Physicochemical and immunochemical properties of heavy chains of immunoglobulin G typical of malignant growth

Molecular weight of heavy chains of immunoglobulin G typical of cancer is studied immunoglobulin and may be responsible for manifestation of certain anomalous acid and peptide composition of this protein heavy chains as compared with immunoglobulin G in blood serum of healthy people. Immunochemical methods helped detecting an antigenic determinant (or determinants) which is arranged in the heavy chains of the studied immunoglobulin and may be responsible for manifestation of certain anomalous properties of cancer-typical immunoglobulin G molecules. A set of bromo-cyanogenic fragments differing from the spectrum of these fragments in the heavy chains of normal immunoglobulin G is formed following a specific chemical effect of bromo-cyanogen on the heavy chains of immunoglobulin G typical of cancer. Essential differences are found in dancyl-fingerprints of the heavy chains of the compared proteins. Everything mentioned is a result of changes in the primary structure of the heavy chains of immunoglobulin G typical of cancer.     

The partial sequence of two large peptides from the N-terminal half of heavy chains from normal rabbit immunoglobulin G

The partial amino acid sequence of two large peptides is described. These were prepared from the N-terminal half of the heavy chain of immunoglobulin G from pooled normal rabbit serum by tryptic digestion after the in-amino groups of the lysine residues had been blocked with S-ethyl trifluorothioacetate. These peptides are believed to account for about 145 residues of fragment C-1, the N-terminal section of rabbit immunoglobulin G heavy chain prepared by cyanogen bromide cleavage. The evidence from the present paper and the preceding paper (Cebra, Givol & Porter, 1968) suggests that it may be possible to deduce a predominant amino acid sequence for most, if not all, of this section of the molecule.     

The N-terminal sequence of the heavy chain of rabbit immunoglobulin IgG

The absence of an N-terminal amino acid with a free alpha-amino group from the heavy chain of rabbit immunoglobulin IgG has been confirmed and no evidence could be found of a blocking formyl, acetyl or propionyl group. The N-terminal amino acid appears to be pyrrolid-2-one-5-carboxylic acid (PCA) in all molecules. A mixed amino acid sequence follows in the approximate proportions: PCA-Ser-Val-Glu-Glu-Ser-Gly-Gly-Arg, 50%; PCA-Ser-Leu-Glu, 20%; PCA-Glu(NH(2)), 20%. The heavy chains of a purified antibody, namely anti-(human serum albumin), and of immunoglobulin IgG from a rabbit homozygous at the allotypic loci both showed a similar mixed N-terminal sequence.     

Allotype-related sequence variation of the heavy chain of rabbit immunoglobulin G

The heavy chain of rabbit immunoglobulin G exists in three major allotypic patterns, Aa1–Aa3. A comparison of the amino acid compositions of the heavy chains isolated from immunoglobulin IgG homozygous for each allotypic determinant revealed the presence of an additional methionine residue per chain in the Aa3 allotype relative to the Aa1 and Aa2 allotypes. The position of the additional methionine residue was determined by cyanogen bromide cleavage and by tryptic digestion of the γ-chains; it coincided with the inter-Fd–Fc area of the chain. Isolation and characterization of the corresponding tryptic peptides of 31 amino acid residues from each of the allotypes showed the presence of a methionine-for-threonine replacement in the Aa3 allotype, but only in about 70–80% of the molecules. No other allotypic variations were seen in this tryptic peptide. Allotypically related variations in composition were also detected in the N-terminal cyanogen bromide-cleavage peptide.     

Interconversion of conformational isomers of light chains in the Mcg immunoglobulins.

Previous crystallographic studies in this laboratory demonstrated that immunoglobulin light chains with the same amino acid sequence can have at least two and probably three or more conformations, depending on whether the second member of an interacting pair is a light or heavy chain. If a heavy chain is not available in the assembly medium, a second light chain plays the structural role of the heavy chain in the formation of a dimer. In the present work, the lambda-type light chains were dissociated from the heavy chains of a serum IgG1 immunoglobulin from the patient Mcg and reassembled noncovalently into a dimer. The reassembly process was completed by allowing the penultimate half-cystine residues to form an interchain disulfide bond. The covalently linked dimer was compared with the Mcg urinary Bence-Jones dimer, for which an atomic model has been fitted to a 2.3-A electron density map. The assembled dimer and the native Bence-Jones protein were indistinguishable in their chromatographic and electrophoretic properties, as well as in their activity in the binding of bis(dinitrophenyl)lysine. These results indicate that the light chains can be converted into the two types of Bence-Jones conformational isomers. The procedure was also reversed: the two Bence-Jones isomers were dissociated and reassembled as the single type of isomer associating with each of two heavy chains in the IgG1 protein. The change in activity occurring when a light chain associates with a heavy chain instead of a second light chain is illustrated by the fact that the Mcg IgG1 immunoglobulin does not bind dis(dinitrophenyl)lysine in measurable amounts.     

