ALBERT

Description: In gene therapy with human hematopoietic stem and progenitor cells (HSPCs), each gene-corrected cell and its progeny are marked in a unique way by the integrating vector. This feature enables lineages to be tracked by sampling blood cells and using DNA sequencing to identify the vector integration sites. Here, we studied 5 cell lineages (granulocytes, monocytes, T cells, B cells, and natural killer cells) in patients having undergone HSPC gene therapy for Wiskott-Aldrich syndrome or β hemoglobinopathies. We found that the estimated minimum number of active, repopulating HSPCs (which ranged from 2000 to 50 000) was correlated with the number of HSPCs per kilogram infused. We sought to quantify the lineage output and dynamics of gene-modified clones; this is usually challenging because of sparse sampling of the various cell types during the analytical procedure, contamination during cell isolation, and different levels of vector marking in the various lineages. We therefore measured the residual contamination and corrected our statistical models accordingly to provide a rigorous analysis of the HSPC lineage output. A cluster analysis of the HSPC lineage output highlighted the existence of several stable, distinct differentiation programs, including myeloid-dominant, lymphoid-dominant, and balanced cell subsets. Our study evidenced the heterogeneous nature of the cell lineage output from HSPCs and provided methods for analyzing these complex data.

Description: T cells bearing a second-generation anti-CD19 chimeric antigen receptor (CAR) induce complete remission in 〉90% of patients with acute lymphoblastic leukemia (ALL) at our institution. However, disease may recur and we recently identified two molecular mechanisms of relapse (PMID: 26516065). We here present a novel mechanism of antigen-negative relapse in a pediatric ALL patient. A 21 year-old male patient was in third relapse at the time of enrollment onto our CTL019 trial (ClinicalTrials.Gov #NCT01626495). The patient achieved an MRD-negative complete remission 1 month after CTL019 infusion but relapsed nine months later. Quantitative PCR analysis of the transgene and flow cytometry for CAR19 protein analysis showed the expected expansion of the CART cells followed by log-normal decay following disease eradication. At relapse, however, the transgene copy numbers had increased without a concomitant rise in CAR19 protein-expressing T cells. The CAR protein was found to be expressed by the now CD19-negative CD45dimCD10+CD3negCD22+ leukemia. Molecular analysis via next-generation immunoglobulin heavy chain sequencing (NGIS) of the apheresis product, used for CTL019 manufacturing, and relapse marrow at 9 months demonstrated clonal identity of the relapsed clone, which carried two rearranged IgH alleles. Sequencing of the CD19, CD21, CD81, and CD225 loci did not reveal any mutations. The analysis of lentiviral vector integration sites (LVIS) of the infusion product and post-infusion specimens showed the following: a) the infusion product carried over 15,000 unique integration sites; b) only 7 LVIS were shared between this sample and month 9 and 20 relapse specimens, none of which were near proto-oncogenes; c) the relapsed leukemia carried two LVIS, one on chromosome 10, 〉50 kb distal from neuropilin (NRP1) and the second in an intron of proprionyl coenzyme A carboxylase-A (PCCA). Flow cytometric and qRT-PCR analysis of leukemic cells in the apheresis and relapse showed that NRP1 levels were indistinguishable, suggesting that the lentiviral vector did not act as an enhancer for NRP1. Furthermore, qRT-PCR demonstrated that the lentiviral integration did not affect the gene expression levels of PCCA. Investigation into the origins of the leukemic CAR transduction event showed that the patient did not exhibit replication-competent lentivirus. However, NGIS analysis of infusion product revealed the leukemic clonotypes this sample, indicating that the gene transfer occurred during the manufacturing of the CTL019 cells. A retrospective analysis of 115 aphereses from ALL patients showed that the index patient had an unusually high disease burden in the apheresis product with 63% of all cells expressing CD19; at harvest, however, the CTL019 product consisted of 99.21% T cells, highlighting the purging effect of the CD19-specific T cells during