Development of a Bicistronic Anti-CD19/CD20 CAR Construct Including Optimization to Abrogate Retroviral Recombination Events

Anti-CD19 chimeric antigen receptor (CAR) T cells can eliminate lymphoma, but CD19 loss from lymphoma can cause anti-CD19 CAR T-cell treatment failure. To address CD19 loss, we designed a bicistronic construct encoding 2 CARs. The first CAR in the bicistronic construct was the anti-CD19 CAR Hu19-CD828Z, which incorporated a human anti-CD19 single-chain variable fragment (scFv) along with CD28 and CD3ζ domains (Brudno et al. Nature Medicine 2020). The 2nd CAR in the construct was a novel anti-CD20 CAR incorporating a human anti-CD20 scFv, plus 4-1BB and CD3ζ domains. This bicistronic CAR construct, designated Hu1928-Hu20BB-original, was encoded by the mouse stem cell virus-based splice-gag (MSGV1) gamma-retroviral vector. Repeated segments of identical DNA sequence can lead to recombination events when retroviral vectors are utilized. Recombination events driven by repeated identical nucleotide segments can occur during retroviral vector production in packaging cells. Recombination events can also occur in transduced T cells during reverse transcription when repeated segments of identical nucleotides on the same nucleotide strand anneal, which leads to strand switching by the reverse transcriptase enzyme and deletion of part of the sequence. We assessed T cells transduced with Hu1928-Hu20BB-original for evidence of recombination. Southern blots of DNA from T cells transduced with Hu1928-Hu20BB-original showed a dominant band of the expected CAR transgene length and no aberrant bands after 21 hours of exposure; however, with extended exposure of 8 days, an unexpected band indicating shorter transgene length became visible. This aberrant band was consistent with deletion of part of the transgene sequence due to recombination. To investigate possible recombination by a more sensitive method, we assessed RNA from transduced T cells by single-molecule real-time RNA sequencing (SMRT-RNAseq, PacBio). Deletions of Hu1928-Hu20BB-original RNA sequence between segments of identical sequence were detected by SMRT-RNAseq. These findings were consistent with recombination. The most common recombination events were between the CD8α hinge and transmembrane (HT) domains of the 2 CARs of Hu1928-Hu20BB-original. These HT domains shared regions of identical nucleic acid sequence. Less commonly, recombination events occurred between segments of identical sequence shared by the heavy-chain domains and the light-chain domains of the two CARs in the construct. The attached table summarizes deletions consistent with recombination in Hu1928-Hu20BB-original RNA from transduced T cells of one patient. Similar results were obtained in T cells of 3 other patients. We confirmed deletions consistent with recombination in CAR RNA transcripts by short-read RNA sequencing (Illumina). Digital droplet PCR analysis of DNA from transduced T cells showed that recombination events between the HT domains of Hu1928-Hu20BB-original were present in DNA of transduced T cells. We modified the DNA sequence of Hu1928-Hu20BB-original to reduce repeated segments of identical DNA sequence to form a new CAR designated Hu1928-Hu20BB-standard. When T cells transduced with Hu1928-Hu20BB-standard were studied by SMRT RNAseq, deletions of RNA sequence consistent with recombination were substantially reduced (Table). We modified Hu1928-Hu20BB-standard by lengthening the linker in the anti-CD20 scFv to form a construct designated Hu1928-Hu20BB-long. We compared Hu1928-Hu20BB-standard to Hu1928-Hu20BB-long in vitro, and both specifically recognized CD19 and CD20 in assays of degranulation, cytokine release, and proliferation. In vitro assays showed higher interleukin-2 release by T cells transduced with Hu1928-Hu20BB-long versus Hu1928-Hu20BB-standard in response to 3 different CD20+ target cells (P value range 0.001 to 0.036). We tested Hu1928-Hu20BB-long against tumors established in nod-scid common gamma-chain knockout (NSG) mice. Human T cells expressing Hu1928-Hu20BB-long eliminated tumors of the following tumor cell lines: st486 (CD19+, CD20+), st486-CD19-negative (CD20+, CD19 low to negative expression), and NALM6 (CD19+, CD20 low expression). One million Hu1928-Hu20BB-long T cells per mouse eradicated st486 tumors. These optimized anti-CD19/CD20 bicistronic CAR constructs are promising for clinical treatment of B-cell malignancies. Figure 1 Figure 1. Disclosures Lam: Kite, a Gilead Company: Patents & Royalties. Kochenderfer: Bristol Myers Squibb: Research Funding; Kite, a Gilead Company: Patents & Royalties: on anti-CD19 CARs, Research Funding.

