VH and VL gene usage by murine IgG antibodies that bind autologous insulin

To assess the recognition structures of antibodies that bind a self-Ag, we used mRNA analysis to identify the V region genes of IgG antibodies that bind autologous insulin. Four anti-insulin mAb from primary immunization of BALB/c mice use different combinations of H and L chain V region genes. Two VH genes are from the V-gam 3-2 and V-gam 3-8 families that are infrequently expressed in adult BALB/c mice, and two VH genes are members of the J558 family. Each anti-insulin antibody uses a different Vk gene family. Two antibodies express common Vk genes (Ox1 and Vk21C), whereas two other Vk genes are unusual in BALB/c mice. One Vk gene may represent a BALB/c equivalent of the VkOx2 subfamily and another is identical to a Vk used by anti-idiotypic antibodies from C57Bl/6 mice. When compared with known germ-line counterparts, all of the Vk sequences are close to germ-line configuration. In contrast, the germ-line counterparts for the anti-insulin VH genes are not known, however, they differ only in five to seven predicted amino acids from VH of other expressed antibodies. One antibody (mAb 123) differs in one amino acid in complementarity-determining regions 1 and 2 from the VH of the murine tumor BCL1, and another (mAb 126) employs an unmutated DFL16.1 germ-line D segment. These data suggest that antibodies binding autologous insulin use V gene components that are not extensively mutated, even when derived by immunization with heterologous insulin.     

Cloning and sequence analysis of the VH and VL regions of an anti-myelin/DNA antibody from a patient with peripheral neuropathy and chronic lymphocytic leukemia

We have cloned and determined the nucleotide sequence of the Ig VH and VL region genes of an IgM kappa mAb that binds to denatured DNA and myelin from a patient (POP) with chronic lymphocytic leukemia and peripheral neuropathy. Sequence analysis indicates that the V region of the kappa L chain gene (PopVK) has 99% homology to a V kappa IIIa germ-line gene and the V region of the mu H chain gene (PopVH) has 96% homology to the VH26 germ-line gene that is a member of the VH3 gene family. It is likely the V kappa and VH genes arose from these respective germ-line genes via somatic mutation or from closely related genes. V kappa III genes have frequently been used by other IgMk mAb especially those with rheumatoid factor activity, and the VH26 gene with no somatic mutation has been used by several anti-DNA antibodies, suggesting the possibility of preferential association of these or related germ-line genes with autoantibodies. The minor differences between the sequences of POP's VH and V kappa genes and sequences used by other autoantibodies, may be responsible for this antibody's crossreactivity with myelin and, as a result, the autoimmune neuropathy.     

A molecular and structural analysis of the VH and VK regions of monoclonal antibodies bearing the A48 regulatory idiotype

The results presented in this paper explore the molecular basis for expression of the A48 regulatory Id (RI). A48 RI+ mAb derived from idiotypically manipulated mice molecularly resembled the A48 and UPC 10 prototypes of this system by utilizing a VHX24-Vk10 combination. Id expression by these antibodies was not restricted by a particular D region sequence, JH, or JK segment, but quantitative differences in Id expression were associated with utilization of different members of the VK10 germ-line gene families. The VL sequences of these A48 RI+ mAb has identified amino acid residues lying in four different idiotope-determining regions which may contribute to the structural correlate of this Id. A comparative sequence analysis of the VH regions of these VHX24 utilizing A48 RI+ mAb with several A48 RI+ mAb utilizing VHJ558 or VH7183 VH genes as well as a hybrid transfectoma antibody derived from two A48 RI-, VHJ558 utilizing hybridomas, all suggested that four nonconsecutive positions which lie outside the idiotope-determining regions may contribute structural elements toward expression of this Id. The VH and VL regions of the A48RI+, VHX24-Vk 10+ mAb showed low to moderate levels of somatic mutation which showed different patterns of distribution between the complementary determining region (CDR) and framework regions in the H and L chains. Although the VK sequences contained 50% of the replacement mutations in the CDR, with a replacement/silent mutation ratio of 10, the CDR of the VH sequences contained only 31% of the replacement mutations with a replacement/silent mutation ratio of 0.69.     

