An immunoglobulin heavy chain variable region gene is generated from three segments of DNA: VH, D and JH

We have determined the sequences of separate germline genetic elements which encode two parts of a mouse immunglobulin heavy chain variable region. These elements, termed gene segments, are heavy chain counterparts of the variable (V) and joining (J) gene segments of immunoglobulin light chains. The VH gene segment encodes amino acids 1-101 and the JH gene segment encodes amino acids 107-123 of the S107 phosphorylcholine-binding VH region. This JH gene segment and two other JH gene segments are located 5' to the mu constant region gene (Cmu) in germline DNA. We have also determined the sequence of a rearranged VH gene encoding a complete VH region, M603, which is closely related to S107. In addition, we have partially determined the VH coding sequences of the S107 and M167 heavy chain mRNAs. By comparing these sequences to the germline gene segments, we conclude that the germline VH and JH gene segments do not contain at least 13 nucleotides which are present in the rearranged VH genes. In S107, these nucleotides encode amino acids 102-106, which form part of the third hypervariable region and consequently influence the antigen-binding specificity of the immunoglobulin molecule. This portion of the variable region may be encoded by a separate germline gene segment which can be joined to the VH and JH gene segments. We term this postulated genetic element the D gene segment, referring to its role in the generation of heavy chain diversity. Essentially the same noncoding sequences are found 3' to the VH gene segment and as inverse complements 5' to two JH gene segments. These are the same conserved nucleotides previously found adjacent to light chain V and J gene segments. Each conserved sequence consists of blocks of seven and ten conserved nucleotides which are separated by a spacer of either 11 or 22 nonconserved nucleotides. The highly conserved spacing, corresponding to one or two turns of the DNA helix, maintains precise spatial orientations between blocks of conserved nucleotides. Gene segments which can join to one another (VK and JK, for example) always have spacers of different lengths. Based on these observations, we propose a model for variable region gene rearrangement mediated by proteins which recognize the same conserved sequences adjacent to both light and heavy chain immunoglobulin gene segments.     

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.     

Allelic forms of the immunoglobulin heavy chain variable region

The complete variable region sequence of the heavy chain from a phosphorylcholine-binding myeloma protein of C57/BL allotype has been determined. When this sequence was compared with the germ line-coded heavy chain variable region sequence of BALB/c phosphorylcholine-binding proteins, five differences were observed. Four of the substitutions were located in the framework portion of the variable region and the fifth in the "J" or joining segment. Two of the framework substitutions were found at positions 14 and 16. Previous studies have shown that heavy chains from all anti-phosphorylcholine antibodies induced in C57/BL mice have the same amino acids at positions 14 and 16 as the C57/BL myeloma protein described in this communication. It has therefore been concluded that these residues are encoded in the C57/BL germ line in contrast to two alternatives in the BALB/c genome. This finding, in addition to the 96% homology found between the C57/BL and BALB/c sequences, suggests that these structures represent allelic forms of an entire variable region.     

Primary structure of the variable regions of two canine immunoglobulin heavy chains.

The complete amino acid sequences of the variable regions of two canine immunoglobulin heavy chains have been determined by automated Edman degradation and found to be strongly homologous to the human VHIII subgroup. The canine sequences were identical with each other at 76 of 113 residue positions. Twenty-three of the 37 differences are located within the four hypervariable regions previously defined by the sequences of several human VHIII proteins. Forty-five of 77 framework residue positions are invariant in the seven human and two canine VHIII proteins which have been completely sequences. The canine proteins are 78% homologous to the framework of the human prototype. Phylogenetically associated residues before the first hypervariable region were confirmed and several potential phylogenetically associated residues were identified between the first and third hypervariable regions. This study represents the first complete amino acid sequences of VH regions of spontaneously occurring, nonhuman homogeneous immunoglobulins. The date demonstrate a high degree of preservation of VHIII structure in another species.     

