Chimaeric monoclonal antibodies encoded by the human VH26 gene from naïve transgenic mice display a wide range of antigen-binding specificities

High-throughput immunoglobulin repertoire analysis distinguishes between human IgM memory and switched memory B-cell populations

B-cell receptor (BCR) diversity is achieved centrally by rearrangement of Variable, Diversity, and Joining genes, and peripherally by somatic hypermutation and class-switching of the rearranged genes. Peripheral B-cell populations are subject to both negative and positive selection events in the course of their development that have the potential to shape the BCR repertoire. The origin of IgM(+)IgD(+)CD27(+) (IgM memory) cells is controversial. It has been suggested that they may be a prediversified, antigen-independent, population of cells or that they are a population of cells that develop in response to T-independent antigens. Most recently, it was suggested that the majority of IgM memory cells are directly related to switched memory cells and are early emigrants from the germinal center reaction. Advances in sequencing technology have enabled us to undertake large scale IGH repertoire analysis of transitional, naive, IgM memory and switched memory B-cell populations. We find that the memory B-cell repertoires differ from the transitional and naive repertoires, and that the IgM memory repertoire is distinct from that of class-switched memory. Thus we conclude that a large proportion of IgM memory cells develop in response to different stimuli than for class-switched memory cell development.

Cloning and molecular characterization of a human recombinant IgG Fab binding to the Tat protein of human immunodeficiency virus type 1 (HIV-1) derived from the repertoire of a seronegative patient

A study aiming at cloning and characterizing natural antibodies to human immunodeficiency virus type 1 (HIV-1) targets is described. In particular, we report the molecular cloning of a Fab molecule binding the HIV-1/Tat protein from a seronegative patient. The Fab was characterized for its binding specificity and investigated in regards to its molecular structure. Furthermore, to evaluate the role played by the heavy and light chains in the binding to the antigen, hybrid Fabs were constructed combining the heavy and the light chain of the natural anti-Tat clone with a control high-affinity Fab derived from the repertoire of the same patient. The results indicate that the natural immunoglobulin under study: (i) is a polyreactive antibody of IgG1 isotype, and not an IgM as usually described for anti-HIV natural clones, (ii) shows a pattern of mutations compatible with an antigen-driven mechanisms, (iii) its heavy chain derives from a V-gene subfamily (V3-23) highly represented in fetal life, and (iv) its heavy chain variable region exhibits several characteristics, including an extremely long, hydrophilic CDR3, that are unusual and theoretically important in determining the polyreactive capacity of the molecule.

The role of antigen in the selection of the human V3-23 immunoglobulin heavy chain variable region gene

The immune system mounts antibody responses using few of the available immunoglobulin variable region (IgV) genes with some, such as the V3-23 heavy chain gene, regularly over-represented in responses to many antigens. The reasons for the over-representation of some V genes have not been established; the process could be either stochastic or selective. We demonstrated previously that the V3-23 gene, which is over-represented in the primary B lymphocyte repertoire in humans, encodes antibodies with differing antigen-binding reactivities in transgenic mice that express the human V3-23 gene. The aim of the current study was to assess if V3-23 gene over-representation is stochastic or could be influenced by antigen exposure. Transgenic mice were immunized with human IgG-Fc (hIgG-Fc), bovine collagen type II (bCII) or tetanus toxoid (TT), and hybridomas secreting human mu chain-containing antibodies generated. These were tested for binding to the immunogens and a panel of self- and exogenous antigens. In hybridomas derived from hIgG-Fc-immunized mice, 53% secreted antibodies specific for hIgG-Fc. A similar proportion (54%) of hybridomas from bCII-immunized mice secreted antibody that bound to collagen. By contrast, only 21% of hybridomas from mice immunized with TT bound to tetanus toxoid. Intriguingly, chimaeric antibodies generated from mice immunized with bCII or TT were mainly polyreactive, similar to antibodies generated from naive transgenic mice. However, hybridomas generated from mice immunized with hIgG-Fc were mainly specific, reacting exclusively with hIgG-Fc. These results suggest that selection and eventual expansion of B lymphocytes expressing the V3-23 gene are likely to be determined by exposure to self- and/or environmental antigens.