Sequences of the VH and VL regions of murine monoclonal antibodies against 3-fucosyllactosamine

Many mAb that bind the carbohydrate antigenic determinant 3-fucosyl-lactosamine (3-FL), Gal beta 1-4[Fuc alpha-3]GlcNAc-R have been raised in BALB/c mice, and we are studying the structure and regulation of these antibodies. In this report, we present the first information about their amino acid sequences and the Ig gene segments used to encode them. V regions of the H and L chains of three anti-3-FL antibodies, PMN6, PMN29, and PM81, were sequenced by a combination of mRNA and amino acid sequencing. The L chain sequences of PMN6 and PM81 antibodies indicate that their VK and JK regions are encoded by VK24B and JK1 germ-line genes, respectively. The nucleotide and amino acid sequences of the H chains suggest that the three anti-3-FL antibodies are encoded by the VH441 gene segment of the X24 VH family, and this conclusion was supported by Southern filter hybridization with VH441 and JH3-JH4 probes. PMN29 has at least 11 amino acid substitutions, which is an unusually large amount of somatic mutation for an IgM antibody. Previous analyses of BALB/c genomic libraries with VHX24 and VH441 probes make it unlikely that this VH family contains additional germ-line genes, but this possibility cannot be excluded. All three antibodies use the DQ52 and JH4 gene segments. The single VH and VL gene segments used to encode the anti-3-FL antibodies is in contrast to the multiple VH and VL segments used by antibodies against other carbohydrate Ag such as alpha 1-6 dextran and group A streptococcal carbohydrate. VH441 also encodes the VH regions of antibodies against galactan and levan (beta 2-6 fructosan). The similarities among VH segments of antibodies against 3-FL, levan, and galactan, and the striking differences in their CDR3 sequences, suggest that CDR3 plays an important role in the formation of the Ag binding site. The use of a single VH segment from the smallest VH gene family by antibodies against at least three different carbohydrate determinants is noteworthy. It raises the possibility that the amino acid sequence encoded by VH441 has some general structural features that make it particularly well adapted for binding to carbohydrate sequences.     

Analysis of antibody diversity: V-D-J mRNA nucleotide sequence of four anti-GAT monoclonal antibodies. A paucigene system using alternate D-J recombinations to generate functionally similar hypervariable regions

The nucleotide sequence of four anti-(Glu60-Ala30-Tyr10)n (GAT) monoclonal gamma 1 heavy chain mRNAs was determined from codon 10 to 120. This sequence overlaps with the NH2-terminal amino acid sequence, allowing elucidation of the complete protein sequence encompassing regions VH, D and JH. These sequences, which are highly conserved, indicate that anti-GAT antibodies expressing the same public idiotypic specificities represent a paucigene system, which uses at least two D-J combinations leading to functionally similar hypervariable regions involved in the recognition of the dominant Glu-Tyr determinant. D regions are encoded by D genes which are closely related either to the D-SP2 or the D.FL16 germ line gene cores.     

Nucleotide sequences and three-dimensional modelling of the VH and VL domains of two human monoclonal antibodies specific for the D antigen of the human Rh-blood-group system.

The nucleotide sequences were determined for the VH and VL domains of two human IgG1 antibodies, Pag-1 and Fog-B, specific for the D antigen of the Rh-blood-group system. The VH-region genes of the two antibodies were derived from separate germ-line genes within the VH-IV gene family, but both antibodies used the same JH6 gene. The D-region genes differed from each other, and no similarity was found to known D regions. The light chain of Fog-B belongs to the V lambda-I subgroup and that of Pag-1 probably belongs to the V lambda-V subgroup; both light chains used the J2/3 gene. Three-dimensional models of the variable domains were made, based on those of known crystallographic structure. The surface contours at the combining sites are clearly different, consistent with the evidence that the antibodies recognize different but overlapping epitopes. Some details of the molecular modelling of hypervariable regions have been deposited as Supplementary Publication SUP 50155 (6 pages) at the British Library Document Supply Centre, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1990) 265, 5.     

The amino acid residues at the VH-D-JH junctions affect the affinity of anti-p-azophenylarsonate antibodies

Murine A/J anti-p-azophenylarsonate (Ars) antibodies sharing a predominant idiotype are encoded by a single combination of germ-line V region gene segments. The dominance of this idiotype among secondary immune response anti-Ars antibodies has been explained by the Ag-driven selection of favorable somatic mutants of this gene segment combination, associated with an intrinsic Ars-affinity of the germ-line V region higher than that of other possible combinations. To determine the effect of junctional diversity upon affinity for Ag, independently of somatic mutation, we determined the V region sequences and affinity for Ars of five primary response antibodies. These antibodies share identical unmutated V regions but differ only at the D gene junctions. Among the five antibodies, Ars-affinity differed up to 10-fold depending upon the identity of the amino acid residues at the VH-D and the D-JH junctions. The combination of junctional residues observed in two primary response antibodies with relatively low Ars-affinity has not been observed among secondary response antibodies. Thus the identity of junctional residues resulting from gene rearrangement prior to antigen stimulation must be taken into account in hypotheses which account for idiotype dominance by selection on the basis of affinity.     