Sequence studies of the Fd section of the heavy chain of rabbit immunoglobulin G

A partial amino acid sequence was given by Cebra, Steiner & Porter (1968b) of the N-terminal half of the heavy chain of rabbit immunoglobulin G. This was extended and in part corrected to give a continuous sequence of 136 residues, which together with other work accounts for three-quarters of the total sequence. Evidence is given suggesting that there is a limited region of 10–15 residues that are exceptionally variable in the heavy chains from pooled rabbit immunoglobulin G.     

Partial amino acid sequence and genetic control of latent a2 allotype induced in rabbits by immunization with anti-a2 antibody

We have shown that after immunization of homozygous a1 rabbits of the B immunoglobulin (Ig) heavy chain haplotype with anti-a2 antibody (Ab) a population of molecules appears that has all of the serologic characteristics of the a2 allotype. We have now isolated these putative latent a2 molecules, have separated the heavy chains, and after enzymatic deblocking, have determined the first 19 N-terminal amino acids. For all eight allotype-associated residues, these putative latent a2 molecules have the amino acid residues typical of a2 allotype. As expected, the preimmune IgG from this a1a1 rabbit has the amino acids typical of the a1 allotype. Thus by partial amino acid sequence analysis, we provide additional evidence that the latent a2 allotype can be induced in a1a1 rabbits of the B heavy chain haplotype by immunization with anti-a2 Ab. Rabbits of other heavy chain haplotypes were also immunized with anti-a2 Ab and were tested for their ability to synthesize latent a2 allotype. Thus far, a1a1 rabbits of the A, B, C, and I heavy chain haplotypes all synthesize latent a2 allotype. In contrast, a3a3 rabbits of the G and H heavy chain haplotypes did not synthesize latent a2 allotype.     

Anomalous behavior of goldfish IgM heavy chain in sodium dodecylsulfate polyacrylamide gel electrophoresis

By sodium dodecylsulfate polyacrylamide gel electrophoresis, the heavy chain of the serum immunoglobulin (IgM) of the goldfish (Carassius auratus) differs not only from other studied vertebrate serum IgM heavy chains, but also from other vertebrate lymphocyte membrane IgM heavy chains including those from the goldfish itself. This difference, an increase in apparent Mr of approximately 5000, was investigated by assessing in comparison with the IgM heavy chain of human and rainbow trout (Salmo gairdneri) the following properties: (1) molecular size by gel filtration in denaturing buffers; (2) carbohydrate content, by direct analysis; (3) intrinsic net charge, by isoelectric focusing; (4) net hydrophobicity, deduced from amino acid analysis; and (5) sodium dodecylsulfate binding by direct measurement. Results indicate that goldfish IgM heavy chain is indistinguishable from other IgM heavy chains in terms of (a) its gel-filtration behavior in denaturing conditions, (b) its carbohydrate content (which is similar to trout IgM heavy chain) and (c) its intrinsic net charge and hydrophobicity. However, goldfish IgM does differ from the other proteins studied in its detergent-binding ability and it is this behavior that is concluded to be the cause of its unusual mobility in sodium dodecylsulfate polyacrylamide gel electrophoresis.     

Ornithodoros moubata: host immunoglobulin G in tick hemolymph

Hemolymph proteins of a soft tick, Ornithodoros moubata, were analyzed immunochemically and biochemically. The components of tick hemolymph proteins were shown to be totally different from the host (rabbit) serum proteins by polyacrylamide gel electrophoresis with sodium dodecyl sulfate and Coomassie blue or silver stain. However, in the hemolymph of ticks engorged from rabbits immunoglobulin G was detected by immunoblotting analysis with goat anti-rabbit immunoglobulin G. The concentration of rabbit Immunoglobulin G in tick hemolymph changed with the physiological stages after a blood meal. Immunoglobulin G was isolated from tick hemolymph by affinity chromatography on a Protein A-Sepharose 4B column. Analysis of the isolated immunoglobulin G from tick hemolymph with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Ouchterlony double diffusion test showed it to be composed of the same subunits as heavy and light chains of host (rabbit) immunoglobulin G. Tracer experiments showed that 125I-labeled heavy and light chains of immunoglobulin G were detected in an intact form in hemolymph from ticks that sucked 125I-labeled rabbit immunoglobulin G through an artificial membrane. These facts suggested that the host rabbit immunoglobulin G ingested in the tick midgut passed through the gut wall without digestion. By solid-phase enzyme immunoassay, immunoglobulin in the hemolymph was shown to retain its antibody activity.     

