Cas-CLOVER is a novel high-fidelity nuclease for safe and robust generation of TSCM-enriched allogeneic CAR-T cells.

The use of T cells from healthy donors for allogeneic chimeric antigen receptor T (CAR-T) cell cancer therapy is attractive because healthy donor T cells can produce versatile off-the-shelf CAR-T treatments. To maximize safety and durability of allogeneic products, the endogenous T cell receptor and major histocompatibility complex class I molecules are often removed via knockout of T cell receptor beta constant (TRBC) (or T cell receptor alpha constant [TRAC]) and B2M, respectively. However, gene editing tools (e.g., CRISPR-Cas9) can display poor fidelity, which may result in dangerous off-target mutations. Additionally, many gene editing technologies require T cell activation, resulting in a low percentage of desirable stem cell memory T cells (TSCM). We characterize an RNA-guided endonuclease, called Cas-CLOVER, consisting of the Clo051 nuclease domain fused with catalytically dead Cas9. In primary T cells from multiple donors, we find that Cas-CLOVER is a high-fidelity site-specific nuclease, with low off-target activity. Notably, Cas-CLOVER yields efficient multiplexed gene editing in resting T cells. In conjunction with the piggyBac transposon for delivery of a CAR transgene against the B cell maturation antigen (BCMA), we produce allogeneic CAR-T cells composed of high percentages of TSCM cells and possessing potent in vivo anti-tumor cytotoxicity.

ADAMTS13 autoantibodies cloned from patients with acquired thrombotic thrombocytopenic purpura: 1. Structural and functional characterization in vitro.

BACKGROUND: Acquired thrombotic thrombocytopenia purpura (TTP) is a life-threatening illness caused by autoantibodies that decrease the activity of ADAMTS13, the von Willebrand factor-cleaving protease. Despite efficacy of plasma exchange, mortality remains high and relapse is common. Improved therapies may come from understanding the diversity of pathogenic autoantibodies on a molecular or genetic level. Cloning comprehensive repertoires of patient autoantibodies can provide the necessary tools for studying immunobiology of disease and developing animal models. STUDY DESIGN AND METHODS: Anti-ADAMTS13 antibodies were cloned from four patients with acquired TTP using phage display and characterized with respect to genetic origin, inhibition of ADAMTS13 proteolytic activity, and epitope specificity. Anti-idiotypic antisera raised to a subset of autoantibodies enabled comparison of their relatedness to each other and to polyclonal immunoglobulin (Ig)G in patient plasma. RESULTS: Fifty-one unique antibodies were isolated comprising epitope specificities resembling the diversity found in circulating patient IgG. Antibodies directed both to the amino terminal domains and to those requiring the ADAMTS13 cysteine-rich/spacer region for binding inhibited proteolytic activity, while those solely targeting carboxy-terminal domains were noninhibitory. Anti-idiotypic antisera raised to a subset of antibody clones crossreacted with and reduced the inhibitory activity of polyclonal IgG from a set of unrelated patients. CONCLUSIONS: Anti-ADAMTS13 autoantibodies isolated by repertoire cloning display the diversity of epitope specificities found in patient plasma and provide tools for developing animal models of acquired TTP. Shared idiotypes of inhibitory clones with circulating IgG from multiple patients suggest common features of pathogenic autoantibodies that could be exploited for developing more targeted therapies.

L1 retrotransposition occurs mainly in embryogenesis and creates somatic mosaicism.

Long Interspersed Element 1 (L1) is a retrotransposon that comprises approximately 17% of the human genome. Despite its abundance in mammalian genomes, relatively little is understood about L1 retrotransposition in vivo. To study the timing and tissue specificity of retrotransposition, we created transgenic mouse and rat models containing human or mouse L1 elements controlled by their endogenous promoters. Here, we demonstrate abundant L1 RNA in both germ cells and embryos. However, the integration events usually occur in embryogenesis rather than in germ cells and are not heritable. We further demonstrate L1 RNA in preimplantation embryos lacking the L1 transgene and L1 somatic retrotransposition events in blastocysts and adults lacking the transgene. Together, these data indicate that L1 RNA transcribed in male or female germ cells can be carried over through fertilization and integrate during embryogenesis, an interesting example of heritability of RNA independent of its encoding DNA. Thus, L1 creates somatic mosaicism during mammalian development, suggesting a role for L1 in carcinogenesis and other disease.