Recurrent somatic mutations in mouse antibodies to p-azophenylarsonate increase affinity for hapten

Two mouse mAb specific for the hapten p-azophenylarsonate and encoded by the same combination of germ-line V, D, and J genes differ 200-fold in affinity for hapten. We determined the amino acid sequences of the V regions of the high affinity antibody and compared them to the published sequences of the low affinity antibody which is not somatically mutated. Of 19 amino acid substitutions, two, Ile57 and Thr58 in the H chain, also occur, either alone or together, in other somatically mutated antibodies specific for p-azophenylarsonate; these antibodies have been independently isolated. Introduction of either one of these mutations alone into the low affinity antibody by oligonucleotide-directed mutagenesis increased the antibody affinity for hapten three- to fourfold, whereas introduction of both mutations together conferred an eightfold increase in affinity. These results support the hypothesis that somatic mutations are selected on the basis of the affinity for antigen that they confer, and suggest that even relatively small increases in affinity may be selected, probably in a sequential manner.     

Relationship of human variable region heavy chain germ-line genes to genes encoding anti-DNA autoantibodies

In order to identify the V region genes encoding systemic lupus erythematosus (SLE)-derived anti-DNA autoantibodies, we have determined the nucleotide sequence of heavy chain mRNA from several DNA-binding immunoglobulins secreted by human hybridomas. We used the technique of cDNA primer extension for determining sequences of the VH, D, and JH gene segments of anti-DNA autoantibodies from three different primary hybridoma growths from an SLE patient and one hybridoma from a leprosy patient. Immunoglobulins from two of the SLE hybridomas expressed the same idiotype, Id-16/6, which is also expressed on immunoglobulins in sera of patients with active SLE. Their mRNA sequences showed complete homology to each other in the V, D, and J genes and more than 99% homology to the VH26 germ-line gene sequence, a member of the human VHIII gene family. The VH mRNA sequence of the third SLE hybridoma, 21/28, which was idiotypically unrelated to the other two, was 93% homologous to a different VH germ-line gene sequence, HA2, a member of the human VHI gene family. The fourth anti-DNA-producing hybridoma, 8E10, was derived from a leprosy patient of different ethnic origin than the SLE patient. It was idiotypically related to 21/28 and expressed a VH segment gene identical to that of 21/28. Hybridomas 21/28 and 8E10 shared sequence homology with the VH26 anti-DNA antibodies in the first complementarity-determining region. In addition, 21/28 shared sequence homology with the Id-16/6+ group in the region encoded by the D and J gene segments. Our findings indicate that some SLE autoantibodies are encoded by unmodified or scarcely modified VH germ-line genes that are conserved in the human population and identify two distinct VH germ-line genes that can encode segments of anti-DNA immunoglobulins.     

Germ-line affinity and germ-line variable-region genes in the B cell response

The predominance of germ-line genes in IgM expression was evaluated from the nucleotide sequences of mRNA, derived from 10 hybridoma cell lines, coding for the VH and VL regions of anti-5-dimethylaminonaphthalene-1-sulfonyl (anti-Dns) IgM antibody. At least six germ-line VH gene segments distributed among four families are used in this response. Seven of the 10 independently rear-ranged VH genes were identified as germ line, with the other three possibly germ line. In all of them the D and JH portions retained the germ-line sequences of the D and JH segments from which they were derived. Maximum diversity was found in the D segments and the use of noncoded nucleotides at the VH-D and D-JH junctions. Of the eight cell lines expressing the lambda light chains, all were germ line and involved the three subtypes. Maximum affinity for the homologous ligand was found among the seven cell lines identified as expressing germ-line gene segments. Thus any somatic mutation among the remaining 3 cell lines did not provide enhanced affinity and the observed affinity of each cell line can be described as germ-line affinity. It is further suggested that the anti-Dns selectivity of the IgM antibodies is associated primarily with the CDR3 regions.     