The effects of a human IgM monoclonal anticardiolipin antibody on pregnancy in a transgenic mouse model

The clinical features of antiphospholipid (or Hughes') syndrome (APS) are most commonly seen in individuals who have raised levels of IgG anticardiolipin antibodies. Most murine models of the syndrome have involved the administration of such antibodies to normal mice. However, APS can occur in the presence of raised levels of serum IgM anticardiolipin antibodies alone. The present study was designed to see if an IgM monoclonal antibody can induce changes in mice similar to those seen in human APS. This antibody, BH1, has previously been derived from a patient with primary APS. In its ligand-binding and idiotypic characteristics it is representative of antiphospholipid antibodies (aPL) found in the serum of patients with APS. In order to minimise the immune response to human IgM, we used transgenic mice (F15) which express, and are predicted to be tolerant of, human immunoglobulin mu chains. The features of APS may develop more readily in individuals who have an existing autoimmune disorder, such as systemic lupus erythematosus (SLE). We therefore crossed these transgenic mice with New Zealand Black (NZB, SLE-prone) mice, and used the progeny (F15 x NZB/F1) in our experiments. Twenty-four F15 x NZB/F1 mice were given BH1, or a control IgM antibody, (A5566) immediately preceding and then three times during pregnancy. There was a reduction in the mean number of foetuses in animals given BH1 compared with those given A5566 (8.6 vs 11.0; P < 0.05), and a similar reduction in mean total foetal weight per pregnancy (9.05 vs 12.73 g; P < 0.05). Two mice showed a marked reduction in platelet count. No evidence of thrombosis was detected macroscopically or histologically. Our results show a lower incidence of APS-type features compared to previous studies in which mice have been administered aPL. This may be because BH1 is an IgM antibody. Nevertheless, the data support the concept that IgM aPL of particular ligand-binding specificities may have a direct pathogenetic role in certain cases of human APS.

Rearrangement of the human heavy chain variable region gene V3-23 in transgenic mice generates antibodies reactive with a range of antigens on the basis of VHCDR3 and residues intrinsic to the heavy chain variable region

To formulate a 'logic' for how a single immunoglobulin variable region gene generates antibodies with different antigen specificity and polyreactivity, we analysed chimeric antibodies produced in transgenic mice carrying the germ-line human V3-23 gene, multiple diversity (D) and joining (J) gene segments. Hybridomas producing antibodies encoded by the V3-23 gene in combination with different mouse Vkappa genes were obtained by fusion of splenocytes from transgenic mice. All antibodies had human mu-chains and mouse light chains, were multimeric in structure and expressed the human V3-23 gene. Nucleotide sequence analyses of genes encoding the heavy and light chains of 12 antibodies in relation to antigen specificity highlighted the importance of heavy chain variable region CDR3 in determining reactivity with different antigens. However, the results also suggest that non-CDR3 sequences intrinsic to the V3-23 gene itself may be involved in, or determine, the binding of the chimeric antibodies to some of the antigens tested in the current study.

Light chain determines the binding property of human anti-dsDNA IgG autoantibodies

We have previously prepared human anti-double-stranded (ds) DNA IgG Fab clones using phage-display technology. Nucleotide sequence analysis of genes of immunoglobulin (Ig) heavy and light chain variable regions in these Fab clones suggested that the DNA-binding activity of the clones depended on light chain usage. To confirm the role of the light chain in antibody binding to DNA, we constructed in the present study's new recombined Fab clones by heavy and light chain shuffling between the original anti-dsDNA Fab clones. Clones constructed by pairing Fdgamma fragments with the light chain from a high DNA-binding clone showed high DNA-binding activities, whereas other constructed clones using light chains from low DNA-binding clones showed low DNA-binding activities. Our results indicate that light chains in anti-dsDNA antibodies can determine the DNA-binding activity of the antibodies. Ig chain shuffling of phage-display antibodies may be useful for investigating the molecular mechanisms for antigen-antibody binding of human autoantibodies.

Antibody Repertoires of Four- and Five-Feature Translocus Mice Carrying Human Immunoglobulin Heavy Chain and κ and λ Light Chain Yeast Artificial Chromosomes

We have produced mice that carry the human Ig heavy (IgH) and both κ and λ light chain transloci in a background in which the endogenous IgH and κ loci have been inactivated. The B lymphocyte population in these translocus mice is restored to about one-third of normal levels, with preferential (3:1) expression of human λ over human κ. Human IgM is found in the serum at levels between 50 and 400 μg/ml and is elevated following immunization. This primary human Ab repertoire is sufficient to yield diverse Ag-specific responses as judged by analysis of mAbs. The use of DH and J segments is similar to that seen in human B cells, with an analogous pattern of N nucleotide insertion. Maturation of the response is accompanied by somatic hypermutation, which is particularly effective in the light chain transloci. These mice therefore allow the production of Ag-specific repertoires of both IgM,κ and IgM,λ Abs and should prove useful for the production of human mAbs for clinical use.

Production of human antibody repertoires in transgenic mice

Transgenic mice have been created that carry human immunoglobulin heavy and light chain genes in germline configuration and that have the corresponding endogenous genes silenced. The transgenes are either minigene constructs or large, almost authentic, transloci on yeast artificial chromosomes and undergo B-cell-specific DNA rearrangement and hypermutation in the mouse lymphoid tissue. Monoclonal antibodies with good affinities for human antigens have been obtained after immunisation. These mice may be a future source of human antibodies for therapy.