manufacturing. NGIS analysis of infusion products of 17 additional ALL patients also identified the leukemic clonotype(s) in 6 more products. Only one additional patient demonstrated CAR19 protein expression on the leukemic cells, and this clone was not dominant at relapse (0.075% of all leukemic cells expressed the CAR). Our investigation into the biology of CAR19-expressing ALL cells showed the following: 1) the in vitro analysis of BBζ-signaling CAR19 showed no evidence of cytokine secretion; 2) the infusion of the baseline leukemia and CAR19-expressing leukemic cells from the same patient in mice did not demonstrate differential pharmacodynamics, even after restimulation with human CD19-expressing murine B cells in vivo; 3) the CD19 protein was detectable using flow cytometry and confocal microscopy, but only with an antibody recognizing an intracellular epitope; 4) importantly, the relapsed clone was indeed resistant to killing by CART19 cells in a xenograft model yet retained sensitivity to anti-CD22 CAR T cells. In conclusion, our data therefore show that a single leukemic cell accidentally transduced with CAR19 survived the 10-day manufacturing process and, upon reinfusion into the patient, was the sole clone at relapse 9 months later. This leukemic clone evaded CTL019 detection via downregulation of the target antigen in a cell-autonomous fashion. Disclosures Lacey: Novartis: Research Funding. Xu:Novartis: Research Funding. Ruella:novartis: Patents & Royalties: Novartis, Research Funding. Barrett:Novartis: Research Funding. Kulikovskaya:Novartis: Research Funding. Ambrose:Novartis: Research Funding. Patel:Novartis: Research Funding. Reich:Novartis: Research Funding. Scholler:Novartis: Patents & Royalties: Royalties, Research Funding. Nazimuddin:Novartis: Research Funding. Fraietta:Novartis: Patents & Royalties: Novartis, Research Funding. Maude:Novartis: Consultancy. Gill:Novartis: Patents & Royalties, Research Funding. Levine:Novartis: Patents & Royalties, Research Funding; GE Healthcare Bio-Sciences: Consultancy. Orlando:Novartis: Employment. Grupp:Jazz Pharmaceuticals: Consultancy; Pfizer: Consultancy; Novartis: Consultancy, Research Funding. June:Tmunity: Equity Ownership, Other: Founder, stockholder ; Pfizer: Honoraria; Immune Design: Consultancy, Equity Ownership; Celldex: Consultancy, Equity Ownership; University of Pennsylvania: Patents & Royalties; Johnson & Johnson: Research Funding; Novartis: Honoraria, Patents & Royalties: Immunology, Research Funding. Melenhorst:Novartis: Patents & Royalties: Novartis, Research Funding.

Description: Background: Autologous T cells genetically modified with a lentiviral vector to express affinity-enhanced T cell receptors (TCR) or chimeric antigen receptors have shown great promise for the treatment of cancer. NY-ESO-1 is a cancer testis antigen with little normal tissue expression but with aberrant expression in MM, sarcomas, and melanomas. An HLA-A201 restricted TCR recognizing the NY-ESO-1/LAGE-1 157-165 epitope (SLLMWITQC) kills NY-ESO positive cell lines and has been used to treat 25 patients with MM after ASCT with expansion, persistence, antigen-directed functionality and long-term safety and antitumor activity (Nat Med 2015, Blood Adv 2019). We hypothesized removal of the genes encoding the endogenous TCR, TCRα (TRAC) and TCRβ (TRBC), would enhance NY-ESO TCR expression and reduce TCR mispairing and with removal of PD-1 (PDCD1) would enhance activity and persistence. We previously demonstrated CRISPR/Cas9 and TCRα, TCRβ and PDCD1 targeting gRNAs could be successfully introduced via electroporation in preclinical models to disrupt gene expression (Clin Cancer Res 2017). We therefore began a phase 1 pilot clinical trial for pts with advanced MM and sarcoma of NY-ESO-1 TCR-expressing T cells with CRISPR/Cas9 TCRα, TCRβ and PDCD1 edited genes to assess safety, feasibility and activity (NCT03399448). Methods: Adults with HLA-A*0201 and expressing NY-ESO-1 and/or LAGE-1 antigen with advanced MM, synovial sarcoma, and myxoid/round cell liposarcoma (MRCL) with adequate performance and organ function and, for MM relapsed or refractory to at least 3 prior regimens and, for MRCL, proven metastatic disease or surgically inoperable local recurrence, were enrolled. Autologous T cells were transfected with Cas9 protein complexed with single guide RNAs against TRAC, TRBC