V-region and class specific RT-PCR amplification of human immunoglobulin heavy and light chain genes from B-cell lines

Specific Targeting of Lymphoma Cells Using Semisynthetic Anti-Idiotype Shark Antibodies

The B-cell receptor (BCR) is a key player of the adaptive immune system. It is a unique part of immunoglobulin (Ig) molecules expressed on the surface of B cells. In case of many B-cell lymphomas, the tumor cells express a tumor-specific and functionally active BCR, also known as idiotype. Utilizing the idiotype as target for lymphoma therapy has emerged to be demanding since the idiotype differs from patient to patient. Previous studies have shown that shark-derived antibody domains (vNARs) isolated from a semi-synthetic CDR3-randomized library allow for the rapid generation of anti-idiotype binders. In this study, we evaluated the potential of generating patient-specific binders against the idiotype of lymphomas. To this end, the BCRs of three different lymphoma cell lines SUP-B8, Daudi, and IM-9 were identified, the variable domains were reformatted and the resulting monoclonal antibodies produced. The SUP-B8 BCR served as antigen in fluorescence-activated cell sorting (FACS)-based screening of the yeast-displayed vNAR libraries which resulted after three rounds of screening in the enrichment of antigen-binding vNARs. Five vNARs were expressed as Fc fusion proteins and consequently analyzed for their binding to soluble antigen using biolayer interferometry (BLI) revealing binding constants in the lower single-digit nanomolar range. These variants showed specific binding to the parental SUP-B8 cell line confirming a similar folding of the recombinantly expressed proteins compared with the native cell surface-presented BCR. First initial experiments to utilize the generated vNAR-Fc variants for BCR-clustering to induce apoptosis or ADCC/ADCP did not result in a significant decrease of cell viability. Here, we report an alternative approach for a personalized B-cell lymphoma therapy based on the construction of vNAR-Fc antibody-drug conjugates to enable specific killing of malignant B cells, which may widen the therapeutic window for B-cell lymphoma therapy.

Efficient construct of a large and functional scFv yeast display library derived from the ascites B cells of ovarian cancer patients by three-fragment transformation-associated recombination

Over the past decade, yeast display technology has emerged as a powerful tool for the isolation of high-affinity immunoglobulin fragments with potential utility as clinical diagnostic and therapeutic reagents. Despite significant refinement of the various methodologies underpinning library construction and selections, certain aspects remain challenging and process limiting. We have sought to significantly improve the robustness of the single-chain Fv (scFv) library construction step by overcoming the technical inefficiencies frequently encountered during the PCR-mediated assembly of scFvs from the discrete heavy and light V-domain repertoires. Using a novel primer set designed to provide maximum amplification coverage of the known germ-line V-domain repertoire, we have exploited the potential of the in vivo homologous gap-repair apparatus of Saccharomyces cerevisiae to assemble intact scFvs directly from co-transformed PBMC-derived VH, VL, and linearized vector component fragments. We have successfully applied this three-fragment assembly strategy to construct a large (>10(9)) scFv yeast display library from the ascites immune repertoire of ovarian cancer patients and validated the approach by applying FACS-based sorting to readily isolate scFvs that recognize various tumor marker antigens (TMAs). It is expected that this simplified construction method may find general utility, both for de novo scFv library construction and for subsequent combinatorial affinity maturation manipulations that require more than two fragments.

Humanization and epitope mapping of the H23 anti-MUC1 monoclonal antibody reveals a dual epitope specificity

The tumor-associated antigen MUC1 is a cell surface mucin that is expressed on the apical surface of most glandular epithelial cells, including the ducts of the breast, ovary, pancrease, lung and colon. During malignancy, epithelial tissues regularly display elevated levels of MUC1 in a non-polar fashion and in an underglycosylated form, exposing cryptic peptide and carbohydrate epitopes. As such, MUC1 is regarded a potential target for immunotherapeutical intervention. Murine monoclonal H23 antibody specifically recognizes a MUC1 epitope on the surface of human breast cancer cells. We describe the cloning of the variable domains of H23 and their expression in (Escherichia coli) E. coli as maltose-binding protein-scFv (MBP-scFv) fusions. We humanized H23 and evaluated the binding properties of the murine and the humanized recombinant forms, which were similar in affinity and specificity, but lower in apparent affinity in comparison to the original monoclonal IgG. We mapped the epitope of humanized H23 by affinity-selecting a phage-displayed random peptide library on humanized H23 scFv-displaying bacteria. Our results show that humanized H23 binds an epitope corresponding to the MUC1 tandem repeat and an additional epitope not related to MUC1. These epitopes are competitive, bound with similar affinities and are recognized by the original murine H23 monoclonal antibody as well.

Translocations into human chromosome 14 JH region: factors influencing downstream abortive immunoglobulin class switching

Bcl-2 translocations in follicular lymphomas (FL) are often associated with downstream immunoglobulin class switch recombination (CSR) on the translocated allele. We studied cell lines with different translocations into the IgH locus to gauge any common features associated with downstream CSR events. CSR associated with chromosomal rearrangements was observed in cells (RL) with translocations similar to those frequently observed in FL (bcl-2-JH), and such CSR was also seen with a myc (near exon 1)-JH5 intron translocation (MC116), but not for far 5'-myc-JH5 intron (P3HR-1) or myc-Smu translocations (Ramos). Both MC116 and P3HR-1 myc translocations showed evidence for an origin from somatic hypermutation. Therefore, the association of JH translocations with CSR on the translocated allele is unlikely to be linked with specific translocation mechanisms, and the P3HR-1 configuration indicated that the downstream class switching is not a necessary consequence of (or precondition for) such a translocation event. MC116 and RL, but not P3HR-1 cells, showed constitutive transcription through the translocated IgH alleles, suggesting that transcription through this region or the processing of such transcripts may promote CSR. However, while CSR events clearly occurred in the precursors of MC116 and RL, neither cell line could undergo complete class switching.