Sequence of the full-length immunoglobulin kappa-chain of mouse myeloma MPC 11.

MPC 11 mouse myeloma cells synthesize two immunoglobulin kappa light chains, coded by two separate genes. One of these Kappa-chains has no variable region and is degraded intracellularly. The other is a full-length kappa-chain contaning both variable and constant regions: this chain is secreted, both by itself and combined with heavy chains in molecules of immunoglobulin G. This paper reports the amino acid sequence of the myeloma MPC 11 full-length kappa-chain. The chain is unusual in having 12 extra residues at its N-terminus when its sequence is aligned with those of other mouse kappa-chains; no other anomalies were found in its sequence.     

Variation in the N-terminal sequence of heavy chains of immunoglobulin G from rabbits of different allotype

The sequences of the N-terminal peptides prepared by Pronase digestion of the heavy chain of rabbit immunoglobulin G of allotype Aa1, Aa2 and Aa3 were determined and were shown to be related to the allotype. An N-terminal fragment of about 34 residues was also prepared from the allotype heavy chains, by cleavage with cyanogen bromide; the yield varied with the allotype. The sequences of the cyanogen bromide fragments from the Aa1 and Aa3 heavy chains contain allotype-related variations similar to those found in the N-terminal Pronase peptides, and these sequences are thought to be representative of the whole heavy-chain populations. There is about 60% homology between the two sequences, and superimposed on the differences between them there are a number of positions within each sequence at which at least two amino acids are present.     

The amino acid sequences of the Fd fragments of two human γ heavy chains

The amino acid sequences of the Fd fragments of two human pathological immunoglobulins of the immunoglobulin G1 class are reported. Comparison of the two sequences shows that the heavy-chain variable regions are similar in length to those of the light chains. The existence of heavy chain variable region subgroups is also deduced, from a comparison of these two sequences with those of another gamma 1 chain, Eu, a mu chain, Ou, and the partial sequence of a fourth gamma 1 chain, Ste. Carbohydrate has been found to be linked to an aspartic acid residue in the variable region of one of the gamma 1 chains, Cor.     

Differential reduction of interchain disulphide bonds of mouse immunoglobulin G

The relative lability of the interchain disulphide bonds of mouse G_2a-myeloma protein 5563 was studied as a function of 2-mercaptoethanol concentration. Analysis of partial-reduction mixtures by polyacrylamide-gel electrophoresis and microdensitometry showed that the disulphide bonds between light and heavy chains are much more susceptible to reduction than the bonds between heavy chains. At a low concentration of 2-mercaptoethanol (10mm) the major dissociable products of mouse immunoglobulin G are heavy-chain dimers and free light chains. These findings contrast with the reported behaviour of rabbit immunoglobulin G, for which the lability of inter-heavy-chain bonds was found to exceed that of the bonds linking light and heavy chains (Hong & Nisonoff, 1965); the relative stability of rabbit immunoglobulin G interchain bonds was confirmed in the present study. Examination of human immunoglobulin G and an immunoglobulin G (γ2) of guinea pig showed that at least in the majority of molecules, as with mouse immunoglobulin G, the disulphide bonds between light and heavy chains are more susceptible to reduction than the inter-heavy-chain bonds.     

Possible palindromes in immunoglobulin heavy-chain genes: Their role in membrane attachment

An analysis of mRNA structures as deduced from the amino acid sequences of immunoglobulin heavy chains reveals possible base-paired regions within the sequences coding for the 20 C-terminal amino acids of the human and chains. The two regions are similar in structure and contain a palindrome which might serve as an enzyme recognition site. Although other base-paired regions can be predicted in the remainder of the constant regions of these heavy chains, they have no common features. These regions and the palindromes within them may be involved in the regulation of membrane and serum immunoglobulin synthesis. Two possible mechanisms for this are proposed.     

Contribution to the structural characterization of gamma globulin from pig colostrum

From the results obtained in the present work it is concluded that gamma globulin of the 7 S type (γG) which represents the main immunoglobulin component of pig colostrum, differs from serum γG globulin by the presence of another type of polypeptide chain, designed L₂; the latter was detected after S-sulfonation in starch gel electrophoresis as the fastest moving component and its immunoelectrophoretic pattern shows the presence of two precipitating components. Preparation of soluble heavy and light chains enabled us to study them imunochemically. The heavy chain is represented by two zones; the fainter one was not detected in comparative analysis of the heavy chain of serum γG globulin. The L₁ chain of colostral gamma globulin and the light chain of serum gamma globulin seem to contain three precipitating components, one of which appears due to aging of the chain solution in the presence of glycine. The material from colostrum seems to contain a larger amount of this component than serum. Further it was shown that the component arising in this way is antigenically closely related to the heavy chain.     