and PDCD1 and subsequently transduced to express NY-ESO-1-specific TCR at the University of Pennsylvania. Frequency of NYCE T cells in final product was measured by flow cytometric dextramer analysis. Once cells were successfully manufactured and released, pts received fludarabine 30mg/m2 and cyclophosphamide 300mg/m2 daily on day -4,-3,-2. On Day 0 pts received a single infusion of thawed NYCE T cells as an out-patient. Pts were monitored closely for the first 28 days, monthly till 6 mo and then followed every 3 mo for adverse events, antitumor response and survival, NYCE T cell expansion, persistence, trafficking, phenotype and function, and immunogenicity. An assessment after accrual of the first 3 subjects in this ongoing trial was planned and is reported here. Results: 3 pts, 2 with MM and 1 with MRCL, have received NYCE T cells. Pt 1 is a 67 y/o F with IgG kappa MM with lytic bone lesions, and a +17q after 8 lines of therapy including 3 ASCTs, lenalidomide, pomalidomide, bortezomib, carfilzomib, daratumumab, and panobinostat. Pt 2 is a 65 y/o M with a recurrent MRCL manifested by abdominal and pelvic involvement after neo-adjuvant doxorubicin, multiple resections and radiation treatments with progression at time of enrollment. Pt 3 is a 62 y/o F with kappa light chain MM with lytic bone lesions and plasmacytomas and a +1q after 7 lines of therapy including lenalidomide, pomalidomide, bortezomib, carfilzomib, daratumumab, 2 ASCTs and an immunoconjugate . Manufacturing for these pts resulted in satisfactory products with 89.4 to 96% viability, transduction efficiency by qPCR of 0.04 to 0.2 copies/cell , residual Cas9 concentration 0 to 0.37 ng/ml, dextramer 0.4 to 1.8% NY-ESO-1 expression. TRAC, TRBC, and PDCD1 disruption efficiency was 44.3 to 49.4, 3.61 to 15.7 and 15.6 to 20.2% respectively. Pts tolerated treatment well without neurotoxicity or CRS. By day +60 pt 1 progressed by IMWG. Pt 2 received 1 U PRBC. By day +90 he remained with stable disease by serial CT scans. Pt 3 is too early to evaluate. Serial qPCR for copies of lentiviral transcripts in peripheral blood and tumor biopsies for pts 1+2 showed in vivo expansion, stable persistence and tumor targeting (Figure). Conclusion: Early results of a phase 1 trial of NYCE T cells infused in 3 pts with advanced MM and MRCL show safety and feasibility and viable, expanding, and persisting CRISPR/Cas9 gene edited T cells that trafficked to tumor. The persistence of the NYCE T cells suggests that immunogenicity from multiplexed gene-editing using Cas9 is minimal under these conditions. Further characterization of phenotype and function of these cells and clinical outcomes will be presented. Figure Disclosures Stadtmauer: Celgene: Consultancy; Takeda: Consultancy; Janssen: Consultancy; Amgen: Consultancy; Novartis: Consultancy, Research Funding; Tmunity: Research Funding; Abbvie: Research Funding. Cohen:Poseida Therapeutics, Inc.: Research Funding. Lacey:Novartis: Patents & Royalties: Patents related to CAR T cell biomarkers; Tmunity: Research Funding; Novartis: Research Funding. Melenhorst:Incyte: Research Funding; Novartis: Research Funding, Speakers Bureau; Parker Institute for Cancer Immunotherapy: Research Funding; Genentech: Speakers Bureau; Stand Up to Cancer: Research Funding; IASO Biotherapeutics, Co: Consultancy; Simcere of America, Inc: Consultancy; Shanghai Unicar Therapy, Co: Consultancy; Colorado Clinical and Translational Sciences Institute: Membership on an entity's Board of Directors or advisory committees; National Institutes of Health: Research Funding. Fraietta:Tmunity: Research Funding; Cabaletta: Research Funding; LEK Consulting: Consultancy. Mangan:amgen: Speakers Bureau; takeda: Speakers Bureau; celgene: Speakers Bureau; janssen: Speakers Bureau. Lancaster:novartis: Research Funding. Suhoski:novartis: Research Funding. Fesnak:Novartis: Research Funding. Young:novartis: Research Funding. Chew:tmunity: Other: Scientific Founder, Research Funding; novartis: Research Funding. Zhao:Tmunity: Membership on an entity's Board of Directors or advisory committees, Research Funding; novartis: Research Funding. Hwang:Novartis: Research Funding; Tmunity: Research Funding. Hexner:novartis: Research Funding. June:Novartis: Research Funding; Tmunity: Other: scientific founder, for which he has founders stock but no income, Patents & Royalties.

