Antibody-dependent cellular cytotoxicity directed against cells expressing human immunodeficiency virus type 1 envelope of primary or laboratory-adapted strains by human and chimpanzee monoclonal antibodies of different epitope specificities.

The characteristics of antibody-dependent cellular cytotoxicity (ADCC) directed by a panel of human and chimpanzee antienvelope (anti-Env) monoclonal antibodies (MAbs) of different epitope specificities were studied; this was accomplished by using target cells expressing human immunodeficiency virus type 1 (HIV-1) Envs of either primary or laboratory-adapted strains. Human MAbs of similar apparent affinities (1 x 10(9) to 2 x 10(9) liters/mol) against either a "cluster II"-overlapping epitope of gp41 or against the CD4 binding site, V3 loop, or C5 domain of gp120 directed substantial and comparable levels of specific lysis against targets infected with laboratory-adapted strains of HIV-1. As expected, those MAbs specific for relatively conserved regions of Env generally exhibited ADCC activity against a broader range of HIV-1 strains than those directed against variable epitopes. Significant ADCC activities of selected MAbs against primary isolate Env-expressing cells were demonstrated. In addition, a new ADCC epitope in the V2 domain of gp120 was defined. CD56+ cells were demonstrated to be the effector cells in these studies by fluorescence-activated cell sorting followed by ADCC assays. Notably, all anti-Env MAbs tested in this study, including MAbs directed against each of the known neutralization epitope clusters in gp120, directed significant levels of ADCC against targets expressing Env of one or more HIV-1 strains. These results imply that many, if not most, HIV-1-neutralizing human Abs of high affinity (> or = 3 x 10(8) liters/mol in these studies) and of the immunoglobulin G1 (IgG1) subclass (i.e., the predominate IgG subclass) are capable of directing ADCC. Since neutralizing Abs have been associated with long-term survival following HIV-1 infection, this suggests that ADCC activity may be beneficial in vivo.

Inhibition of virus attachment to CD4+ target cells is a major mechanism of T cell line-adapted HIV-1 neutralization.

Antibody-mediated neutralization of human immunodeficiency virus type-1 (HIV-1) is thought to function by at least two distinct mechanisms: inhibition of virus-receptor binding, and interference with events after binding, such as virus-cell membrane fusion. Here we show, by the use of a novel virus-cell binding assay, that soluble CD4 and monoclonal antibodies to all confirmed glycoprotein (gp)120 neutralizing epitopes, including the CD4 binding site and the V2 and V3 loops, inhibit the adsorption of two T cell line-adapted HIV-1 viruses to CD4+ cells. A correlation between the inhibition of virus binding and virus neutralization was observed for soluble CD4 and all anti-gp120 antibodies, indicating that this is a major mechanism of HIV neutralization. By contrast, antibodies specific for regions of gp120 other than the CD4 binding site showed little or no inhibition of either soluble gp120 binding to CD4+ cells or soluble CD4 binding to HIV-infected cells, implying that this effect is specific to the virion-cell interaction. However, inhibition of HIV-1 attachment to cells is not a universal mechanism of neutralization, since an anti-gp41 antibody did not inhibit virus-cell binding at neutralizing concentrations, implying activity after virus-cell binding.

A novel antibody-dependent cellular cytotoxicity epitope in gp120 is identified by two monoclonal antibodies isolated from a long-term survivor of human immunodeficiency virus type 1 infection.