Sequence studies on the constant region of the Fd sections of rabbit immunoglobulin G of different allotype.

The amino acid sequence has been completed for the constant region of the Fd fragments of heavy chains from rabbit IgG (immunoglobulin G) of allotype Aa1 and Aa3. The amino acid sequence given by Fruchter et al. [(1970) Biochem. J. 116, 249-259] for the constant region of the Fd fragment from Aa1 IgG was extended and in in part corrected to give a continuous sequence of 140 residues. No allotype-related sequence variation was found in the constant section of the Fd fragment. This evidence confirms the view that the differences in sequence between the variable regions of Aa1 and Aa3 IgG [Mole et al., (1971) Biochem. J. 124, 301-318] are responsible for the allotypic specificities.     

Spontaneous missense mutation of an immunoglobulin in a mouse myeloma cell line.

The characterisation of the alteration in amino acid sequence of the immuno globulin heavy chain of IF4, a charge mutant of the myeloma line MOPC 21, is described. This was achieved by comparing the sequence of mutant IF4 heavy chain with the known sequence of the wild type. The peptic fragment (Fab′)₂ from whole immunoglobulin, and all the ten CNBr fragments of MOPC 21 wild-type and mutant IF4 heavy chains, were identified and characterised. The only difference was in a tryptic peptide of the C-terminal CNBr fragment which had the same amino acid composition, but different electrophoretic mobilities. Thermolysin digestion products showed that asparagine 415 of wild-type heavy chain had been replaced by an aspartate in the mutant. Analysis of newly synthesized immunoglobulins from wild type and mutant showed the same charge difference, which did not seem therefore to result from deamidation.Fingerprints of the [³²P]mRNA of IF4 heavy chain were prepared. The T₁ ribonuclease oligonucleotide that includes the coding sequence for residue 415 in wild type was not found in mutant IF4.The mechanism is most likely a missense point mutation (A to G transition) in the MOPC 21 heavy chain structural cistron.     

Interchain disulphide-bond formation in the assembly of immunoglobulin G. Heavy-chain dimer as an intermediate

1. The role of disulphide-bond formation in the assembly of G_2a myeloma protein 5563 was studied by pulse-labelling ascitic plasma cells of tumour-line 5563 for 2–8min. with radioactive amino acids, and analysing the intracellular proteins. Myeloma-protein determinants were first purified by ion-exchange chromatography under conditions that do not dissociate non-covalently linked sub-units of immunoglobulin G. The pulse-labelled material was then analysed by electrophoresis on polyacrylamide gels in sodium dodecyl sulphate–phosphate–urea buffer, which dissociates non-covalently linked sub-units; after gel electrophoresis, radioactive protein bands were located by radioautography, and characterized immunologically after elution. 2. Two heavy-chain intermediates were detected: (i) heavy-chain dimer; (ii) the dimer with one light chain attached. Free light chains had previously been shown to be intermediates in assembly. No evidence for the presence of half-molecules (one light chain attached to one heavy chain) was obtained. The formation of the disulphide bond between the heavy chains thus appears to precede the light-chain–heavy-chain linkage in immunoglobulin G assembly.     

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.     

Human placental sialidase complex: characterization of the 60 kDa protein that cross-reacts with anti-saposin antibodies

Sialidase isolated from human placenta is associated with several proteins including acid beta-galactosidase, carboxypeptidase, N-acetyl-alpha-galactosaminidase, and others. These proteins are thought to form an aggregated complex during isolation of sialidase. One of the proteins of 60 kDa was recently identified by Potier et al. (Biochem. Biophys. Res. Comm. 173, 449-456, 1990) as a sialidase protein: this protein also cross-reacted with anti-prosaposin antibodies. We have isolated this protein and from the following evidence identified it as a heavy chain component of immunoglobulin G and not sialidase or a derivative of prosaposin. On gel filtration HPLC, sialidase activity and the 60 kDa protein were clearly separated from one another. The 60 kDa protein cross-reacted not only with antibodies raised against human saposins A, C, and D, but also with second antibody (goat anti-rabbit immunoglobulin G antibody) alone. This 60 kDa protein strongly cross-reacted with anti-human immunoglobulin G antibodies. The sequence of the initial 15 amino acids from the N-terminus of the 60 kDa protein was identical to the sequence of an immunoglobulin G heavy chain protein Tie (gamma 1).