Investigating Optimal Autologous Cellular Platforms for Prenatal or Perinatal Factor VIII Delivery to Treat Hemophilia A

Patients with the severe form of hemophilia A (HA) present with a severe phenotype, and can suffer from life-threatening, spontaneous hemorrhaging. While prophylactic FVIII infusions have revolutionized the clinical management of HA, this treatment is short-lived, expensive, and it is not available to many A patients worldwide. In the present study, we evaluated a panel of readily available cell types for their suitability as cellular vehicles to deliver long-lasting FVIII replacement following transduction with a retroviral vector encoding a B domain-deleted human F8 transgene. Given the immune hurdles that currently plague factor replacement therapy, we focused our investigation on cell types that we deemed to be most relevant to either prenatal or very early postnatal treatment and that could, ideally, be autologously derived. Our findings identify several promising candidates for use as cell-based FVIII delivery vehicles and lay the groundwork for future mechanistic studies to delineate bottlenecks to efficient production and secretion of FVIII following genetic-modification.

Single vector multiplexed shRNA provides a non-gene edited strategy to concurrently knockdown the expression of multiple genes in CAR T cells.

3103 Background: Engineered T cells expressing chimeric antigen receptors (CAR) are now delivering clinically relevant results in patients with advanced hematological malignancies. One critical area for future development is to modulate gene expression thereby endowing the engineered T cell with specific desired features that enhance anti-tumor activity. Methods: Short-hairpin RNA (shRNA) were cloned individually or multiplexed within micro-RNA scaffolds that enabled the co-expression of the individual shRNA with a CAR and a selectable marker all driven by a PolII promoter within a single retroviral vector. Primary human T cells transduced with the CAR-shRNA vectors were selected, expanded in vitro, subjected to negative selection to eliminate any remaining TCR+ cells and examined for target gene expression and functional activity. Results: A 500bp DNA fragment incorporating a shRNA-specific for CD3ζ cloned into a retroviral vectoreffectively knocked down expression of CD3ζ in transduced BCMA-specific CAR T cells. The consequent reduction of cell surface TCR expression resulted in minimal cytokine production upon TCR stimulation in vitro providing a potential allogeneic CAR T approach. These CAR T cells showed no demonstrable evidence of GvHD induction when infused in NSG mice yet maintained BCMA-specific CAR activity in KMS-11 and RPMI-8226 established myeloma models. Initial studies further confirmed that two shRNA could be expressed from a single retroviral vector to modulate the expression of multiple genes. Further engineering of the microRNA framework reduced the size of the transgene load to 394bp while enabling the expression of up to 4 shRNA within a single vector. shRNA specific for CD3ζ, beta-2-microglobulin, CD52 and diacylglycerol kinase alpha were engineered into the framework downstream of a CD19-CAR. Transduced Jurkat cells showed concurrent knockdown of the respective gene products at the mRNA and protein levels. Conclusions: A first-in-human clinical trial evaluating the first-generation single shRNA-vector in the context of a BCMA-targeting CAR as a non-gene edited approach to allogeneic CAR T cell therapy will be initiated in 2020. The proof of principle study here shows that multiple shRNAs are active within a single viral vector thereby avoiding the need for bespoke individual clinical reagents to target multiple genes. The multiplexed shRNA vector system is now in further development to explore whether this strategy can enhance the therapeutic potential of CAR T cells.