Two monoclonal antibodies (MAbs), 42F and 43F, were isolated some 14 months apart from a single long-term survivor of human immunodeficiency virus type 1 (HIV-1) infection. These MAbs were found to be indistinguishable in terms of their isotypes, specificities, affinities, and biological activities. Both 42F and 43F directed substantial antibody-dependent cellular cytotoxicity (ADCC) against cells infected with four divergent lab-adapted strains of HIV-1, but no neutralizing activity against these strains was detectable. The ability of MAbs 42F and 43F, as well as that of MAbs against two other gp120 epitopes, to direct ADCC against uninfected CD4+ cells to which recombinant gp120SF2 had been adsorbed (i.e., "innocent bystanders") was demonstrated to be less efficient by at least an order of magnitude than their ability to direct ADCC against HIV-1-infected cells. Flow cytometry analyses showed that 42F and 43F also bind to native primary isolate Envs from clades B and E expressed on cell surfaces. By direct binding and competition assays, it was demonstrated that the 42F/43F epitope lies in a domain of gp120 outside the previously described CD4-binding site and V3 loop ADCC epitope clusters. Immunoblot analysis revealed that the 42F/43F epitope is not dependent on disulfide bonds or N-linked glycans in gp120. Epitope mapping of 42F and 43F by binding to linear peptides demonstrated specificity of these MAbs for a sequence of 10 amino acids in the C5 domain comprising residues 491 to 500 (Los Alamos National Laboratory numbering for the HXB2 strain). Thus, 42F and 43F define a new ADCC epitope in gp120. Because of the relative conservation of this epitope and the fact that it appears to have been significantly immunogenic in the individual from which these MAbs were derived, it may prove to be a useful component of HIV vaccines. Furthermore, these MAbs may be used as tools to probe the potential importance of ADCC as an antiviral activity in HIV-1 infection.

Synergistic neutralization of human immunodeficiency virus type 1 by a chimpanzee monoclonal antibody against the V2 domain of gp120 in combination with monoclonal antibodies against the V3 loop and the CD4-binding site.

Synergistic neutralization of human immunodeficiency virus type 1 (HIV-1) was observed in studies using a chimpanzee anti-V2 monoclonal antibody (MAb), C108G, in combination with anti-V3 loop and anti-CD4 binding-site (bs) MAbs of different epitope specificities. C108G paired with either of two anti-V3 loop MAbs or either of two anti-CD4 bs MAbs synergistically neutralized both the uncloned IIIB and clonal HXB2 strains of virus in H9 target cells. Synergism was quantitated by calculation of combination indices. Significant synergy with a given MAb pair was seen over a range of MAb ratios, with the optimal effect centering around the ratio at which the MAbs were equipotent for a given HIV-1 strain (on the basis of the 50% neutralization titer). In preliminary experiments with monocytotropic strains of HIV-1 in peripheral blood mononuclear cell targets, significant synergism was also observed between anti-V2-anti-V3 and anti-V2-anti-CD4 bs MAb pairs. Synergism by all MAb pairs tested was greater against heterogeneous isolates of HIV-1 (IIIB and Ba-L) than against clonal isolates (HXB2 and NLHXADA), suggesting that strain broadening may be a component of the synergism observed against the heterogeneous isolates. In addition, conformational changes in gp120 upon binding of one or both MAbs may result in increased affinity or exposure of the epitope of one or both MAbs. Finally, a three-MAb combination of C108G, an anti-V3 MAb, and an anti-CD4 bs MAb was more effective in neutralizing the HXB2 strain of HIV-1 than any of the three two-MAb combinations within this trio, as determined by the dose reduction indices of each MAb required to achieve a given level of neutralization. This is the first report of synergistic neutralization of HIV-1 by a three-MAb combination composed of MAbs directed against the three major neutralization epitope clusters in gp120. Implications for vaccine design and for immunoprophylaxis and immunotherapy with a combination of MAbs are discussed.

In vitro effects of anti-HIV immunotoxins directed against multiple epitopes on HIV type 1 envelope glycoprotein 160.

