Immunoglobulin V regions of a bactericidal anti-Neisseria meningitidis outer membrane protein monoclonal antibody

Systematic design and testing of nested (RT-)PCR primers for specific amplification of mouse rearranged/expressed immunoglobulin variable region genes from small number of B cells

The aim of this study was to develop a highly specific and sensitive (RT-)PCR capable of potentially amplifying the rearranged/expressed VH and VL gene belonging to any mouse immunoglobulin V gene family from a single or a small number of B cells. A database of germline immunoglobulin sequences was used to design 112 primers for a nested (RT-)PCR based strategy to cover all VH, VL, JH, JL, CH and CL gene families/genes from C57BL/6 and BALB/c mice. 93.7% of the primers had 4-fold or less, while 71.4% had no degeneracy. The proportions of germline V genes to which the primers bind with no, up to 1 and up to 2 mismatches are 59.7%, 84.1% and 94.9%, respectively. Most but not all V gene family specific primers designed allow amplification of full-length V genes. The nested primers permit PCR amplification of rearranged V genes belonging to all VH and VL gene families from splenocyte genomic DNA. The V gene family-specific nature of the primers was experimentally confirmed for randomly selected 6 VH and 6 Vkappa families, and all Vlambda genes. The broad V gene family coverage of our primer set was experimentally validated by amplifying the rearranged/expressed VH and VL genes from splenocytes and a panel of 38 hybridomas under conditions where primer mixes and genomic DNA or total RNA was used as starting template. We observed no or low-level cross-family priming. Pooled constant region specific primers allowed efficient RT-PCR amplification of H and L chain isotypes. The expressed VH and VL genes belonging to different V gene families RT-PCR amplified from a mixture of hybridomas in a representative manner. We successfully amplified the expressed VH and Vkappa gene from a single hybridoma cell by RT-PCR and from 10-15 microdissected B cells by genomic PCR. This, first of its kind, comprehensive set of highly sensitive and specific nested primers that provide broad V gene family coverage will open up new avenues and opportunities to study various aspects of mouse B cell biology.

Development and characterization of a murine monoclonal antibody specific for the P1.15 PorA proteins from vaccine strain B:4,7:P1.19,15 of Neisseria meningitidis

Neisseria meningitidis isolates are conventionally classified by serosubtyping, which characterizes the reactivities of the PorA outer membrane protein variable-region epitopes with monoclonal antibodies (MAbs). New murine hybridomas, secreting specific MAbs against PorA of N. meningitidis serogroup B, were generated using conventional hybridoma procedures. Using outer membrane protein as antigen, we obtained two positive clones, and one of them we characterized. This MAb reacted, on whole-cell enzyme-linked immunosorbent assay (ELISA) and immunoblotting, only with strain subtype P1.15 and its IgG2b isotype. This MAb demonstrated bactericidal activity against the homologous strain in the presence of human complement.

Mapping of monoclonal antibodies specific to P64k: A common antigen of several isolates of Neisseria meningitidis

P64k is a minor outer membrane protein from Neisseria meningitidis. This protein has been produced at high levels in Escherichia coli. We generated a group of monoclonal antibodies (mAbs) against recombinant P64k, which recognise four non-overlapping epitopes, as shown using competition assays with biotinylated mAbs. The P64k sequences involved in mAbs binding were mapped with synthetic overlapping peptides derived from the P64k protein, and located in the previously determined three-dimensional structure of the protein. These antibodies were also characterised by whole-cell ELISA and bactericidal tests against N. meningitidis. Only two of the recognised epitopes were exposed on the bacterial surface, and none of the mAbs showed bactericidal activity. The relationship between these results and the structural data on the epitopes bound by the mAbs is discussed.Key words: Neisseria meningitidis, P64k, monoclonal antibodies, epitope mapping.

