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.     

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.     

Antigenic studies of a VH fragment: demonstration of three sets of antigens, idiotypic, VH subgroup, and VH framework-specific antigens.

The antigenic properties of the VH region of immunoglobulin heavy chains were studied by means of a fragment corresponding to the variable part of the heavy chain of an IgG3 myeloma protein (KUP) and an antiserum made against this fragment. By hemagglutination, hemagglutination inhibition, and immunofluorescence techniques, it was shown that the anti-VH antiserum detected three sets of antigens in the VH region, namely idiotypic antigens, VH subgroup-specific antigens, and VH domain-(framework) specific antigens. The VH fragment inhibited in a VHII subgroup-specific hemagglutination inhibition test system. The VH fragment was thus antigenically similar to the tvh region found in the intact molecules and the light chains were not needed to express the VH subgroup antigens or the VH framework antigens.     

Characterization of upFc, a fragment of human immunoglobulin G1 produced by pepsin in urea.

The digestion of human IgG1/K myeloma proteins with pepsin in the presence of 8 M-urea produces fragments that differ from those produced by aqueous peptic digestion, and from other characteristic immunoglobulin fragments. Fb'2, the larger urea/pepsin fragment, was previously shown to consist of the constant regions of the light chains, and the CH1 domains and hinge regions of the heavy chains. The smaller fragment, upFc, has now been characterized. After reduction, three peptides were released from fragment upFc. Amino acid sequencing, N- and C-terminal determinations and amino acid compositions have enabled these peptides to be identified as residues Ile-253 to Leu-306, residues Thr-307 to Asp-376 and residues Thr-411 to Gly-446 of the heavy chain. Fragment upFc therefore contains the entire Fc region, beginning at residue Ile-253, except for a 34-residue section from within the CH3-domain disulphide loop. Peptic digestion of IgG1/K proteins in 8M-urea therefore provides a method for isolating from gamma1 heavy chains five homogeneous peptides in good yield, which account for almost the entire constant region. Characterization of fragments Fb'2 and upFc has shown that the action of pepsin in urea is entirely different from that of aqueous pepsin. Two gamma1 heavy chains have been shown to differ in sequence at three positions from the sequence reported for protein Eu.     

Cloning and sequence of the cDNA corresponding to the variable region of immunoglobulin heavy chain MPC11.

Poly(A)-containing mRNA from mouse myeloma MPC11 was transcribed into cDNA which was cloned in the PstI site of the plasmid pBR322. The transformants were screened by hybridization with a cDNA fragment, derived from plasmid p gamma(11)7, corresponding to the 5' portion of the constant region of MPC11 heavy chain. Several positive transformants were found to contain various lengths of the variable region of the heavy chain. We describe the structure and sequence of one of these clones, pV(11)2, which contains cDNA corresponding to the entire variable region of MPC11 heavy chain and extends to codon 248 in the constant region. The protein sequence deduced from the DNA sequence indicates that the variable region of MPC11 heavy chain contains 121 amino acids and belongs to subgroup II of mouse heavy chains. Comparison of this sequence with other heavy chain sequences suggests a J (joining) segment of 16 residues which overlaps five residues of the third hypervariable region. The cDNA sequence shows that there is no discontinuity between the end of the variable region and the beginning of the constant region.     

Characterization of light chain and light chain constant region fragment mRNAs in MPC 11 mouse myeloma cells and variants

Cultured MPC 11 mouse myeloma cells synthesize not only γ_2b heavy and κ light chains but also a carboxyl terminal (constant region) fragment of κ light chain. In vitro translational analysis of total cytoplasmic and microsomal RNA indicates that these cells contain RNA which directs synthesis of both a light chain precursor and a light chain fragment precursor. Variant clones which do not synthesize either heavy or light chains continue to synthesize the light chain fragment. One such “nonproducing” variant was studied in detail. It does not contain translatable mRNA for the intact light chain but does contain RNA which is translated into the light chain fragment precursor. Nucleic acid hybridization analysis with a cDNA probe specific for the constant region of κ light chains revealed that microsomal RNA from the wild-type cell contains both a 14S and a 10S species of κ specific RNA, whereas the variant contains only the 10S species. Translational analysis of these same RNAs indicates that the 14S species codes for the light chain precursor, while the 10S RNA codes for the light chain fragment precursor.     

Intrachain disulfide bond in the core hinge region of human IgG4.