We have used a panel of anti-gp160 MAbs to construct anti-HIV immunotoxins by coupling antibodies to ricin A chain (RAC). The ability of the immunotoxins to kill HIV-1-infected cells and halt the spread of infection was tested in tissue culture on persistently and acutely infected cell lines and primary lymphocyte cultures stimulated with phytohemagglutinin (PHA blasts). Laboratory strains and clinical isolates of HIV both were tested. The constitution and antigen-binding capacity of the immunotoxins were confirmed by ELISA and indirect immunofluorescence. Immunotoxins that bind epitopes exposed on the cell surface effectively killed persistently infected cells, although killing was not directly proportional to binding of immunotoxin to cell. The activity of anti-gp41, but not anti-gp120, immunotoxins was markedly enhanced in the presence of soluble CD4 or peptides corresponding to the CDR3 region of CD4. CD4-mediated enhancement of anti-gp41 immunotoxin activity was observed for laboratory strains neutralized by sCD4 and for clinical isolates that were resistant to neutralization by sCD4. Immunotoxin action was potentiated by brefeldin A, bafilomycin A1, cortisone, and an amphipathic fusion peptide, but not by cytochalasin D, nocodazol, monodansyl cadaverine, or trans-retinoic acid. Anti-HIV immunotoxins are useful tool with which to study the functional expression of gp120/gp41 antigens on the surface of HIV-infected cells, as well as potential AIDS therapeutics. Because these studies relate to the accessibility of viral antigens to antibody-mediated attack, these studies also have relevance for vaccine development.

Characterization of the variable regions of a chimpanzee monoclonal antibody with potent neutralizing activity against HIV-1.

The variable (V) regions of C108G, a potent neutralizing chimpanzee mAb against a glycan-dependent epitope in the V2 region of HIV-1 gp120, have been characterized for reactivity with human VH and VK family-specific antisera, and their nucleotide sequences have been determined and analysed. To our knowledge, this is the first study characterizing expressed chimpanzee VH and VK genes. Results show that C108G expresses members of the VH3 and VK1 families, the largest VH and VK families in humans, respectively. Nucleotide and amino acid sequence analyses reveal that C108G VH is most homologous to the human VH3 germline gene, hsigdp33 or V3-43, and the human JH4 minigene. The human germline VK1 gene that is most homologous to C108G VK, hsigk1012, was previously observed in unmutated form in a human autoantibody with anti-i red blood cell antigen specificity and in seven human Fabs and a mAb directed against epitopes overlapping the CD4-binding site of HIV-1 gp120. This germline gene was unmutated in three of the human Fabs and was somatically mutated in the other four Fabs and the mAb. In addition, the JK minigene was used in C108G VK, JK2, is apparently over-represented in anti-HIV-1 mAbs/Fabs; this minigene was used in 61% of the anti-gp120 human Fabs recently described and in three other anti-CD4-binding site human mAbs derived by EBV transformation. While the significance of these findings is unclear, they may suggest a bias in VK/JK gene usage and/or network regulation involving an hsigk1012/JK2 idiotope(s) in the antibody response to HIV-1. Both the C108G VH and VK genes showed evidence of somatic mutation and antigen selection that apparently occurred in vivo during chronic exposure to HIV-1 and its antigens. Surprisingly, this somatic mutation was most profound in the CDR3 region of C108G VK; this region shared only 48% nucleotide homology with hsigk1012 contrasted with a homology of 94% over the remainder of these two V gene sequences. Perhaps the most significant finding of this study is that the expressed VH and VK genes of chimpanzee mAb C108G are no more divergent from their most homologous human germline genes than are the expressed V genes of several recently characterized human anti-HIV-1 mAbs/Fabs from their apparent human germline genes. This suggests that chimpanzee mAbs are no more likely to elicit deleterious anti-immunoglobulin responses in humans than are human mAbs and emphasizes the potential for development of chimpanzee mAbs as immunotherapeutic agents.

Characterization of neutralization epitopes in the V2 region of human immunodeficiency virus type 1 gp120: role of glycosylation in the correct folding of the V1/V2 domain.

