Intrachain disulphide bridges in immunoglobulin G heavy chains. The Fc fragment

The disulphide bridges of the Fc fragment (C-terminal half of the heavy chain) have been studied in several human immunoglobulins, containing heavy chains of different antigenic types (gamma1, gamma2, gamma3 and gamma4), and in heavy-chain-disease proteins. Two intrachain disulphide bridges were found to be present. The sequences appear to be identical in the Fc fragments of two types of chain studied (gamma1 and gamma3), and very similar to corresponding sequences of the Fc fragment in rabbit. These results suggest that the C-terminal half of the heavy chains is covalently folded (in a similar fashion to the light chains) with a C-terminal loop and an N-terminal loop. The similarity is emphasized by comparison of the sequence and location of the disulphide-bridged peptides of the C-terminal loop of heavy and light chains. The N-terminal loop, on the other hand, appears to be very different in Fc fragments and light chains. The C-terminal loop is the only one present in the F'c fragment.     

The disulphide bridges of a mouse immunoglobulin G1 protein

[(35)S]Cystine-labelled immunoglobulin MOPC21 (IgG1) was prepared from myeloma cells in tissue culture. Carrier myeloma protein was added and the protein was digested with pepsin. The digest was fractionated on Sephadex G-50 into two fractions, further digested with trypsin and again fractionated on Sephadex. Disulphide-bridge peptides were purified by electrophoresis and chromatography and identified by radioautography. A peptide of 96 residues was isolated, which contains both the heavy-light interchain disulphide bridge and all the inter-heavy-chain disulphide bridges. Other peptides were isolated, accounting for all the intrachain disulphide bridges (which could be placed by homology with proteins of other species), except for the variable section of the light chain. Sequences describing this missing disulphide bridge were obtained from totally reduced and alkylated light chains. Peptides related to the interchain disulphide-bridge peptide were isolated from partially reduced and alkylated myeloma protein and from totally reduced heavy chain. The interchain disulphide-bridge peptide was placed at the C-terminal position of the F(ab')(2) fragment, prepared by digestion of the protein with pepsin at pH4.0. Sequences from the heavy-chain intrachain disulphide bridges of MOPC 21 immunoglobulin are compared with homologous sequences from mouse myeloma proteins of other subclasses and proteins of other species.     

Isolation and properties of a fragment of human serum albumin demonstrating the absence of a methionine residue from some of the albumin molecules.

1. A fragment designated D was isolated from human serum albumin degraded by CNBr. Its properties show that it is made up of the B and C fragments isolated by McMenamy et al. (1971) (J. Biol. Chem., 246, 4744-4750). 2. Reduction of fragment D gives rise to two chains, one of which consists of the second subfragment of reduced fragment B linked to fragment C by an amino acid different from methionine. It thus demonstrates the existence of albumin molecules from which the second methionine residue located between fragments B and C is missing.     

Isolation and study of a fragment of human serum albumin containing one of the antigenic sites of the whole molecule

1. A fragment of human serum albumin called `inhibitor' has been degraded by trypsin, and one of the degradation products, designated fragment F1, has been isolated. Fragment F1 has a molecular weight of 6600. It contains neither tyrosine nor tryptophan. It is not precipitated with rabbit anti-sera to human serum albumin. 2. Fragment F1 was coupled to p-aminobenzylcellulose to form an insoluble conjugate. Rabbit anti-(human serum albumin) antibodies reacting with fragment F1 were specifically adsorbed on this conjugate and were desorbed by glycine–hydrochloric acid buffer. The isolated antibodies are composed of γ-globulin and β₂-macroglobulin. 3. Human serum albumin and fragment F1 formed with 7s anti-(fragment F1) antibodies soluble complexes that were studied by passive haemagglutination, ultracentrifugation and electrophoresis. Fragment F1 was shown to contain only one of the antigenic sites of albumin molecule. The 7s anti-(fragment F1) antibodies were shown to be bivalent and monospecific.     