IgG is a tetrameric protein composed of two copies each of the light and heavy chains. The four-chain structure is maintained by strong noncovalent interactions between the amino-terminal half of pairs of heavy-light chains and between the carboxyl-terminal regions of the two heavy chains. In addition, interchain disulfide bonds link each heavy-light chain and also link the paired heavy chains. An engineered human IgG4 specific for human tumor necrosis factor-alpha (CDP571) is similar to human myeloma IgG4 in that it is secreted as both disulfide bonded tetramers (approximately 75% of the total amount of IgG) and as tetramers composed of nondisulfide bonded half-IgG4 (heavy chain disulfide bonded to light chain) molecules. However, when CDP571 was genetically engineered with a proline at residue 229 of the core hinge region rather than serine, CDP571 (S229P), or with an IgG1 rather than IgG4 hinge region, CDP571(gamma 1), only trace amounts of nondisulfide bonded half-IgG tetramers were observed. Trypsin digest reversephase HPLC peptide mapping studies of CDP571 and CDP571(gamma 1) with on-line electrospray ionization mass spectroscopy supplemented with Edman sequencing identified the chemical factor preventing inter-heavy chain disulfide bond formation between half-IgG molecules: the two cysteines in the IgG4 and IgG1 core hinge region (CPSCP and CPPCP, respectively) are capable of forming an intrachain disulfide bond. Conformational modeling studies on cyclic disulfide bonded CPSCP and CPPCP peptides yielded energy ranges for the low-energy conformations of 31-33 kcal/mol and 40-42 kcal/mol, respectively. In addition, higher torsion and angle bending energies were observed for the CPPCP peptide due to backbone constraints caused by the extra proline. These modeling results suggest a reason why a larger fraction of intrachain bonds are observed in IgG4 rather than IgG1 molecules: the serine in the core hinge region of IgG4 allows more hinge region flexibility than the proline of IgG1 and thus may permit formation of a stable intrachain disulfide bond more readily.     

Crystals of the human heavy chain disease protein Riv and human Fc fragment are isomorphous: further evidence for conformational flexibility in the hinge region of immunoglobulins

Protein Riv is a human gamma 1 heavy chain disease immunoglobulin variant with a deletion of the entire VH and CH1 domains and consisting of most of the hinge region plus the CH2 and CH3 domains. Crystals of this protein are orthorhombic, belonging to the space group P2(1)2(1)2(1), with a = 80.1 A, b = 145.5 A, c = 50.1 A. These crystals are shown to be isomorphous with crystals of a human Fc fragment, indicating that the hinge region and the initial part of the CH2 domain of protein Riv do not assume a unique conformation in the crystalline state.     

Structural and genetic analysis of four chicken 7S immunoglobulin allotypes

Four 7S immunoglobulin allotypic specificities in three inbred chicken lines were demonstrated in two immunoglobulin regions, probably associated with the heavy chains. Two specificities were associated with papain-produced Fab fragments, most likely the Fd fragment since they were not demonstrated on the 17S immunoglobulin. The other allotypes were detected only on intact 7S immunoglobulin and were undetectable on the Fab and Fc fragments; therefore, they probably were associated with a region of the heavy chain sensitive to papain digestion. Among F₂ hybrids, these specificities segregated in a manner statistically indistinguishable from that expected of three codominant alleles at an autosomal locus. This locus was not closely associated with any of five chicken blood group loci.     

Novel human light chain V kappa segment: serologic and structural analyses of the kappa III-like Bence Jones protein and IgG kappa light chain REE

Immunochemical and sequence analyses of kappa light chain REE (Bence Jones protein REE and the light chain isolated from IgG kappa myeloma protein REE) revealed antigenic and structural features not previously described for human kappa-chains. Although closely related to proteins of the V kappa III subgroup, light chain REE is readily distinguished from light chains classified serologically as members of the kappa IIIa or kappa IIIb sub-subgroups. Light chains REE (Bence Jones protein REE and light chain REE) are identical in sequence and differ from kappa III proteins by at least 10 uncommon amino acid substitutions in the first three framework regions. Further, kappa-chain REE is unique by virtue of a four-residue deletion in the third complementarity-determining region. The deletion encompasses the three carboxyl-terminal residues in the V kappa-encoded segment and the first residue at the site of V-J recombination. Urine specimens from patient REE also contained a light chain fragment that lacked the first (amino-terminal) 85 residues of the native light chain but otherwise was identical in sequence to the light chain REE. The extensive amino acid differences and unique length of the V kappa segment in light chain REE indicate that this kappa-chain is the product of an unusual V kappa III gene or, alternatively, represents a rarely expressed and novel human V kappa gene.     

The effect of the interaction of heavy and light chains of IgG on the Gm and Inv antigens

Studies of isolated polypeptide chains, of reconstituted, and of intact IgG show that the antigens present on the Fab fragment, Gm (3), Gm (4), and Inv (1), depend upon the interaction of heavy and light chains for their full antigenic expression, while the antigens of the Fc portion of the heavy chain, Gm (1), Gm (5), Gm (13), and Gm (14), have the same antigenicity in intact IgG, in isolated heavy chains, and in reconstituted IgG. Hybridization experiments using Bence-Jones protein light chains indicate that different homogeneous populations of light chains differ in their ability to restore Gm (3) and Gm (4) antigenicity and that this ability is independent of light-chain antigenic type.The investigations reported in this paper were supported in part by National Institutes of Health Grant GM 07214.Recipient of support from National Institutes of Health Training Grant 2T1 GM 226.     

