Mitchell H. Finer

Functional transplant of megabase human immunoglobulin loci recapitulates human antibody response in mice

We constructed two megabase-sized YACs containing large contiguous fragments of the human heavy and kappa (κ) light chain immunoglobulin (Ig) loci in nearly germline configuration, including approximately 66 VH and 32 Vκ genes. We introduced these YACs into Ig-inactivated mice and observed human antibody production which closely resembled that seen in humans in all respects, including gene rearrangement, assembly, and repertoire. Diverse Ig gene usage together with somatic hypermutation enables the mice to generate high affinity fully human antibodies to multiple antigens, including human proteins. Our results underscore the importance of the large Ig fragments with multiple V genes for restoration of a normal humoral immune response. These mice are likely to be a valuable tool for the generation of therapeutic antibodies.

Anti-Tumor Activity of Human T Cells Expressing the CC49-zeta Chimeric Immune Receptor

A chimeric immune receptor consisting of an extracellular antigen-binding domain derived from the CC49 humanized single-chain antibody, linked to the CD3zeta signaling domain of the T cell receptor, was generated (CC49-zeta). This receptor binds to TAG-72, a mucin antigen expressed by most human adenocarcinomas. CC49-zeta was expressed in CD4+ and CD8+ T cells and induced cytokine production on stimulation. Human T cells expressing CC49-zeta recognized and killed tumor cell lines and primary tumor cells expressing TAG-72. CC49-zeta T cells did not mediate bystander killing of TAG-72-negative cells. In addition, CC49-zeta T cells not only killed FasL-positive tumor cells in vitro and in vivo, but also survived in their presence, and were immunoprotective in intraperitoneal and subcutaneous murine tumor xenograft models with TAG-72-positive human tumor cells. Finally, receptor-positive T cells were still effective in killing TAG-72-positive targets in the presence of physiological levels of soluble TAG-72, and did not induce killing of TAG-72-negative cells under the same conditions. This approach is being currently being utilized in a phase I clinical trial for the treatment of colon cancer.

T-cell killing of heterogenous tumor or viral targets with bispecific chimeric immune receptors

We have previously described several novel chimeric immune receptors (CIRs) that redirect human T cells to kill malignant or HIV-infected cells. These CIRs comprise a cancer- or virus-specific ligand or single-chain antibody fused to the signaling domain of the T-cell receptor CD3-ζ subunit. Binding of the ligand- or antibody-based CIR to the target antigen (Ag) triggers T-cell-mediated cytolysis of the tumor- or virus-infected cell independent of target cell major histocompatibility complex class I expression. A new type of CIR was developed to mediate the lysis of cells that expressed one or more distinct viral or tumor Ags; three bispecific CIRs (BCIRs) were generated that recognized the carcinoembryonic Ag (CEA) and TAG-72 tumor Ags or, alternatively, distinct epitopes in the HIV envelope (HIVenv). T cells expressing the antitumoral Ag BCIR lysed both CEA- and TAG-72-expressing targets and did not kill Ag-negative targets or target cells expressing other members of the CEA family. Similarly, T cells expressing the anti-HIVenv BCIR lysed target cells expressing both the wild-type HIVenv and a mutant HIVenv that lacked the epitopes recognized by the monospecific CIRs. This approach permits the generation of T cells with a broader spectrum of activity capable of killing virus-infected cells and malignant cells and reduces the potential of progression of disease due to Ag loss variants.

Hybrid yeast-bacteria cloning system used to capture and modify adenoviral and nonviral genomes.

Adenoviral vectors are widely used to express transgenes in vitro and in vivo. A major obstacle to the generation of adenoviral vectors is the manipulation of the large (35 kb) adenoviral genome. We developed a hybrid yeast-bacteria cloning system for the creation of novel adenoviral vectors. The adenovirus 5 (Ad5) genome was cloned into a shuttle vector that contains both yeast and bacterial elements for replication and therefore functions as both a yeast artificial plasmid (YAP) and as a plasmid artificial chromosome (PAC). Any sequence can be introduced into any region of the adenoviral genome via the highly efficient homologous recombination in yeast and then these recombinants are rapidly amplified in bacteria. Adenoviral vectors are generated by introduction of the PAC into the appropriate complementing mammalian cell without the need for plaque purification. Vectors were constructed with deletions in the E1, E3, and/or E4 regions. We have generated more than 100 vectors with a number of different transgenes and regulatory elements. In addition, the YAP/PAC vector was used to capture a DNA fragment encompassing the human factor IX gene, demonstrating the utility of this system to clone and analyze genomic DNA. This novel cloning strategy allows the rapid and versatile construction of adenoviral vectors for gene expression and gene therapy applications.