The immunoglobulin heavy chain class switch

Conclusions While much has been learned concerning the molecular structural basis for the heavy chain class switch, many questions relating to the regulation of the switch remain unanswered, or at least controversial. Identification of the enzyme system which mediates the class switch, as well as other regulatory, possibly X-linked, genes should provide the necessary key to our understanding of this unique process.AbbreviationsB cell lymphocyte derived from the bone marrow in adult mammals or the bursa of Fabricius in chickens - bp base pair - C immunoglobulin constant region - CDR complementarity-determining region of the immunoglobulin variable region - D diversity gene segment of the immunoglobulin heavy chain variable region gene - H immunoglobulin heavy chain - Ig immunoglobulin - J joining region gene segment of the immunoglobulin variable region gene - kb kilobase - L immunoglobulin light chain - LPS lipopolysaccharide - Pyr pyrimidine - S-, s-site, s-region switch rearrangement site - SCE sister chromatid exchange - sIg surface immunoglobulin - T cell lymphocyte derived from the thymus - USCE unequal sister chromatid exchange - V immunoglobulin variable region     

Complete heavy and light chain variable region sequence of anti-arsonate monoclonal antibodies from BALB/c and A/J mice sharing the 36-60 idiotype are highly homologous

Structural and serologic studies on murine A/J monoclonal anti-arsonate antibodies resulted in the identification of a second idiotype family (Id36-60) in addition to the predominant idiotype family (IdCR). Id36-60, unlike IdCR, is a dominant idiotype in the BALB/c strain but is a "minor" idiotype in the A/J strain. The complete heavy and light chain variable region (VH and VL) amino acid sequences of a representative Id36-60 hybridoma protein from both the A/J and BALB/c strains have been determined. There are only four amino acid sequence differences between the VH of antibody 36-60 (A/J) and antibody 1210.7 (BALB/c). Two of these differences arise from single nucleotide changes in which the A/J and BALB/c Id36-60 VH germline gene sequences differ. The two other differences are the result of somatic mutation in hybridoma protein 36-60. In addition, Id36-60 heavy chains employ the same D and JH3 segments in both strains. The entire Vk2 VL of 36-60 and 1210.7 differ by only two amino acids, suggesting that like the heavy chains, they are derived from highly homologous VL genes. The same Jk segment is used in both antibodies. A comparison of the amino acid sequence data from Id36-60-bearing hybridomas suggests that a heavy chain amino acid difference accounts for the diminished arsonate binding by the 1210.7 hybridoma protein. Because the 1210.7 heavy chain is the unmutated product of the BALB/c VH gene, somatic mutation in VH may be required to enhance Ars affinity in this system.     

Structural evidence for a polymorphic or allelic form of the heavy chain variable region.

The heavy (H) chains of anti-phosphocholine (PC) antibodies from C57BL/6J and CBA/J were sequenced through the N-terminal 36 residues and compared with previously published sequences of A/J anti-PC antibody and BALB/c PC-binding myeloma proteins T15, M603, and M511. Each of these antibody preparations contained molecules having light (L) chains and idiotypic determinants of T15, M511, and M603 indicating the presence of at least three different anti-PC antibodies in each pool. The structures of the C57BL/6J and CBA/J H chains each revealed a single sequence from positions 1 to 36 (which includes the first complementarity determining region (CDR), and they were identical. The first CDR was identical to that previously found for BALB/c and A/J indicating that this portion of these antibody molecules is highly conserved throughout inbred mice and is probably critical to PC-binding. A surprising finding was that both C57NL/6 and CBA sequence differed from the BALB/c and A/J sequences at two positions, residue 14 and 16. Since each of these strains differs at the allotype locus, the data indicates that the evolution of allotypy in mice occurred after variable region diversity for the particular genes.     