Location of the inter-chain disulfide bonds of the third component of human complement

Location of the disulfide bonds connecting three polypeptide chains (alpha 3, 27kd; 2, 43kd; beta, 75kd) of C3c has been investigated by partial reduction with cysteine followed by alkylation with 14C-monoiodoacetic acid. Treatment of C3c with cysteine produced a partially reduced fragment, composed of disulfide-linked beta and alpha 3 chains. A single thiol residue was detected on the alpha 3 chain but not on the beta chain of the fragment, suggesting that the alpha 2 chain in C3c is linked through a single disulfide bond to the alpha 3 chain but not to the beta chain.     

Fc and Fab Fragments from IgG<Subscript>2</Subscript> Human Immunoglobulins Characterized

Papain digestion of 7S immunoglobulin G (IgG) produces two 3.5S Fab fragments and one 3.5S Fc fragment^1–8. The Fab fragment contains one light chain and one Fd fragment and is still able to combine specifically univalently with antigen. The Fc fragment is a dimer of the carboxyl terminal half of the heavy chain. Pepsin splits 7S IgG into some small peptides derived from Fc and one 5S F(ab′)₂ fragment, which contains both antigen-binding sites. Based on this information, some investigators^6,7 have postulated that pepsin splits the γ chains at the C-terminal side of the inter-heavy chain disulphide bridges, whereas papain splits at the N-terminal side of the inter-heavy chain disulphide bridges. We report here evidence that this model does not apply to all IgG subclasses. In the case of human IgG₂ subclass myeloma proteins, papain splits initially at the C-terminal side of inter-heavy chain disulphide bridges. We also show that the amino-acid sequence of the Fc fragment of human IgG₂ subclass so far determined has approximately 95% homology with that of human IgG₁ and IgG₄ subclasses reported by others^9–15.     

Limited pepsin digestion of human plasma albumin.

Limited pepsin digestion of human plasma albumin at pH 3.5 and 0 degrees in the presence of octanoate caused cleavage at residue 307 of the albumin molecule to yield two fragments. Thw two fragments corresponding to the NH2- and the COOH-terminal halves of the molecule were isolated in yields of about 15%. The COOH-terminal fragment is a mixture in which about 85% of the molecules had an additional cleavage at residue 422 of the albumin molecule. The COOH-terminal fragment with the additional cleavage at residue 422 contains two peptides which are linked by a disulfide bridge at residues 391 and 437 of the albumin molecule. Both the NH2- and the COOH-terminal fragment of human albumin showed no detectable binding of octanoate anions, that is, less than 1/170 of the binding constant of the primary site of human albumin. These findings differ from earlier observations on limited pepsin digestion of bovine plasma albumin where the corresponding COOH-terminal fragment had the octanoate-binding activity, about 1/8 of the primary binding constant of bovine albumin, while the NH2-terminal fragment did not. The COOH-terminal fragment of bovine albumin did not have cleavage at residue 422 as in the corresponding fragment of human albumin. However, it is not clear that the loss of octanoate-binding activity of fragment C of human albumin is a direct consequence of the cleavage at residue 422.     

An abnormal human IgA1 half-molecule.

An IgA1 half-molecule, which is composed of a deleted alpha1 chain linked with a disulfide bond to an intact kappa chain, was detected in a patient (Cha). The molecular weights of the paraprotein and the isolated alpha1 chain were estimated to be 75 000 and 53 000, respectively. Identification of tyrosine as the C-terminal amino acid and the presence of idiotypic determinants in the abnormal alpha1 chain indicated that the molecule would have an intact N-terminal variable region and a C-terminal region. Furthermore, no cleavage of the abnormal protein into Fab and Fc by proteolytic enzyme isolated from Neisseria gonorrhoeae suggested the absence of a "hinge" region in the abnormal alpha1 chain.     

Isolation, by partial pepsin digestion, of the three collagen-like regions present in subcomponent Clq of the first component of human complement.

