)) using ELISA and Western blotting of recombinant PrP or synthetic peptide fragments of PrP. The first group of antibodies, which is represented by Mabs 5B2 and 8B4, reacts with PrP(23-145), indicating that the epitopes for these Mabs are located in the 23 to 145 N-terminal region of human PrP. The second group includes Mabs 1A1, 6H3, 7A9, 8C6, 8H4, 9H7 and 2G8. These antibodies bind to epitopes localized within N-terminally truncated recombinant PrP(90-231). Finally, Mabs 5C3, 2C9 and 7A12 recognize both PrP(23-145) and PrP(90-231), suggesting that the epitopes for this group are located in the region encompassing residues 90 to 145. By Western blotting with PepSpot(TM), only three of Mabs studied (5B2, 8B4 and 2G8) bind to linear epitopes that are present in 13-residue long synthetic peptides corresponding to human PrP fragments. The remaining nine Mabs appear to recognize conformational epitopes. Two N terminus-specific Mabs were found to prevent the binding of the C terminus-specific Mab 6H3. This observation suggests that the unstructured N-terminal region may influence the local conformation within the folded C-terminal domain of prion protein.     

Proteolytic cleavage of the puromycin-sensitive aminopeptidase generates a substrate binding domain

The puromycin-sensitive aminopeptidase was found to be resistant to proteolysis by trypsin, chymotrypsin, and protease V8 but was cleaved into an N-terminal 60-kDa fragment and a C-terminal 33-kDa fragment by proteinase K. The two proteinase K fragments remain associated and retained enzymatic activity. Attempts to express the 60-kDa N-terminal fragment in Escherichia coli produced inclusion bodies. A hexa-histidine fusion protein of the 60-kDa N-terminal fragment was solubilized from inclusion bodies with urea and refolded by removal of the urea through dialysis. The refolded protein was devoid of aminopeptidase activity as assayed with arginine-beta-naphthylamide. However, the refolded protein bound the substrate dynorphin A(1-9) with a stoichiometry of 0.5 mol/mol and a K(0.5) value of 50 microM. Dynorphin A(1-9) binding was competitively inhibited by the substrate dynorphin B(1-9), but not by des-Tyr(1)-leucine-enkephalin, a poor substrate for the enzyme.     

Identification of protein domains by shotgun proteolysis

The identification of protein domains within multi-domain proteins is a persistent problem. Here, we describe an experimental method (shotgun proteolysis) based on random DNA fragmentation and protease selection of the encoded polypeptides on phage for this purpose. We applied the method to the Escherichia coli genome and identified 124 protease-resistant fragments; several were re-cloned for expression as soluble fragments in bacteria, and corresponded to autonomously folding units with folding energies similar to natural protein domains (DeltaG(u)=3.8-6.6 kcal/mol). Structural information was available for approximately half of the selected proteins, which corresponded to compact, globular and domain-sized units that had been derived from a wide range of protein superfamilies. Furthermore, boundaries of the selected fragments correlated with domain boundaries as defined by bioinformatics predictions (R2=0.82; p=0.016). However, predictions were incomplete or entirely lacking for the remaining fragments, reflecting the limited proteome coverage of current bioinformatics methods. Shotgun proteolysis therefore provides a means to identify domains and other autonomously folding units on a genome-wide scale, without any prior knowledge of sequence or structure. Shotgun proteolysis should be particularly valuable for structural studies of proteins and represents a high-throughput alternative to the classical limited proteolysis method for the isolation of stable components of multi-domain proteins.