Description: The historical model of hematopoiesis, mainly derived from murine studies, is based on the existence of a single hematopoietic stem cell (HSC) capable of generating all blood cell lineages. However this model has been challenged by the proposal of four types of murine HSC, which differ by their relative contribution to the myeloid and lymphoid lineages. Here we have used data from a gene therapy trial to treat Wiskott-Aldrich syndrome (WAS) to explore hematopoiesis in humans. In the trial, the therapeutic vector (lentivirus) integrates into the genome at unique positions in each hematopoietic stem and progenitor cell (HSPC) and is consequently transmitted to all its progeny. Thus hematopoietic ontogeny in humans can be inferred by tracking the appearance of unique integration sites in fractionated blood cell populations. This provides a unique opportunity to model the developmental complexity of the human haematological system. Considerable effort over the last 15 years has been devoted to optimizing retroviral integration sites (RIS) analysis using ligation mediated PCR (LM-PCR), combined with acoustic shearing and high-throughput Illumina sequencing. Acoustic shearing enables more precise quantification of RIS abundance through the enumeration of the various sizes of shear fragments (SonicAbundance) containing a given RIS, which correspond to individual ancestor HSPC and its blood progeny. In four WAS patients treated by gene therapy, we have sorted peripheral blood samples for 5 cell types: myeloid (granulocytes and monocytes) and lymphoid subpopulations (T, B and NK cells), and analysed their RIS profile. Each RIS corresponds to a particular stem/progenitor cell clone, with a particular pattern defined by its presence or absence in each of the 5 lineages. These data are then use to reconstruct aspects of the hematopoietic hierarchy. In order to face the challenging issue of cell sorting contamination we have been using a stringent sort precision mode and we treat residual contamination explicitly in downstream statistical models. Using these approaches, we have characterized up to tens of thousands RIS per patients with a follow up of 4 years. In order to minimize biases due to sparse sampling, we concentrate on the more abundant RIS clones that can be more easily caught and are therefore analysed more reliably. We showed that a significant fraction of RIS clones are detected in a single lineage, while other RIS clones are characterized by different levels of contribution to the myeloid and lymphoid lineages, highlighting the heterogeneity of human HSC. Clones contributing to all 5 lineages are readily recovered but this study also unravels a diversity of inferred hematopoietic programs with various potentials contributing to human blood homeostasis. Longitudinal analysis of clonal dynamics is ongoing, with preliminary results highlighting the maintenance of this heterogeneity of HSPC over time. These new findings provide unique data on human hematopoiesis based on gene corrected WAS patients. Disclosures No relevant conflicts of interest to declare.

Description: CD19-specific Chimeric Antigen Receptor (CTL019)-engineered T-cells provide a breakthrough for personalized cancer therapy. An anti-CD19 CAR gene with 41BB costimulatory domain is delivered into patient T-cells ex vivo using a lentiviral vector, expanded in culture and then reinfused into patients. While dramatically successful for some treatment-refractory cancers, a significant proportion of patients do not experience therapeutic levels of CAR T cell expansion - thus it is important to investigate factors driving successful expansion in responders in more detail. Here we have analyzed sites of lentiviral vector integration in CAR T cells from trials to ALL and CLL, comparing successful and unsuccessful therapy in longitudinal data sets for 40 subjects. The location of each integrated vector marks a cell lineage uniquely allowing the fate mapping of individual CAR-engineered T cells in the infusion product and after adoptive transfer. We found that 81.4% of integrations had occurred in annotated transcription units which is consistent with previous reports for lentiviral vector integration sites. Relatively larger and more diverse populations of CAR-modified T-cells were associated with improved outcome (Chao1 index, p=0.043). Population sizes were also significantly more diverse in the infusion product compared with day 28 post-infusion, and more diverse at this time point when comparing responders with non-responders, or even partial responders with non-responders (p