1. Digestion of human subcomponent C1q with pepsin at pH4.45 for 20h at 37 degrees C fragmented most of the non-collagen-like amino acid sequences in the molecule to small peptides, whereas the entire regions of collagen-like sequence that comprised 38% by weight of the subcomponent C1q were left intact. 2. The collagen-like fraction of the digest was eluted in the void volume of a Sephadex G-200 column, was was showm to be composed of two major fragments when examined by electrophoresis on polyacrylamide gels run in buffers containing sodium dodecyl sulphate. These fragments were separated on CM-cellulose at pH4.9 in buffers containing 7.5M-urea. 3. Human subcomponent C1q on reduction and alkylation yields equimolar amounnts of three chains, which have been designated A, B and C [Reid et al. (1972) Biochem. J. 130, 749-763]. One of the pepsin fragments was shown to be composed of the N-terminal 95 residues of the A chain linked, via residue A4, by a single disulphide bond to a residue in the sequence B2-B6 in the N-terminal 91 residues of the B chain. The second pepsin fragment was shown to be composed of a disulphide-linked dimer of the N-terminal 94 residues of the C chain, the only disulphide bond being located at residue C4.4. The mol. wts. of the unoxidized and oxidized pepsin fragments were estimated from their amino acid compositions to be 20 000 and 18 200 for the A-B and C-C dimers and 11 400, 8800 and 9600 for the collagen-like fragments of the A, B and C chains respectively. Estimation of the molecular weights of the peptic fragments by polyacrylamide-gel electrophoresis run in the presence of sodium dodecyl sulphate gave values that were approx. 50% higher than expected from the amino acid sequence data. This is probably due to the high collagen-like sequence content of these fragments.     

Platelet membrane glycoprotein I: structure and function. The domain of glycoprotein I involved in the von Willebrand receptor

The basic structure of platelet membrane glycoprotein I (GPI) and its relation to glycocalicin are now well understood. Glycocalicin is a proteolytic fragment produced by the action of an endogenous Ca2+ activated protease. GPI consists of two glycopeptides, an alpha and a beta chain connected by a disulphide bridge. Glycocalicin is the major part of the GPI alpha chain and can be split by trypsin into a heavily glycosylated trypsin-resistant fragment and a peptide containing at least one intramolecular disulphide bridge and a thrombin binding site. Both the alpha and the beta chains of GPI show hydrophobic properties and are probably integral membrane proteins. The position of the von Willebrand factor binding site within the GPI molecule is still controversial but the bulk of the evidence points to it lying within the non-glycosylated part of the glycocalicin fragment. It is however evident that the GPI beta chain may influence the GPI alpha chain in maintaining the correct conformation of the binding site. The von Willebrand factor binding site and the thrombin binding site appear to be independent but may nevertheless influence one another.     

Human complement component C1s. Partial sequence determination of the heavy chain and identification of the peptide bond cleaved during activation

Human C1s proenzyme (Mr 83 000) was isolated by a rapid two-stage method involving affinity chromatography of C1 on IgG-Sepharose and isolation of subcomponent C1s by ion-exchange chromatography on DEAE-Sephacel. Single-chain C1s proenzyme was activated to two-chain C1s with self-activated C1r. After reduction and S-carboxamidomethylation the heavy chain of C1s (Mr 57 000) was isolated by ion exchange chromatography on DEAE-Sephacel. Cleavage of C1s heavy chain with CNBr yielded five fragments whose N-terminal sequences were determined. The alignment of the fragments within the heavy chain was established by tryptic peptides containing methionine. C1s heavy chain comprises about 470 amino acid residues and 42% of its sequence was determined. An intrachain sequence homology and a homology to the alpha 2 chain of human haptoglobin were identified. The C-terminal CNBr fragment comprising 44 amino acid residues was completely sequenced. From BNPS-skatole cleavage of reduced and alkylated C1s proenzyme a fragment was isolated which overlaps the C1s heavy and light chain parts and which contains the peptide bond cleaved during activation. The results show that this is an Arg-Ile bond and that under standard conditions of activation no peptide material is liberated from this portion of the molecule. The sequence data and homology to two-chain serine proteases indicate a single interchain disulfide bond in C1s.     

The mechanism of activation of human prothrombin by an activator isolated from Dispholidus typus venom.