A number of monoclonal antibodies (MAbs) with various levels of neutralizing activity that recognize epitopes in the V1/V2 domain of LAI-related gp120s have been described. These include rodent antibodies directed against linear and conformational epitopes and a chimpanzee MAb, C108G, with extremely potent neutralizing activity directed against a glycan-dependent epitope. A fusion glycoprotein expression system that expressed the isolated V1/V2 domain of gp120 in native form was used to analyze the structural characteristics of these epitopes. A number of MAbs (C108G, G3-4, 684-238, SC258, 11/68b, 38/66a, 38/66c, 38/62c, and CRA3) that did not bind with high affinity to peptides immunoprecipitated a fusion glycoprotein expressing the V1/V2 domain of HXB2 gp120 in the absence of other human immunodeficiency virus sequences, establishing that their epitopes were fully specified within this region. Biochemical analyses indicated that in the majority of V1/V2 fusion molecules only five of the six glycosylation signals in the V1/V2 domain were utilized, and the glycoforms were found to be differentially recognized by particular MAbs. Both C108G and MAbs directed against conformational epitopes reacted with large fractions of the fully glycosylated molecules but with only small fractions of the incompletely glycosylated molecules. Mutational analysis of the V1 and V2 glycosylation signals indicated that in most cases the unutilized site was located either at position 156 or at position 160, suggesting the occurrence of competition for glycan addition at these neighboring positions. Mutation of glycosylation site 160 destroyed the C108G epitope but increased the fraction of the molecules that presented the conformational epitopes, while mutation of the highly conserved glycosylation site at position 156 greatly diminished the expression of the conformational epitopes and increased expression of the C108G epitope. Similar heterogeneity in glycosylation was also observed when the HXB2 V1/V2 fusion glycoprotein was expressed without most of the gp70 carrier protein, and thus, this appeared to be an intrinsic property of the V1/V2 domain. Heterogeneity in expression of conformational and glycan-dependent epitopes was also observed for the natural viral env precursor, gPr160, but not for gp120. These results suggested that the closely spaced glycosylation sites 156 and 160 are often alternatively utilized and that the pattern of glycosylation at these positions affects the formation of the conformational structures needed for both expression of native epitopes in this region and processing of gPr160 to mature env products.

Bathophenanthroline disulfonate and soluble CD4 as probes for early events of HIV type 1 entry.

We report here that a metalloprotease inhibitor, bathophenanthroline disulfonate (Bphe-ds), neutralizes both laboratory-adapted and primary strains of HIV-1. Presaturation of Bphe-ds with zinc does not alter its neutralizing activity, suggesting that the metal-chelating ability of Bphe-ds is not required for neutralization. Bphe-ds blocks infection of CD4+ cells at the stage of viral entry, not through a direct viricidal effect, but by interfering with both binding and postbinding events. This drug interacts with HIV-1 envelope, blocking almost completely the binding of three MAbs that recognize epitopes overlapping the CD4-binding site on gp120, but has no effect on the binding of MAbs directed to the cellular receptor CD4. The exposure of epitopes in the V2 and V3 but not C5 domains of gp120 is partially decreased in the presence of Bphe-ds, suggesting that the drug induces conformational changes in the envelope glycoprotein(s). Binding of both virions and soluble gp120 to CD4+ cells is inhibited by this drug in a dose-dependent manner. This contrasted with the effects of soluble CD4, which actually increased binding of virions to cells at 4 degrees C, while inhibiting the binding of soluble gp120. Bphe-ds also increases shedding of gp120 from cells infected with HIV-1IIIB. Thus, Bphe-ds appears to be an envelope-directed inhibitor of HIV-1 that neutralizes HIV-1 infectivity via multiple mechanisms.

A novel, glycan-dependent epitope in the V2 domain of human immunodeficiency virus type 1 gp120 is recognized by a highly potent, neutralizing chimpanzee monoclonal antibody.