Comparative sequence and immunochemical analyses of murine monoclonal anti-morphine antibodies

A more complete characterization is given for four previously reported anti-morphine monoclonal antibodies that bind the hapten with high affinity and to which anti-idiotypic antibodies have been raised that mimic opiates at receptor binding sites. The variable (V) region nucleotide sequences of the heavy (H) and light (L) chains of these murine antibodies have been determined by direct sequencing of the poly(A)+ mRNAs using specific oligonucleotide primers and dideoxynucleotide chain-termination, and the deduced amino acid sequences are compared. The primary sequences predicted for the VH segments of 10C3 and 11C7 antibodies are closely associated with the VHIIIB subgroup of mouse H-chain (80 to 82% homology), while those for the V-regions of 3B9 and 12D4 H-chains correlate well with the VHIIC subgroup (64 to 67% homology). The 11C7, 10C3, 3B9 and 12D4 hybridoma cell lines use JH1, JH2, JH3 and JH4 DNA segments, respectively. Since considerable variations in length and primary sequence in the CDR3 (complementarity determining region) peptides of all the H-chains are evident, conservation of the D-region structure does not appear to be necessary for effective hapten binding. However, sequence homologies of the CDR2 regions of all the antibodies indicate that residues Glu H-50, Ile H-51, Pro H-52a and Tyr H-59 are conserved, and that these segments may be more critically involved in binding than the other H and L-chain hypervariable regions. The marked VL sequence homology, greater than 93%, among the L-chains and consensus lambda sequence, suggests derivation from a similar or identical VL germ-line gene. The L-chain J-region peptides for all the antibodies are classified JL1 and no VL-JL junctional diversity was apparent. The antimorphine antibody L-chains are apparently generated by the joining of a specific J-gene segment to a single germ-line V-gene segment, and minor sequence variations are the result of somatic mutations within the coding region. The leader sequence for one of the H-chains was determined. The inhibition of morphine binding by phenoxybenzylation or iodination of the affinity-purified immunoglobulins indicates the involvement of a single tyrosyl residue within or close to the antibody-combining site for the opiate. This conclusion is supported by the sequence data and nuclear magnetic resonance measurements reported in the accompanying paper, in which the results are used to interpret nuclear magnetic resonance measurements on one of the ligand-antibody systems. The possible importance of additional contact amino acids, tryptophan, aspartic and/or glutamic acids, is discussed.     

Clonal characterization of the human IgG antibody repertoire to Haemophilus influenzae type b polysaccharide. III. A single VKII gene and one of several JK genes are joined by an invariant arginine to form the most common L chain V region

To characterize the L chain V region repertoire of IgG anti-Haemophilus influenzae type b capsular polysaccharide (Hib-PS) antibodies, clonal antibodies were purified from immune serum and internal amino acid sequences of VKII anti-Hib-PS L chains obtained. We examined VKII L chains because it is the most common VL family expressed in the anti-Hib-PS response. Comparison of VKII amino acid sequences, including the entire CDR2 and CDR3 regions, of five anti-Hib-PS clonal antibodies from four unrelated individuals revealed complete identity with the exception of a single CDR3 residue from one antibody. When the sequence of these antibodies was compared with known VKII genes and myeloma proteins, it was found to be identical to the human VKII gene, A2, whose genomic sequence is presented here. In addition, all five of the VKII anti-Hib-PS antibodies examined contain an arginine inserted at the V-J junction. Finally, in contrast to the extraordinary homology of the VKII-encoded residues, there is variability in the JK gene utilization by these antibodies. These results demonstrate that the most common L chain V region in IgG anti-Hib-PS antibodies is the product of a single germ-line gene. The invariant arginine insertion suggests that this residue has an important role in Ag binding.     

Variable region cDNA sequences and antigen binding specificity of mouse monoclonal antibodies to isomaltosyl oligosaccharides coupled to proteins. T-dependent analogues of alpha(1----6)dextran