Primary structure of the variable region of a human lambda VI light chain: Bence Jones protein SUT

To ascertain if lambda VI light chains have unique structural features that account for the preferential association of these proteins with primary or multiple myeloma-related amyloidosis (amyloidosis AL) we have determined the complete amino acid sequence of the variable (V) region of the lambda VI Bence Jones protein SUT. This protein, obtained from a patient with amyloidosis AL, represents a complete light chain consisting of 216 residues and it has structural and serologic properties characteristic for lambda VI light chains. The sequence of the joining segment (J) (positions 100 to 111) of protein SUT is identical to that of the J lambda I segment of the mouse IG lambda light chain gene. V region SUT is closely homologous in sequence to that of another lambda VI amyloid fibrillar protein, AR, differing by 21 residues. The V regions of proteins SUT and AR contain a two-residue insertion at positions 68 and 69 that has also been found in two other lambda VI human light chains but not in the lambda-chains of other V region subgroups.     

Amino terminal sequence of heavy and light chains from ratfish immunoglobulin

The ratfish,Callorhinchus callorhinchus, a representative of the Holocephali, has a natural serum hemagglutinin (M _r 960 000), composed of heavy (M _r 71000), light (M _r 22 500), and J (M _r 16 000) chains. To approach the mechanisms that generate diversity at this level of evolution, the amino terminal sequence of the heavy and light chains was determined by automated microsequencing. The chains are unblocked and have modest internal sequence heterogeneity. The heavy chains show sequence similarity with the terminal region of the heavy chain from the horned shark,Heterodontus francisci, and other species. In contrast to the heavy chain, the ratfish light chains display low sequence similarity with their shark kappa counterparts. However, their similarity with the variable region of the chicken lambda light chains is about 75%.     

The V-region sequence of the H chain from a third rabbit anti-pneumococcal antibody.

The amino acid sequence of the V (variable) region of the heavy (H) chain of rabbit antibody BS-1, raised against type III pneumococcal vaccine, is reported. Together with the sequence data of the V region of the light (L) chain previously determined [Jaton (1974a) Biochem. J. 141, 1-13], the present work completes the analysis of the V domain of the homogeneous antibody BS-1. The V domains (VL + VH regions) of this antibody are compared with those of two other anti-(type III) pneumococcal antibodies BS-5 and K-25 [Jaton (1975) Biochem. J. 147, 235-247]. Except for the second hypervariable section of the L chains, these antibodies have very different sequences in the hypervariable segments of the V domains. Within the third hypervariable region of the H chain, each antibody has a different length: BS-1 is three amino acids shorter than K-25 and two amino acids shorter than BS-5. When the sequences in that section are aligned for maximal homology, only two residues, glycine-97 and leucine-101, are common to the three antibodies. On the basis of the amino acid sequences of these three anti-pneumococcal antibodies, the results do not support the concept of a simple correlation between primary structure in the hypervariable sections (known to determine the shape of the combining site) and antigen-binding specificity.     

The isolation and characterization of the V-H domain from rabbit heavy chains of different a locus allotype.

The Fd fragment of rabbit gamma-chains was split by papain to yield a smaller fragment with a molecular weight of approximately 14,000 and dialyzable small peptides and amino acids. The domain size fragment was identified as intact variable region from its amino acid content, its blocked amino-terminus, and two characteristic cysteine-containing peptides, while the small peptides and amino acids were accounted for by the degradation of the C-H1 region. The variable regions isolated from Aa1 and Aa3 Fd fragments not only reacted quantitatively with immunoadsorbents conjugated with the homologous anti-a allotype antibody, but also completely inhibited the binding of the parent Fd fragment to the homologous antibody as measured by radioimmune assay. These data provide direct evidence that the group a allotypic determinants are contained entirely in the variable portion and are independent of the constant portion of rabbit heavy chains.     