The crystallizable human myeloma protein Dob has a hinge-region deletion.

During experiments to prepare heavy-metal derivatives of the crystallizable human IgG1 (k) immunoglobulin Dob, it became apparent that this protein has several unusual features. (1) Instead of the four labile interchain disulfide bridges ordinarily found in IgG1, the Dob protein has only a single interchain disulfide bridge, which connects its two light chains. (2) The Dob heavy chain appears to be slightly smaller than a control gamma1 chain, as judged by polyacrylamide gel electrophoresis in sodium dodecyl sulfate and by gel filtration in guanidine. (3) The Dob heavy chain has three fewer residues of half-cystine than expected in gamma1 chains. (4) The Dob IgG is relatively resistant to digestion with papain and trypsin; however, it is readily digested with pepsin, although at an unusual site. These findings suggest that some or all of the gamma1 hinge region is missing in Dob. To localize the deletion, we prepared an F(ab')2 fragment consisting of two heavy-chain pieces (Fd') noncovalently associated with the light-chain dimer. The Fd' piece was isolated and digested with trypsin. The sequence of the C-terminal tryptic peptide was Val-Ala-Pro-Glu-Leu-Leu-Gly-Gly-Pro-Ser-Val. Positions 2-11 of this peptide are identical with residue positions 231-240 of the gamma1 chain. The N-terminal valine could be either Val-211 or Val-215 of the gamma1 sequence. A tryptic peptide, Val-Asp-Lys-Lys, was also isolated from Dob Fd'; this sequence is not found in the variable region of the Dob heavy chain [Steiner, L. A., Garcia Pardo, A., & Margolies, M. N. (1979) Biochemistry (following paper in this issue)] but corresponds to positions 211-214 of the gamma1 constant region. Therefore, the deletion cannot include these residues and must begin after Val-215; normal gamma1 sequence resumes at Ala-231. The same 15-residue deletion has been found in two other IgG1 proteins, Mcg [Fett, J. W., Deutsch, H. F., & Smithies, O. (1973) Immunochemistry 10, 115] and Lec [Rivat, C., Schiff, C., Rivat, L., Ropartz, C., & Fougereau, M. (1976) Eur. J. Immunol. 6, 545]. Possible explanations for the occurrence of identical hinge-region deletions in three different immunoglobulins are suggested by recent experiments demonstrating that the three constant domains and the hinge region of mouse gamma1 chains are each encoded by separate segments of DNA [Sakano, H., Rogers, J. H., Hüppi, K., Brack, C., Traunecker, A., Maki, R., Wall, R., & Tonegawa, S. (1979) Nature (London) 277, 627].     

Cloning and complete nucleotide sequence of mouse immunoglobulin gamma 1 chain gene.

The 6.6 kb DNA fragment coding for the immunoglobulin γ1 chain was cloned from newborn mouse DNA using λgtWES·λB as the EK2 vector. The complete nucleotide sequence (1823 bases) of the γ1 chain gene was determined. The cloned gene contained the entire constant region gene sequence as well as the poly(A) addition site, but not the variable region gene. The results indicate that the variable and constant region genes of immunoglobulin heavy chain are separated in newborn mouse DNA. The constant region genes of other gamma chains (that is, γ2a, γ2b and γ3) are not present in the cloned DNA fragment. The sequence demonstrates that the γ1 chain gene is interrupted by three intervening sequences at the junction of the domains and the hinge region, as previously shown in the γ2b and α chain genes and in the γ1 chain gene cloned from myeloma. The results suggest that the intervening sequence was introduced into the heavy chain gene before divergence of the heavy chain classes, and also support the hypothesis that the splicing mechanism has facilitated the evolution of eucaryotic genes by linking duplicated domains or prototype peptides not directly adjacent to one another. Comparison of the nucleotide sequence of the γ1 chain gene around the boundaries of the coding and intervening sequences with those of other mouse genes revealed extensive divergence, although short prevalent sequences of AG-GTCAG at the 5′ border of the intervening sequence and TCTGCAG-GC at the 3′ border were deduced. A limited homology of nucleotide sequences was found among domains and between the hinge region and the 5′ portion of the CH2 domain. Comparison of 3′ untranslated sequences from the γ1 and γ2b chain genes and the mouse major β-globin gene shows significant homology and a palindrome sequence surrounding the poly(A) addition site.     