Purified human prothrombin was activated, both in the absence and in the presence of thrombin inhibitors (diisopropylfluorophosphate or hirudin), by a coagulant principle isolated from Dispholidus typus venom. The process of activation was monitored by sodium dodecyl sulfate polyacrylamide gel electrophoresis. In the absence of thrombin inhibitor, prolonged incubation of prothrombin with the purified venom yielded thrombin, fragment 1 (F 1) and fragment 2 (F 2). In the presence of diisopropylfluorophosphate, which in the experimental conditions used inhibited only partially the thrombin generated activity, products obtained upon activation of prothrombin by venom were F 1 and a two-chain, disulfide-bridged protein of 58 000 daltons called meizothrombin (des F 1). In the presence of hirudin, which fully inhibited thrombin generated activity, prothrombin activation by the venom did not liberate any fragment, but prothrombin was converted to a derivative composed of two disulfide-bridged polypeptide chains of 48 000 and 37 000 daltons, called meizothrombin. These results are similar to those reported by others when studying the process of prothrombin activation by Echis carinatus venom and allow to conclude that Dispholidus typus venom cleaves a bond linking the A and B chains of thrombin, converting prothrombin into meizothrombin. This enzyme is then responsible for the cleavage of the bond linking F 1 and F 2 and the bond linking F2 the A chain of thrombin.     

Purification and characterization of alpha 1-thiol proteinase inhibitor and its identity with kinin- and fragment 1.2-free high molecular weight kininogen

1. alpha 1-Thiol proteinase inhibitor (alpha 1 TPI) purified from outdated human plasma was a glycoprotein with Mr 83,000 and was composed of heavy and light chains held together with a disulfide bond. 2. The data on amino acid composition, amino terminal sequence of the light chain and carboxyl terminal sequences of the heavy and light chains indicate that alpha 1 TPI is identical with kinin- and fragment 1.2-free HMW kininogen. 3. Purified human plasmin generated a derivative having the same molecular weight (Mr 83,000), same subunit structure (heavy and light chains) and same inhibitory capacity as alpha 1 TPI from HMW kininogen and kinin-free HMW kininogen. This indicated the possibility that alpha 1 TPI is derived from HMW kininogen by plasmin.     

Heat-induced thiol-disulfide interchange reaction on the third component of human complement, C3

The third component of human complement, C3 is composed of two disulfide-bridged polypeptide chains of Mr 120,000 (alpha chain) and Mr 70,000 (beta chain). C3 has a thioester bond that serves as a binding site for targets when C3 is activated. Heat treatment of C3 induces autolytic peptide bond cleavage at the thioester site in the alpha chain as well as rupture of the thioester bond. The alpha chain fragments are linked to each other and beta chain via disulfide bonds. This study, however, documented that prolonged heating gave rise to liberation of several fragments including beta and the larger fragment of alpha chain. Using a fluorescent thiol reagent and [14C]iodoacetamide, we analyzed thiol residues present on each fragment, and elucidated that the thiol residue exposed by rupture of the thioester bond shifts in turn to another fragment resulting in the liberation of the fragments. The results were compatible with those on C4, and suggested that the generated thiol residue induces thiol-disulfide interchange reaction. On heating of plasma, fragments of C3 were not released, while the cleavage of the alpha chain occurred more effectively. The heated C3 (56 degrees C, 15 min) became insusceptible to C3b inactivator (I) and factor H, suggesting that additional conformational change is accompanied with cleavage of the thioester bond.     

The effect of thrombomodulin on the cleavage of fibrinogen and fibrinogen fragments by thrombin