A partially humanized monoclonal antibody to human IFN-gamma inhibits cytokine effects both in vitro and in vivo

The mouse monoclonal antibody (MoAb) IGMB17 (muIGMB17) is a high-affinity antibody- neutralizing human interferon (IFN)-gamma and, accordingly, is a potential therapeutic agent for patients suffering from various diseases in which the cytokine is abnormally expressed. The clinical usefulness of mouse antibodies is limited, however, owing to their immunogenicity in humans. MuIGMB17 antibody was partially humanized by engrafting a small portion of mouse light chain (LC) in a human framework and by engineering its heavy chain (HC) in a chimeric version. The engineered IGMB17 (huIGMB17) was able to replicate a range of functional properties of the original muIGMB17, namely, specific binding to IFN-gamma, inhibition of histocompatibility complex (HLA-DR) expression in response to IFN-gamma induction, reversion of IFN-gamma antiproliferative activity on sensitive cell lines. We have hypothesized that as huIGMB17 was able to block IFN-gamma binding to its receptor as well as its murine counterpart, huIGMB17 could neutralize all cytokine activity, also in vivo. Indeed huIGMB17 was capable of interfering with delayed-type hypersensitivity reaction in humans, thus demonstrating its effectiveness in neutralizing IFN-gamma-mediated reactions in vivo.

Demonstration of light chain restricted clonal B-lymphoid infiltrates in archival bone marrow trephines by quantitative real-time polymerase chain reaction

Assessment of clonality either by demonstrating light chain restriction or showing monoclonal immunoglobulin gene rearrangement is a valuable and indispensable adjunct to diagnosis in hematopathology. The study of light chain restriction by immunohistochemistry on archival material is hampered by a very low sensitivity especially regarding low grade lymphomas of B cell origin. DNA rearrangement studies of the immunoglobulin locus do improve sensitivity markedly but for lymphomas of follicle center origin they are prone to false negative results due to hypermutations. Therefore we developed a new clonality assay based on the quantification of immunoglobulin light chain transcripts using real-time polymerase chain reaction technology, which is also suitable for the analysis of archival bone marrow trephines. We tested the reproducibility and sensitivity of this approach by comparatively analyzing a series of bone marrow trephines with multiple myeloma (n = 26), reactive lymphoid hyperplasia (n = 37), and focal infiltration by low grade B cell lymphoma (n = 29). We could raise the detection rate of clonality from an average of 17% by immunohistochemistry and 66% as assessed by polymerase chain reaction rearrangement studies to 83% by this new technique. Despite false negative results due to light chain hypermutation in some cases, the detection rate of clonality could be improved even for B cell lymphomas of follicle center origin (follicular lymphoma or marginal zone lymphoma) thus making this novel approach a valuable additional tool for the hematopathologist.

A definitive set of oligonucleotide primers for amplifying human V regions

BACKGROUND

The creation of large diverse phage antibody libraries from natural sources relies on primers which are able to amplify as many V genes as possible. All functional germline V genes have recently been catalogued in a database, V BASE [1]. Previously published primer sets are unable to recognise all these V genes.

OBJECTIVES

The design of a human primer set able to recognise all functional human V genes which can be used to create diverse phage antibody libraries.

STUDY DESIGN

A new set of primers able to recognise all functional V genes were designed using the following criteria: at least 16 bp homology of the 3' end of the primer to the V gene, no more than 8-fold total degeneracy and minimum primer dimer formation. These primers were tested in all possible combinations in PCR using cDNA from human peripheral blood lymphocytes or from human cord blood lymphocytes.

RESULTS

By computer analysis, all V genes in V BASE could be amplified using this primer set. This theoretical result was tested practically by PCR and all primer pairs were shown to be functional, producing PCR products of the expected size. The intensity of the PCR products reflected information available on the expression of the different V gene families recognised and their expression in these two different V gene sources.

CONCLUSIONS

This new primer set will facilitate the creation of more diverse phage antibody libraries than has been hitherto possible using presently available primer sets.

Humanization of an antibody recognizing a breast cancer specific epitope by CDR-grafting

BACKGROUND

Muc1-H23 is a cell surface mucin that is expressed on normal breast luminal epithelial cells and over-expressed in most breast tumors. In addition, Muc-1 expressed by malignant cells is glycosylated differently than Muc-1 expressed by normal cells. This difference in glycosylation exposes a peptide epitope on malignant cells which is not exposed on normal cells. Murine monoclonal antibody H23 recognizes this epitope and stains 91% of breast cancers, but only 1/56 non-malignant breast tissue samples.

OBJECTIVE

To create a human antibody that was equivalent to H23 for potential uses in imaging and/or the therapy of breast cancer.

STUDY DESIGN

We decided to humanize H23 by CDR-grafting using overlap PCR, and to this end, designed and constructed a bacterial expression vector that would allow V-regions, cloned via unique restriction sites, to be expressed as Fab fragments. In this way, we hoped to be able to rapidly evaluate Fab constructs for binding to Muc-1 and to cells and tissue sections that expressed the antigen.

RESULTS

A fully humanized Fab fragment was able to bind Muc-1 peptide, as well as breast cancer cells known to express the epitope and tissue sections, generally showing the same reactivity as the native antibody. In addition, an analysis of sFab expressed with a [His]6 tag preceded by a factor Xa proteolytic cleavage site suggested that E. coli periplasmic signal peptidase was able to cleave the factor Xa site, thereby removing the [His]6 tag.

CONCLUSION

We have generated a human antibody that is capable of recognizing a tumor specific epitope expressed by 91% of breast cancers.