Universal PCR amplification of mouse immunoglobulin gene variable regions: the design of degenerate primers and an assessment of the effect of DNA polymerase 3' to 5' exonuclease activity

Degenerate primers were designed for PCR amplification of unknown mouse immunoglobulin (Ig) light (L) and heavy (H) chain variable (V) genes. Each subgroup of mouse Ig gene sequences [Kabat, E.A., Wu, T. T., Perry, H.H., Gottesman, K.S., Foeller, C., 1991. Sequences of Proteins of Immunological Interest, 5th edn. US Department of Health and Human Services, Public Health Service, NIH.] was analyzed, and highly degenerate primers in the framework one (FR1) region were designed. A single highly degenerate FR1 primer sufficed for the amplification of light chains; for heavy chains, a series of FR1 primers was used. At the same time, we assessed the effect of 3' to 5' exonuclease activity of DNA polymerase on the utilization of these degenerate primers. Using Taq polymerase, which lacks 3' to 5' exonuclease activity, we successfully amplified the Ig VL and VH genes expressed in more than a hundred monoclonal hybridoma cell lines reactive against a phosphonamidate hapten. Sequence analysis of the cloned VL and VH genes, 52 of each, showed that they are derived from multiple germline families (10 of the 17 VL families and 9 of the 14 VH families) as recently defined [Martinez, C., Lefranc, M., 1998. The mouse (Mus musculus) immunoglobulin kappa variable (IGKV) genes and joining (IGKJ) segments. Exp. Clin. Immunogenet. 15, 184.]. The universality of our primers was also demonstrated by successful amplification of other mouse hybridoma cell lines that are specific to different antigens.

Efficient amplification and direct sequencing of mouse variable regions from any immunoglobulin gene family

We have designed two original sets of oligonucleotide primers hybridizing the relatively conserved motifs within the immunoglobulin signal sequences of each of the 15 heavy chain and 18 kappa light chain gene families. Comparison of these 5' primers with the immunoglobulin signal sequences referenced in the Kabat database suggests that these oligonucleotide primers should hybridize with 89.4% of the 428 mouse heavy chain signal sequences and with 91.8% of the 320 kappa light chain signal sequences with no mismatch. Following PCR amplification using the designed primers and direct sequencing of the amplified products, we obtained full-length variable sequences belonging to major (V(H)1, V(H)2, V(H)3, Vkappa1 and Vkappa21) but also small-sized (V(H)9, V(H)14, Vkappa2, Vkappa9A/9B, Vkappa12/13, Vkappa23 and Vkappa33/34) gene families, from nine murine monoclonal antibodies. This strategy could be a powerful tool for antibody sequence assessment whatever the V gene family before humanization of mouse monoclonal antibody or identification of paratope-derived peptides.

Rapid cloning of any rearranged mouse immunoglobulin variable genes

Immunoglobulins (Ig) have been the focus of extensive study for several decades and have become an important research area for immunologists and molecular biologists. The use of polymerase chain reaction (PCR) technology has accelerated the cloning, sequencing, and characterization of genes of the immune system. However, cloning and sequencing the Ig variable (V) genes using the PCR technology has been a challenging task, primarily due to the very diverse nature of Ig V region genes. We have developed a simple, rapid, and reproducible PCR-based technique to clone any rearranged mouse Ig heavy or light chain genes. A close examination of all Ig heavy and light chain V gene families has resulted in the design of 5' and 3' universal primers from regions that are highly conserved across all heavy or light chain V gene families, and the joining or constant regions, respectively. We present our strategy for designing universal primers for Ig V gene families. These primers were able to rapidly amplify the rearranged Ig V genes, belonging to diverse Ig V gene families from very different cell lines, i.e., J558, MOPC-21, 36-60, and a chicken ovalbumin specific B-cell hybridoma. In addition, the present study provides the complete alignment of nucleotide sequences of all heavy and light chain variable gene families. This powerful method of cloning Ig V genes, therefore, allows rapid and precise analysis of B-cell hybridomas, B-cell repertoire, and B-cell ontogeny.