Four mouse hybridomas specific for alpha(1----6)dextran, 16.4.12E (IgA kappa, C57BL/6), 28.4.10A (IgM kappa, BALB/c), 35.8.2H (IgG1 kappa, BALB/c), and 36.1.2D (IgM kappa, BALB/c) were obtained by immunization with the T-dependent Ag isomaltohexaose or isomaltotriose coupled to keyhole limpet hemocyanin or to BSA. Immunochemical characterization of the hybridoma antibodies showed that 16.4.12E and 36.1.2D had cavity-type combining sites, recognizing the terminal non-reducing end of alpha(1----6)dextran, whereas 28.4.10A and 35.8.2H had groove-type sites, recognizing internal linear segments of the dextran. The V region cDNA of the H and L chains of the antibodies were cloned and sequenced. VH of 16.4.12E and VH of 36.1.2D belonged to the X24 and Q52 germ-line gene families, respectively. The VH and V kappa sequences of 16.4.12E and V kappa sequence of 36.1.2D were highly homologous to those of W3129, the only anti-alpha(1----6)dextran mAb with a cavity-type site thus far sequenced; 16.4.12E differed from W3129 in the D, JH, and J kappa. VH genes of 28.4.10A and 35.8.2H were homologous to those of several anti-alpha(1----6)dextrans with groove-type sites, but belonged to the J558 germ-line gene family, differed from the other J558 anti-alpha(1----6)dextrans, probably representing a different germ-line subfamily. The L chain sequence of 28.4.10A encoded by V kappa-Ars and J kappa 2 was almost identical to other groove-type anti-alpha(1----6)dextrans obtained by immunizing with the T-independent glycolipid Ag, stearyl-isomaltotetraose. Use of T-dependent Ag such as isomaltosyl oligosaccharide-protein conjugates provides an additional parameter for probing the fine structure of antibody combining sites and evaluating the V-gene repertoire of anti-alpha(1----6)dextrans.     

Characteristics of two idiotypic subfamilies of murine anti-p-azobenzenearsonate antibodies

A family of antibodies bearing a common or cross-reactive idiotype, termed CRIC, predominates in the response of most BALB/c mice to the p-azobenzenearsonate (Ar) hapten, but represents a minor component of the anti-Ar response of most A/J mice. Previous results have suggested that the VH region of CRIC is encoded by two different germ-line genes in both strains. We have determined extensive mRNA sequences for VH and VL, developed specific idiotypic reagents and measured affinities for two subfamilies of CRIC, designated CRIC1 and CRIC2. Both were found to be minor components of A/J anti-Ar antibodies, and CRIC1, but not CRIC2, is a major component of the BALB/c response. The two subfamilies utilize different VH germ-line genes but the same, or nearly identical V kappa genes. The VH nucleotide sequences of CRIC1 and CRIC2 exhibit approximately 90% homology. The D regions of both families are short (one or two amino acid residues) and some can be accounted for on the basis of known JH sequences alone. Affinity differences may account for the dominance of CRIA over CRIC1 and CRIC2 in A/J mice, but results obtained with allotype-congenic mice indicate that background (non-V region) genes are also important in controlling levels of expression of the CRIC1 idiotype. Our data suggest that the A/J germline VH gene that gives rise to the CRIC2 family of antibodies may be identical with a previously sequenced BALB/c germ-line VH gene. On the basis of these and earlier data it is suggested that extensive differences between inbred strains of mice in their complements of VH genes do not result from the accumulation of many mutations in these genes. An alternative possibility is that the differences arise from deletions and/or duplications of VH genes.     

Nucleotide sequence of a cDNA clone encoding a rabbit immunoglobulin-lambda light chain: the V lambda region differs markedly from that of other species

A cDNA clone (pDH7) has been isolated which encodes the entire leader peptide and variable (V) region and most of the constant (C) region of a rabbit lambda-light chain. Although similar to amino acid sequences derived from fragments of isolated lambda-chains from several Basilea rabbits, differences in the first framework region (FR1) suggest that at least two germ-line V lambda genes are expressed. There are major differences between rabbit V lambda sequences and light chains of other species: in particular, rabbit lambda-chains have an additional four amino acids in the vicinity of the FR2-CDR2 junction. The same region also has significant homology with the human D2 germ-line mini-gene sequence, especially with a 14-nucleotide sequence previously shown to be homologous to human and rabbit heavy chain CDR2 sequences. Similar homologies in other heavy and light chain sequences suggest that D-gene segments may be derived from VH genes, perhaps by transposition. The framework regions of the rabbit lambda-chain encoded by clone pDH7 show the greatest homologies with those of human kappa- and lambda-sequences (46 to 54% homology), with that of chicken sequence (55%), and least with murine V lambda sequences (40%).     