Thrombomodulin acts as a linear competitive inhibitor of thrombin with respect to the substrate fibrinogen. In the present study the effect of thrombomodulin on the activity of thrombin with fragments of the A alpha and B beta chain of fibrinogen has been examined. The cleavage of fibrinopeptide A from the N-terminal disulphide knot, fragment 1-44 and fragment 1-51 of the A alpha chain was inhibited by thrombomodulin. The average value for the inhibition constant obtained with these substrates was 0.83 +/- 0.09 nM, which was in good agreement with the values obtained previously for the inhibition of thrombin by thrombomodulin with native fibrinogen as the substrate [Hofsteenge, J., Taguchi, H. & Stone, S. R. (1986) Biochem. J. 237, 243-251]. In contrast, the cleavage of fibrinopeptide A from fragment 1-23 and fragment 1-29 of the A alpha chain was not affected by thrombomodulin. Although the cleavage of the B beta chain in the intact fibrinogen molecule was inhibited by thrombomodulin [Hofsteenge, J., Taguchi, H. & Stone, S. R. (1986) Biochem. J. 237, 243-251], the release of fibrinopeptide B from the N-terminal disulphide knot and the N-terminal 118-residue fragment of the B beta chain was not inhibited by thrombomodulin. In addition, we determined the second-order rate constants of cleavage of these substrates using human thrombin. Fragments of the A alpha chain whose cleavage was inhibited by thrombomodulin were found to have values for kcat/Km that were within one order of magnitude of that for the native fibrinogen, whereas those for A alpha chain fragments whose cleavage was not inhibited by thrombomodulin were found to be more than two orders of magnitudes lower. From these results we conclude that only a relatively small portion of the A alpha chain of the fibrinogen molecule is responsible for the specific binding to thrombin that is affected by thrombomodulin. Moreover, residues 30-44 of the A alpha chain play an important role in this thrombin-fibrinogen interaction.     

Fb''2, a new peptic fragment of human immunoglobulin G.

The digestion of a human IgG1 K myeloma protein with pepsin in the presence of 8M-urea was observed to produce a fragment, designated Fb'2, which differed from the products of aqueous peptic digestion and from other characteristic immunoglobulin digestion products. 2. Fragment Fb's was also found when two other IgG1/K proteins were treated similarly. 3. Sedimentation-equilibrium studies showed the mol.wt. of fragment Fb'2 to be 56800. 4. On reduction, two equivalents of each of three peptides were released from fragment Fb's; these were characterized by N- and C-terminal determinations and by amino acid sequencing. 5. Fragment Fb'2 was shown to consist of the constant regions of both light chains, from residue Ile-117 to the C-terminus, and the CH1 domains and hinge region of the heavy chains, from residue Val-113 to residue Met-252, with a gap of five residues within the intrachain disulphide loop, between residues Leu-174 and Tyr-180.     

Purification and characterization of peptic fragments derived from the carboxyl-terminal half of human albumin

Utilizing a combination of conventional and affinity-chromatographic procedures, we have purified four fragments of human albumin that were generated by controlled limited proteolysis with pepsin [0.3 mM albumin; 37°C; 10 min; pH 3.51; 4.2 mM octanoate; pepsin/albumin, 1:1000 (w/w)]. These fragments have a molecular weight range of 9200-17,000 Da. Amino acid compositions, N- and C-terminal sequences, molecular weights, and other internal markers were used to determine the location of these fragments within the parent molecule. All of the fragments were shown to be derived from the C-terminal half of human albumin. The presence of multiple pepsin-sensitive bonds near the C terminus of each fragment complicated the assignment of specific residue numbers to each fragment. Two pairs of similar peptides were identified: (A) those corresponding to a single-loop structure (residues 309–380 and 309–387) and (B) those containing multiple loops and intraloop cleavages [residues 309–(491–495) with 408–423 deleted]. Purification of these fragments without disulfide bond reduction confirms portions of the loop structure of human albumin and demonstrates increased susceptibility of two specific regions of the C-terminal half of the molecule to peptic digestion.     