Synthesis of a carboxyl-terminal (constant region) fragment of the immunoglobulin light chain by a mouse myeloma cell line

The MPC11 mouse myeloma cell line synthesizes not only heavy chains and light chains but also an 11,600 molecular weight light chain fragment. The fragment comprises 1% of the newly synthesized protein, compared to 8% for the complete light chain. Similar amounts of fragment are produced by a number of heavy plus light chain producing subclones, 18 independently generated light chain producing variant clones, and five independent non-producing variant clones. For both the heavy plus light chain producing and the non-producing cell types, less than 20% of the fragment appears to be secreted, while the remainder is metabolized with a half-life of 30 minutes. Radiochemical peptide analyses and radiochemical amino -terminal sequence analyses are consistent with the fragment containing most of the peptide sequences present in the carboxyl-terminal half (constant region) of the parent kappa light chain, but none of the variable region peptides. The fragments produced by a heavy plus light chain producing clone and a non-producing variant clone were identical by radiochemical peptide analysis. The results suggest that the constant region fragment may be a primary gene product, and in addition, they raise the possibility that the fragment may be specified by a gene discrete from the gene specifying a light chain.     

Primary structure of human gamma 3 immunoglobulin deletion mutant: gamma 3 heavy-chain disease protein Wis

The complete sequence of a gamma 3 heavy-chain disease (HCD) protein Wis is presented. The molecule is a dimer of a 289-residue chain linked by 12 disulfide bonds. Protein Wis has an unusual amino terminus, followed by a deletion of most of the VH domain. After a small stretch homologous to the VC joining region, there is a second deletion which ends at the beginning of the quadruplicated hinge. Two carbohydrate groups are linked to Asn-6 and -140. the molecule has an extra interchain disulfide bridge at position 7 in addition to the 11 normally present in the quadruplicated hinge. The previously noted homology to the gamma 1 heavy chain is striking; from positions 224 to 234, protein Wis resembles gamma 1 Nei [Ponstingl, H., & Hilschmann, N. (1976) Hoppe-Seyler's Z. Physiol. Chem. 357, 1571--1604] except for a serine which replaces Asn at position 227. The results, taken together with studies of other immunoglobulin heavy-chain deletion mutants, support the suggestion that the different domains and interdomain regions of human H chains are coded for by different gene segments and that the deleted proteins reflect alterations in the recombination of different genes and/or the splicing of heterogeneous nuclear messenger ribonucleic acid (hn mRNA).     

Formation of intermolecular disulfide bonds on nascent immunoglobulin polypeptides.

The initial step of intermolecular covalent assembly of immunoglobulins molecules involves formation of heavy chain-light chain or heavy chain-heavy chain disulfide bonds. Using QAE-Sephadex chromatography to isolate microsomal nascent polypeptides, we have shown that this initial step of intermolecular covalent assembly occurs, to a substantial extent, on nascent heavy chains, as well as on completed heavy chains as previously demonstrated by others. In MPC 11 mouse myeloma cells, completed light chains are assembled covalently to nascent heavy chains, whereas in MOPC 21 mouse myeloma cells, completed heavy chains are assembled covalently to nascent heavy chains. These results are consisted with the heavy-light half-molecule being the major initial intermediate in the assembly of MPC 11 IgG2b and heavy-heavy dimer being the major initial intermediate formed in assembly of MOPC 21 IgG1. The nascent MPC 11 heavy chain must be at least 38,000 daltons in size before assembly with the light chain occurs, even though the heavy chain cysteine involved in this disulfide bond is 131 residues (approximately 15,000 daltons) from the NH2 terminus. In addition, pulse-chase labeling studies of MPC 11 cells have shown that the assembly of completed light chains with the nascent heavy chain must occur within a few minutes of the synthesis of the light chain even though a large excess of unassembled MPC 11 light chains remain inside the cell for an average time of 2 h before being secreted.     

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.     

Subunit structure of human alpha 2-macroglobulin (alpha 2-MG) with respect to its interaction with trypsin.

SDS-polyacrylamide gel electrophoresis of a recently prepared alpha 2-macroglobulin solution showed only the polypeptide chains of 190,000 molecular weight. Reduction-alkylation of this preparation followed by gel-filtration on a Sephadex G-200 column in 5.2 M guanidine hydrochloride was unable to separate a fraction of 83,000 molecular weight as previously described. Nevertheless, after incubation of a mixture alpha 2-macroglobulin-trypsin during 45 minutes at 37 degrees C, approximately 60 per cent of the preparation were converted in a component with 83,000 molecular weight as detected in SDS polyacrylamide gel. That component was isolated on Sephadex G-200 in guanidine hydrochloride and corresponds to the subunit, fraction II. According to the results of the present work together with those of previous studies, it can be assumed that alpha 2-MG is a 780,000 molecular weight protein (19S) formed of two half-molecules of equal weight (11-12S). The half-molecule contains two polypeptide chains of 180,000-190,000 molecular weight, each of them having, in its middle, a specific region particularly susceptible to attack by proteases.