The structure of immunoglobulin variable regions in the horned shark,Heterodontus francisci

The heavy and light chains of pooled antibodies of the hybodont shark,Heterodontus francisci (horned shark), were subjected to amino acid sequence analysis. Yield determinations showed that more than 90% of the available polypeptides in the respective pools were sequenced. The heavy chains were homogeneous in the initial framework segment and showed a sequence homology of approximately 70% with the corresponding region of the more recently evolved nurse shark and a 45% homology with a human myeloma heavy chain. The light chains were less homogeneous and not identifiable as either kappa or lambda chains as known in higher species. The first half-cystine characteristics of the variable domain intrachain disulfide bridge of immunoglobulins was present in the same position (22 for heavy chains; 23 for light chains) in the horned shark as in mammalian species. The sequence analysis also suggested the presence of a hypervariable region in the horned shark light chains. The combined data imply that the antigen-binding function of immunoglobulins is mediated in much the same manner in this primitive shark as in more recently evolved species, including mammals.     

Analysis of the diversity of murine antibodies to dextran B1355: N-terminal amino acid sequences of heavy chains from serum antibody.

The N-terminal amino acid sequences of two gamma and two mu chains from normally induced serum antibodies to dextran in BALB/c mice are presented. These heavy chains are derived from antibodies with three distinguishable idiotypes. These variable region (VH) sequences are all identical as far as they have been analyzed (27 to 53 residues). The light chains from these antibodies are all of the lambda type and are identical by isoelectric focusing analysis. Accordingly, the diversity of dextran antibodies appears to reside primarily in the heavy chains. The implications of these observations for antibody diversity are discussed.     

Identification and sequence of the VH gene elements encoding a human anti-DNA antibody

Antibodies to DNA similar to those found in patients with systemic lupus erythematosus (SLE) and autoimmune mice can be derived from the lymphocytes of normal individuals. It is not known whether these normal derived anti-DNA antibodies are made from the same VH gene elements as the anti-DNA antibodies made by SLE patients. To begin to answer this question, we examined mu chain cDNA clones from human hybrid clone C6B2 producing anti-DNA antibodies. The sequence of the 500 base pair restriction fragment containing the variable region (5' terminus) was determined and was sequenced. This antibody uses a VHII heavy chain subgroup gene, a J3 joining segment, a hitherto unknown D segment, and a previously reported leader sequence. Significant homology was found to a mouse anti-DNA antibody sequence in the use of VH subgroup in J3, and in the hypervariable regions with a shared Ser-Tyr construction in CDR1 and an identical five amino acid residue stretch in CDR2. Comparison with the limited sequence data of published SLE monoclonal anti-DNA antibodies, both human and mouse, suggests that this shared Ser-Tyr may be important in some but not all antibodies to DNA. Comparison of C6B2 antibody is made with other known antibody sequences with identification of those residues likely to be part of the antigen binding site.     

Length of the antibody heavy chain complementarity determining region 3 as a specificity-determining factor

The antigen binding site of an antibody is made up of residues residing in six hypervariable loops of the heavy and light chains. In most cases several or all of these loops are required for the establishment of the antigen-binding surface. Five of these loops display a limited diversity in length and sequence while the third complementarity determining region (CDR) of the heavy chain is highly different between antibodies not only with respect to sequence but also with respect to length. Its extensive diversity is a key component in the establishment of binding sites allowing for the recognition of essentially any antigen by humoral immunity. The relative importance of its sequence vs its length diversity in this context is however, not very well established. To investigate this matter further we have used an approach employing combinatorial antibody libraries and antigen-specific selection in the search for CDRH3 length and sequence diversity compatible with a given antigen specificity, the major antigenic determinant on the tumour-associated antigen mucin-1. In this way we have now defined heavy chain CDR3 length as a critical parameter in the creation of an antigen-specific binding site. We also propose that this may reflect a dependence of a particular structure of this hypervariable loop, the major carrier of diversity in the binding site, for establishment of a given specificity.     