Fv structure of monoclonal antibody II-481 against herpes simplex virus Fc gamma-binding glycoprotein gE contains immunodominant complementarity determining region epitopes that react with human immunoglobulin M rheumatoid factors

Human immunoglobulin M (IgM) rheumatoid factors (RFs) show primary direct enzyme-linked immunosorbent assay (ELISA) reactivity with Fab rather than Fc fragments of monoclonal antibody (mAb) II-481 directed against the Fc gamma-binding site of herpes simplex virus glycoprotein gE. This preferential anti-Fab specificity suggests that RFs react with antigen-binding portions of mAb II-481 as anti-idiotypic antibodies directed at the combining site regions of mAb reacting with the Fc gamma-binding region of gE. Analysis of this idiotype-anti-idiotype reaction employed polymerase chain reaction amplification and sequencing of the variable heavy and light (VH and VL) regions of mAb II-481. When VH and VL regions of mAb II-481 were synthesized as overlapping 7-mer peptides on polypropylene pins, a panel of 10 polyclonal and 6 monoclonal human IgM RFs reacted primarily with epitopes within the three solvent-exposed mAb II-481 complementarity determining regions (CDRs). Preincubation of single CDR heptamer peptides with IgM RFs in free solution, resulted in 63-100% inhibition of RF binding to mAb II-481 on the ELISA plate, confirming the antigenic importance of linear CDR regions for RF reactivity. Combinations of two or three CDR peptides frequently produced 94-100% inhibition of RF binding to whole mAb II-481. Control peptides, singly or in combination, showed no inhibition. Computer modeling suggested that the RF-reactive mAb II-481 Fv region and a previously demonstrated RF-reactive CH3 epitope displayed considerable three-dimensional similarities in conformation. These studies may provide insight into limited shape homologies possibly involved in an RF anti-idiotypic reaction.

Vectors for the expression of PCR-amplified immunoglobulin variable domains with human constant regions

Cassette vectors have been constructed for mammalian expression of complete immunoglobulin heavy and light chain genes whose variable regions are produced by the polymerase chain reaction (PCR). The light and heavy chain vectors have promoter, leader, partial intron, enhancer and constant region segments within modified pSV2-gpt and pSV2-neo plasmids, respectively. Variable (V) regions are obtained by PCR using a two step process: 1) the V gene is amplified from genomic or cDNA, cloned into an intermediate vector and sequenced; 2) the first PCR product serves as the template for a second amplification in which restriction enzyme recognition sites and limited flanking intron sequence are added. The second PCR product is inserted into the expression vector, which is then transfected into mouse myeloma cells. These vectors contain human constant regions and may be used to express chimeric, humanized or human Ig genes. This report describes the design of these vectors and their application for the expression of chimeric 60.3, an anti-CD18 antibody.

Hybrid antibodies

One of the major advantages of genetic engineering is the ability to produce novel, hybrid antibodies. Hybrid antibodies can be assembled using fragments from different antibodies with the objective of assembling novel combinations of antibody-related effector functions. To efficiently achieve this goal it is necessary to have a precise understanding of the structure-function relationships within the antibody molecule. Secondly, it is possible to produce hybrids of antibodies with non-immunoglobulin proteins thereby achieving unique combination of functional properties. In this case it is necessary to consider both the desired functional properties and the means of assembling the protein components so as to maintain these properties. In all cases it is necessary to have the cloned gene segments, appropriate vectors and expression systems.

Therapeutic human antibodies derived from PCR amplification of B-cell variable regions

Despite advances in the in vitro immunization of human B cells (Borrebaeck et al. 1988) and the development of immunodeficient mice (McCune et al. 1988) for the reconstitution of the human immune system ex vivo, immortalization of antigen-specific human B cells remains the limiting step in the generation of human monoclonal antibodies. Typically this is performed with the aid of Epstein-Barr virus transformation followed by subcloning, confirmation of antigen binding and hybridization of the B lymphoblasts to a suitable fusion partner such as GLI-H7. This general approach is effective and widely used; however, it is time-consuming with erratic results. These were the immediate reasons we and others devised methods to directly obtain the variable regions from small numbers of human B cells (Larrick et al. 1987). The success of the PCR-based approach is illustrated above. In the present studies we successfully captured and stably produced antibodies from the V regions of two potent human anti-tetanus antibodies secreted by heteromyelomas that were too unstable for scale-up production. Although further preclinical evaluation of these antibodies is in progress, results to date indicate that the recombinant antibodies produced in myeloma-based cell lines or CHO cells are equivalent in binding specificity and activity to the native heteromyeloma-derived antibodies. Recent studies from this laboratory indicate that effective anti-tetanus protection will require a cocktail of anti-tetanus antibodies. Details of this work will be the subject of a future communication (Lang et al., in preparation).