An anti-gp120 monoclonal antibody (MAb), C108G (gamma 1, kappa), was isolated from a chimpanzee that had been infected with strain IIIB of human immunodeficiency virus type 1 (HIV-1IIIB) and subsequently immunized with the recombinant glycoprotein rgp160MN. This MAb is specific for the IIIB strain of HIV-1 and related clones and exhibits very potent neutralization of these viruses; e.g., 100% neutralization of approximately 8 x 10(3) infectious units of HXB2 was achieved with 125 ng of C108G per ml. Commensurate with this potent neutralizing activity, the apparent affinity of C108G for rgp160LAI was very high, i.e., approximately 3 x 10(10) liters/mol. The C108G epitope was not destroyed by reduction of gp120 disulfide bonds but was profoundly disrupted by removal of N-linked sugars from gp120. Despite the importance of a glycan(s) in forming the C108G epitope, specific binding of C108G to synthetic peptides overlapping in amino acids 162 to 169 of the V2 region was detected, albeit with an affinity approximately 2,000-fold lower than that of C108G's binding to glycosylated envelope protein. This epitope mapping correlated with results of competition assays using MAbs of known epitope specificities. To our knowledge, this is the first description of an anti-V2 MAb raised in response to HIV-1 infection. Its potent neutralizing activity and epitope specificity indicate that the V2 domain of gp120 may be an effective target of the protective immune response and, therefore, potentially an important component of HIV vaccines.

A potent, neutralizing human monoclonal antibody against a unique epitope overlapping the CD4-binding site of HIV-1 gp120 that is broadly conserved across North American and African virus isolates.

A human monoclonal antibody (HuMAb), 5145A, against HIV-1 gp120 was isolated from an asymptomatic, seropositive hemophiliac. The epitope of this HuMAb was destroyed by reduction of gp120 disulfide bonds, but not by removal of N-linked carbohydrates. This epitope overlaps the CD4-binding site of gp120, because binding of 5145A to gp120 is inhibited by soluble CD4 and by 1125H, a previously described HuMAb directed toward the CD4-binding site. However, the 5145A epitope differs from those of 1125H and other anti-CD4-binding site HuMAbs previously described, as documented by the viral strain specificity of 5145A and its reactivity with a panel of gp120 mutants. Specifically, 5145A reacted with 14 of 15 HIV-1 isolates tested, including 9 isolates from the Central African Republic, 6 of which were not recognized by 1125H. Partial epitope mapping of 5145A, using a series of gp120 mutants, demonstrated its lack of sensitivity to mutations in residues 257 and 427, contrasting with a marked sensitivity to mutations in residues 368 and 370. This pattern of reactivity distinguishes its epitope from that of any HuMAb against the CD4-binding site region described to date. In addition, 5145A exhibited potent and essentially equivalent neutralization of the MN, SF-2, IIIB, and RF strains and possessed significant neutralizing activity against three of three African strains tested. Finally, 5145A synergistically neutralized the MN and SF-2 strains of HIV-1 when combined with 4117C, a HuMAb against the V3 loop. The broad strain specificity and potent neutralizing activity of 5145A, together with its ability to synergize with an anti-V3 loop HuMAb in neutralizing HIV-1, indicate that 5145A has excellent potential as a passive immunotherapeutic agent against HIV-1.

Conformational changes affecting the V3 and CD4-binding domains of human immunodeficiency virus type 1 gp120 associated with env processing and with binding of ligands to these sites.

Two neutralizing human monoclonal antibodies (HuMAbs) directed against epitopes located near the tip of the V3 loop of human immunodeficiency virus type 1 env protein recognized solubilized gPr160, but not gp120, in radioimmunoprecipitation assays. Efficient immunoprecipitation of solubilized gp120 by these antibodies did occur in the presence of HuMAb 1125H, directed against a conformational epitope overlapping the CD4-binding site, or its F(ab')2 fragment. In contrast to the inability of the anti-V3 antibodies to immunoprecipitate solubilized gp120, these HuMAbs did bind to gp120 in intact virions; this level of binding increased severalfold in the presence of the F(ab')2 fragment of 1125H. These results demonstrate that neutralization epitopes in the V3 loop are sequestered in soluble gp120 but partly exposed in gPr160 and in virion-associated gp120 and that binding of antibodies to the discontinuous CD4-binding site leads to conformational changes that result in the exposure of V3 epitopes in soluble gp120 and their enhanced accessibility in gPr160 and in virion-associated gp120. Enhanced binding of suboptimal concentrations of 1125H to soluble gp120 was also induced by the presence of an anti-V3 HuMAb, indicating the occurrence of reciprocal allosteric interactions between the V3 loop and the CD4-binding site. It is likely that these effects contribute to the synergistic neutralization of human immunodeficiency virus type 1 previously reported for antibodies directed against these two regions.