Botulinum neurotoxin type A: cleavage of the heavy chain into two halves and their partial sequences

The 145-kDa type A botulinum neurotoxin (NT) is produced by the bacteria Clostridium botulinum (strain, Hall). The heavy (H) and light (L) chains (97- and 53-kDa, respectively) of this protein are linked by at least one disulfide bond. The N- and C-terminal halves of the H chain appear to have different functions in the mechanism of action of the NT [1987) FEBS Lett. 226, 115-120). Well-characterized and highly purified preparations of the two halves of the H chain are needed for such studies. Two different approaches were taken to cut the H chain with trypsin and isolate the fragments. In one method the cleavage products were: (i) 94-kDa fragment made of the L chain linked to the N-terminal half of the H chain (49 kDa) by a disulfide bond(s), and (ii) the C-terminal 44-kDa fragment. The N-terminal half of H chain was separated from the L chain by reducing the disulfide bond(s) linking them and then purified by ion-exchange chromatography. The 1-27 residues of 49-kDa N-terminal half of the H chain were Ala-Leu-Asn-Asp-Leu-Cys-Ile-Lys-Val-Asn-Asn-Trp-Asp-Leu-Phe-Phe-Ser-Pro- Ser-Glu - Asp-Asn-Phe-Thr-Asn-Asp-Leu-. The sequence of the other half of the H chain (44 kDa) was X-Ile-Ile-Asn-Leu-X-Ile-Leu-Asn-Leu-Arg-Tyr-Glu-X-Asn-His-Leu-Ile-Asp-Le u-Lys- X-Tyr-Ala-Ser-. In the second method, the H chain was first separated from the L chain, purified, and then cleaved. One product of cleavage, the 44-kDa fragment, was partially sequenced; the first 25 residues were identical to the sequence of the 44-kDa fragment generated by the first method. The present work also demonstrated that (i) The cysteine residue(s) located on the N-terminal half of the H chain form the -S-S- link(s) with the L chain. (ii) The other half of the H chain (44-kDa fragment, apparently the C-terminal half) is not linked via -S-S- to the L-chain or to the N-terminal half (49-kDa fragment) of the H chain.(ABSTRACT TRUNCATED AT 400 WORDS)     

The molecular organization of the protein HC-IgA complex (HC-IgA)

Complexes of protein HC and monoclonal IgA1 or IgA2 or polyclonal IgA were isolated from human blood plasma. Dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting showed that all complexes contain three types of chains: two light immunoglobulin chains, one regular IgA alpha-chain, and one chain with Mr = 90,000 carrying both alpha-chain and protein HC epitopes. The complexes were split into Fab alpha and Fc alpha fragments by bacterial IgA proteases. The protein HC epitopes were linked to the Fc fragments. Complexes of protein HC and an alpha-chain devoid of the variable region and the first heavy chain constant domain could also be demonstrated to be present in the blood plasma of a patient with alpha-heavy chain disease. Pepsin digestion of HC-IgA released a fragment containing all the protein HC epitopes and the C-terminal nonapeptide of the IgA alpha-chain. The light immunoglobulin chains, the regular alpha-chain, and the 90,000-Da chain from monoclonal HC-IgA1 were isolated by preparative dodecyl sulfate-polyacrylamide gel electrophoresis and by repeated gel filtration in dodecyl sulfate-containing buffer. The N-terminal amino acid sequence of the alpha-chain was identical with that of a regular human heavy immunoglobulin chain of subgroup III. Subtractive degradations of the 90,000-Da chain displayed 2 amino acid residues in each position in a pattern suggesting simultaneous degradations of a chain identical with the regular alpha-chain of HC-IgA and of uncomplexed, low molecular weight, protein HC. All the results are compatible with a model for HC-IgA in which a single low molecular weight protein HC polypeptide chain is covalently linked, side by side, to the C-terminal nonapeptide of one of the two alpha-chains of a regular monomeric IgA unit.     

Preparation and analysis of peptide fragments produced by pepsin hydrolysis of human plasma albumin and their relationship to its structure

Human plasma albumin was prepared and subjected to proteolysis by pepsin at pH2.45 at 25 degrees for 10min. with albumin/pepsin ratio 3000:1. Five peptide fragments were detected in the proteolysate by means of zone electrophoresis and gel filtration; these were separated and purified. Molecular weights, amino acid composition and disulphide bond content of the purified fragments were determined. The results show that a high proportion of the polypeptide chain of albumin appears to have a low cystine content, and at low pH values the molecule would be expected to have a considerable degree of freedom in its structure in these regions of the chain. A tripartite model for the structure of plasma albumin is proposed.