Molecular mapping of idiotopes of anti-arsonate antibodies

As part of understanding molecular function in structural terms, we have been attempting to map the idiotypic topography of specific anti-arsonate (Ars) antibodies. A panel of anti-Ars hybridomas of which the complete primary sequences are known were used. These molecules show a varied reactivity profile with a panel of monoclonal anti-idiotypic antibodies. By judicious chain recombination experiments and chemical modifications that altered this reactivity profile, we were able to identify particular amino acid residues or discreet regions of anti-Ars antibodies as having crucial roles in the expression of idiotypic determinants. Idiotopes were mapped to the heavy chain second hypervariable region and D segment, and to the light chain first and third hypervariable regions.     

Structural studies on induced antibodies with defined idiotypic specificities. I. The heavy chains of anti-p-azophenylarsonate antibodies from A/J mice bearing a cross-reactive idiotype.

Amino acid sequence analysis has been performed on three groups of heavy (H) chains of A/J mice. H chains derived from unimmunized animals were compared to anti-p-azophenylarsonate (anti-Ar) antibodies which were further subdivided into those possessing and those depleted of a cross-reacting idiotype (CRI). It was found that anti-Ar antibodies bearing the CRI are homogeneous through the first hypervariable region of the H chain. The same sequence was obtained for pooled antibody isolated from the ascites fluid of 18 A/J mice or from a single mouse. The H chains appear to belong to a minor V-H subgroup. In the first 30 positions Anti-Ar antibodies depleted of the CRI had the same sequence as those containing the CRI (with small amounts of heterogeneity at some positions), but contained a mixture of sequences in the first hypervariable region of the H chain. These studies indicate that antibodies with similar specificity and with identical framework sequences, but which differ in their hypervariable regions, contain different idiotypic determinants, and support the concept that the idiotypic determinants reside primarily within hypervariable regions.     

Structural studies on induced antibodies with defined idiotypic specificities. V. The complete amino acid sequence of the light chain variable regions of anti-p-azophenylarsonate antibodies from A/J mice bearing a cross-reactive idiotype.

The complete amino acid sequence of the variable regions of light chains derived from anti-p-azophenylarsonate antibodies from A/J mice bearing a cross-reactive idiotype is reported. At least two and probably more than three distinct light chains are associated with this idiotypically characterized antibody. The antibodies have several differences in their "framework" structures but evidence is presented indicating that all three light chain hypervariable regions have a homogeneous sequence. The data are discussed in relation to the various theories of antibody diversity. In addition, the findings support the view that hypervariable regions, idiotypic determinants, and the antibody-combining site involve, to a large extent, the same molecular structures.     

Comparison of the amino acid sequences of the variable domains of two homogeneous rabbit antibodies to type III pneumococcal polysaccharide.

The amino acid sequences of the V (variable) regions of the H (heavy) and L (light) chains derived from rabbit antibody K-25, specific for type III pneumococci, were determined; this is the second homogeneous rabbit antibody besides antibody BS-5 whose complete sequence of the V domain has been established (Jaton, 1974d). The V regions of L chains BS-5 and K-25 (both of allotype b4) differ from each other by 19 amino acid residues; 11 of these 19 substitutions are located within the three hypervariable sections of the V region. On the basis of seven amino acid differences within the N-terminal 28 positions, it is suggested that L chain K-25 belongs to a different subgroup of rabbit K chains and L chain BS-5. H chain K-25 (allotype a2) differs from another H chain of the same allotype by one amino acid substitution within the N-terminal 70 positions in addition to interchanges occurring in the first two hypervariable sections. H chain K-25 was compared with H chain BS-5 (allotype a1) and with the known V-region rabbit sequences. Allotype-related differences between a1, a2 and a3 chains appear to occur within the N-terminal 16 positions and possibly in scattered positions throughout the V-region. In the hypervariable positions, variability between the two antibodies is remarkably more pronounced within the third hypervariable section of both H and L chains than within the first two.