Synergistic neutralization of HIV-1 by human monoclonal antibodies against the V3 loop and the CD4-binding site of gp120.

Two distinct regions or epitope clusters of human immunodeficiency virus type 1 (HIV-1) gp120 have been shown to elicit neutralizing antibodies: the V3 loop and the CD4-binding site. We have isolated neutralizing human monoclonal antibodies (HuMAbs) against conserved epitopes in both of these regions. In this study, we demonstrate that an equimolar mixture of two of these HuMAbs, one directed against the V3 loop and the other against the CD4-binding site, neutralizes HIV-1 at much lower concentrations than does either of the individual HuMAbs. Mathematical analysis of this effect suggests cooperative neutralization of HIV-1 by the two HuMAbs and demonstrates a high level of synergy, with combination indices (CIs) of 0.07 and 0.16 for 90% neutralization of the MN and SF-2 strains, respectively. The dose reduction indices (DRIs) for each of the two HuMAbs at 99% neutralization range approximately from 10 to 150. A possible mechanism for this synergism is suggested by binding studies with recombinant gp160 of the MN strain; these show enhanced binding of the anti-CD4 binding site HuMAb in the presence of the anti-V3 loop HuMAb. These results demonstrate the advantage of including both V3 loop and CD4-binding site epitopes in a vaccine against HIV-1 and indicate that combinations of HuMAbs against these two sites may be particularly effective in passive immunotherapy against the virus.

A human monoclonal antibody against the CD4-binding site of HIV1 gp120 exhibits potent, broadly neutralizing activity.

A human monoclonal antibody (HuMAb) against HIV1, 1125H, was isolated from an asymptomatic, seropositive haemophiliac. This antibody was specific for gp120, and its binding to gp120 was inhibited by soluble CD4, indicating that its epitope was in or near the CD4-binding site. 1125H antibody recognized a variety of divergent HIV1 strains, including most laboratory strains tested as well as some early passage isolates. Commensurate with its specificity and high apparent affinity, 1125H exhibited potent neutralizing activity against IIIB, MN, RF and SF-2 strains. The epitope recognized by 1125H was destroyed by reduction of disulphide bonds, but not by removal of N-linked sugars. Thus, the epitope was conformationally determined and did not involve carbohydrate. Data from radioimmunoprecipitation/SDS-PAGE analysis of proteolytically cleaved viral lysate further indicated that the epitope of 1125H was not affected by cleavage at the V3 loop of gp120, provided that gp120 disulphide bonds remained intact. The potential use of HuMAb 1125H in passive immunotherapy against HIV is discussed as well as the importance of including its epitope in an AIDS vaccine.

Oligomeric structure of gp41, the transmembrane protein of human immunodeficiency virus type 1.

We characterized the structural forms of the human immunodeficiency virus env-encoded proteins with a panel of monoclonal and polyclonal antibodies. Western blot (immunoblot) assays with antibodies specific for gp41 invariably recognized a major component of 160 kilodaltons and a less intense component of 120 kilodaltons in viral lysates. We demonstrated that these species are noncovalently associated tetramers and trimers of gp41 which represent the native form of this protein in virions. These complexes were stable when boiled in the presence of low concentrations of sodium dodecyl sulfate but were dissociated to gp41 monomers at high sodium dodecyl sulfate concentrations. Moreover, two human monoclonal antibodies preferentially recognized the oligomeric complexes over monomeric gp41 in Western blots, indicating the presence of epitopes recognized by the human immune system on the gp41 multimers which are not efficiently expressed by the dissociated monomers. The demonstration of the existence of multimeric env complexes and the enhanced and altered antigenicity of such multimers may be relevant to the design of subunit and recombinant human immunodeficiency virus env vaccines.

Nucleotide sequence of an unequal sister chromatid exchange site in a mouse myeloma cell line.