Two V kappa germ-line genes related to the GAT idiotypic network (Ab1 and Ab3/Ab1') account for the major subfamilies of the mouse V kappa-1 variability subgroup

V kappa Ig germ-line genes have been isolated from recombinant clones prepared in separate libraries constructed from adult BALB/c liver DNA. Three different clones that strongly hybridized with a V kappa-GAT-specific probe were completely characterized and sequenced. All three genes exhibited common characteristic features in their sequences encompassing the 5' to the 3' noncoding region, with coding sections 95% homologous. A comparison with other V kappa genes shows that the size of the first intron is variability subgroup specific. Moreover, a direct correlation exists between the size of this intron and the entire length of the coding region. Nucleotide sequences of these genes were compared with V kappa chains expressed at the Ab1 and Ab1' levels of the GAT idiotypic network: Ag----Ab1----Ab2----Ab3 (Ab1'). K1A5 and K5.1 genes account for V kappa chains in Ab1 and Ab1' hybridomas, respectively. The high conservation of Ab1' sequences in light chain was also recently reported for the heavy chains, suggesting that immunization with Ab2 (anti-idiotypic) antibodies preferentially stimulates the direct expression of germ-line genes. K5.1 and K1A5 genes belong to the V kappa-1 variability subgroup and encode, without any amino acid substitution, V kappa domain in myeloma TEPC 105 and MOPC 467, which are V kappa-1A and V kappa-1C subgroup prototypes, respectively. These genes are extensively used in different mouse strains and in a number of antibodies of discrete specificities, such as anti-GAT, anti-DNP, anti-flagellin, anti-phosphorylcholine, anti-digoxin, anti-phenyloxazolone, and anti-DNA.     

Study of idiotopic suppression induced by anti-cross-reactive idiotype monoclonal antibody in the anti-p-azophenylarsonate antibody response

A/J mice immunized with p-azophenylarsonate coupled to keyhole limpet hemocyanin produce antibodies expressing a cross-reactive idiotype (CRIA). The pretreatment of A/J mice with anti-idiotypic polyclonal or monoclonal antibody directed against the major cross-reactive idiotype (CRIA) borne by p-azophenylarsonate-specific antibody can lead to idiotypic suppression. In this study, we investigate this idiotypic suppression by using four mAb2 (E4, H8, E3, 2D3) recognizing distinct idiotopes whose expression is related to the presence of particular gene segments of the heavy chain V region. 2D3 expression has been related to the presence of some amino acid in the CDR2 region of the VH gene segment derived from the germ line VH IdCR11. So far, the latter is the only germ-line gene coding for CRIA+ antibody that has been identified in the A/J genome. E4 and H8 expression has been related to the use of a particular D segment, whereas E3 expression has been attributed to certain combinations of D and JH segments. Therefore, we might expect independent regulation of the expression of those various idiotopes in relation to the mechanism of gene recombination. Indeed, we observed that 2D3-suppressed A/J mice still produce the three other idiotopes, suggesting the recombination of those particular D and J segments with a different VH gene. Such a gene has been identified in the genome of BALB/c mice. A/J mice pretreated with one of the other three mAb2 are generally cosuppressed for the expression of E4, H8, and E3, but they still produce 2D3+ antibody. In this case, the IdCR11 VH germ-line gene is most probably recombined with different D and J segments. Molecular evidence for the existence of such molecules has also been presented in the literature. So our serologic data on idiotopic suppression in the arsonate system can be compared with recent data provided by molecular genetics.     

A Schwann cell matrix component of neuromuscular junctions and peripheral nerves

Molecules localized to the synapse are potential contributors to processes unique to this specialized region, such as synapse formation and maintenance and synaptic transmission. We used an immunohistochemical strategy to uncover such molecules by generating antibodies that selectively stain synaptic regions and then using the antibodies to analyse their antigens. In this study, we utilized a monoclonal antibody, mAb 6D7, to identify and characterize an antigen concentrated at frog neuromuscular junctions and in peripheral nerves. In adult muscle, immunoelectron microscopy indicates that the antigen is located in the extracellular matrix around perisynaptic Schwann cells at the neuromuscular junction and in association with myelinated and nonmyelinated axons in peripheral nerves. The maintenance of the mAb 6D7 epitope is innervation-dependent but is muscle-independent; it disappears from the synaptic region within 2 weeks after denervation, but persists after muscle damage when the nerve is left intact. mAb 6D7 immunolabelling is also detected at the neuromuscular junction in developing tadpoles. Biochemical analyses of nerve extracts indicate that mAb 6D7 recognizes a glycoprotein of 127 kDa with both N- and O-linked carbohydrate moieties. Taken together, the results suggest that the antigen recognized by mAb 6D7 may be a novel component of the synaptic extracellular matrix overlying the terminal Schwann cell. The innervation-sensitivity of the epitope at the neuromuscular junction suggests a function in the interactions between nerves and Schwann cells.