The mouse myeloma cell line MPC 11 carries two C gamma 2a immunoglobulin heavy-chain genes on the expressed chromosome, a duplication shown to have occurred through unequal sister chromatid exchange (USCE). In the present report, we present the nucleotide sequence of the USCE joint and show that both breaks occurred within tracts of repeated TC dinucleotides. Additional TC dinucleotide tracts and two oligonucleotide segments (N sequences) were inserted at the USCE site.

Unequal sister chromatid exchange. A mechanism affecting Ig gene arrangement and expression.

Two gamma 2a gene forms in the MPC11 mouse myeloma cell line (gamma 2b, K) have been localized to the expressed H chain chromosome, where they exist in tandem downstream of the expressed gamma 2b gene. The gamma 2a gene duplication has apparently occurred by spontaneous, unequal sister chromatid exchange (SCE) in a B lymphoid precursor of MPC11 or in MPC11 itself. It is especially significant that either of the tandem gamma 2a gene forms may be used in the class switch from gamma 2b to gamma 2a production occurring in the MPC11 line, indicating that heavy chain constant region (CH) gene duplication (or deletion) may be a mechanism normally impinging on CH gene expression. The gamma 2a genes of MPC11 undergo further copy number variation via unequal SCE in variants of this line derived by mutagenesis and selection for altered H chain production. The remarkable frequency with which copy number variation occurs in these cells suggests that unequal SCE may play a physiological role in CH gene arrangement and expression.

Hybrid gamma 2b-gamma 2a genes expressed in myeloma variants: evidence for homologous recombination.

The expressed immunoglobulin heavy chain genes of five gamma 2b-gamma 2a hybrid chain-producing variants of the mouse myeloma MPC-11 (gamma 2b, kappa) have been characterized by genomic Southern blot analysis. Results show that a hybrid gamma 2b-gamma 2a gene was formed in each variant by recombination between the expressed gamma 2b gene of MPC-11 and a gamma 2a gene. The recombination sites are within regions of marked homology between gamma 2b and gamma 2a genes: at least three and probably four variants show gamma 2b-gamma 2a recombination within the heavy chain constant region 2 (CH2) domain, while the fifth has its recombination site between the penultimate nucleotide of CH1 and the eighth nucleotide of the hinge. An unexpected finding is that the hybrid heavy chain-producing variants fall into two subgroups based on their use of different gamma 2a gene forms in hybrid gene formation. This result leads to the speculation that either a tandem gamma 2a gene duplication was present in MPC-11 prior to variant generation or mitotic recombination between chromosomes occurred in the generation of one variant subgroup. The similarity of hybrid gene formation in MPC-11 variants to that apparently responsible for concerted evolution within multigene families and hybrid protein expression in various individuals is noted, and the possible relationship between hybrid gene formation and the heavy chain class switch is discussed.

DNA rearrangements in MPC-11 immunoglobulin heavy chain class-switch variants.

Immunoglobulin heavy chain class switching has been observed in vitro. In the IgG2b-producing MPC-11 mouse myeloma cell line, IgG2a-producing cells arise at a high frequency. In some cases, switch variants producing normal-sized (Mr 55,000) gamma 2a heavy chains have arisen spontaneously from a mutagen-induced "intermediate" (ICR 9.7.1) that produces an unusually large (Mr 75,000) heavy chain. Other switch variants have been isolated directly from the parent cell line. The expressed and unexpressed gamma 2b genes of MPC-11 can be distinguished in restriction endonuclease digests of total genomic DNA so that DNA rearrangements detected in MPC-11 variants can be directly associated with one or the other of these two genes. We describe here DNA rearrangements occurring on the expressed heavy chain chromosome of several MPC-11 gamma 2a switch variants and on the expressed chromosome of the ICR 9.7.1 intermediate. Our data indicate that all of these variants express the parental heavy chain variable region (VH) gene, supporting previous protein studies. We provide mapping data for the expressed gene of both ICR 9.7.1 and one of the IgG2a-producing variant cell lines (ICR 9.9.2.1) derived from it and discuss the advantages of an in vitro switching system for examining the dynamics of the immunoglobulin heavy chain class switch.