Description: We recently demonstrated that sustained remission in 41 CLL patients treated with the CD19-specific, 4-1BB/CD3zeta-signaling chimeric antigen receptor (CAR19) T-cells correlated strongly with the expansion and persistence of the engineered T cells and that important pathways such as T cell exhaustion, glycolysis and T cell differentiation segregated responders from non-responders (Fraietta et al., 2018, Nature Medicine). We here report two advanced, chemotherapy-resistant CLL patients with the longest (7 years) follow-up on any trial of CART19 cells. Both patients had received five therapies before being treated at the University of Pennsylvania with autologous, murine CTL019 (tisagenlecleucel) cells for their CLL in 2010, receiving 1.1e9 and 1.4e7 CAR19+ T cells, respectively. Both patients have persistence of CAR-engineered T cells and both patients are still in remission as determined by flow cytometry and deep sequencing of IgH rearrangements for 5.5-7 years. Thus, the infused CAR-T cells have maintained these patients in deep molecular remission of their disease for the longest period of time that has been reported to date. To understand the fate of the infused CAR-T cells we determined the phenotype, function, and clonal nature of the persisting CTL019 cells. Flow cytometric CART19 cell analyses demonstrated that early during the anti-leukemia response, activated, HLA-DR-expressing CD8+ CAR-T cells rapidly expanded, followed by similarly activated CD4+ CAR-T cells. With tumor clearance the CAR-T cell population contracted, but an activated CD4+ CAR-T cell population was maintained and was still detectable at the last follow-up of 7 years. The CD8+ CAR-T cell pool remained present at low frequencies. Both populations had acquired and maintained an effector memory phenotype, a phenotype most consistent with active disease control. Furthermore, the analysis of the classical immune checkpoint inhibitory markers PD1, TIM3, LAG3, and CTLA4 showed that only PD1 was expressed from the earliest to the latest time point on 〉80% of all CAR-T cells, whereas LAG3 and TIM3 were expressed only early on but lost after tumor clearance. These data suggest that the initial tumor clearance was mediated by CD8+ CAR-T cells, but sustained by a CD4+ CAR-T cell population that still actively engages with target cells. To understand the clonal nature of these long-term persisting CAR-T cells we used two complementary methods: a) CAR T cells were sorted from post-infusion aliquots during the first two years for T cell receptor-beta deep-sequencing (TCR-seq); b) the CAR integration sites in the genome were sequenced in the infusion product and in circulating CAR-T cells. TCR-seq analysis of early post-infusion time points demonstrated that the circulating CAR-T cell populations consisted of hundreds to thousands of distinct clones which in patient 1 and 2 displayed clonal focusing by 21 and 1 month post-infusion, respectively, with some clones making up as much as 12% (patient 1) and 48% (patient 2) of the CAR-T cell repertoire. The analysis of clonotype sharing at the various time points via Morisita's overlap index analysis similarly showed repertoire stabilization late (21 months; patient 1) and early (1 month; patient 2) after infusion. Lastly, fate mapping of the infused CART19 cells via CAR integration site analysis in the infusion product until the latest time point indicated that the infusion products for both patients had a very diverse, non-clonal make-up, containing over 8,000 and 3,700 integration sites in patients 1 and 2, respectively. The higher degree of clonality in patient 2 but not 1 CAR-T cells as seen by TCR-seq was confirmed by integration site analysis, as was the sharing of CAR-T cell clones over time. Importantly, whereas the CAR integration site repertoire in patient 1 was diverse in the first two years, it stabilized and trended towards oligoclonality 21 months after infusion. Lastly, CAR integration site analysis revealed a high degree of clonal persistence, suggesting that tumor control and B cell aplasia were maintained by few, highly functional CD4+ CAR-T cell clones. In summary, we demonstrate that in both patients with the longest persistence of CAR-T cells reported thus far, early and late phases of the anti-CLL response are dominated by highly activated CD8+ and CD4+ CAR-T cells, respectively, largely comprised of a small number of persisting CD4+ CAR-T cell clones. Disclosures Melenhorst: Parker Institute for Cancer Immunotherapy: Research Funding; Incyte: Research Funding; Casi Pharmaceuticals: Consultancy; novartis: Patents & Royalties, Research Funding; Shanghai UNICAR Therapy, Inc: Consultancy. Porter:Genentech: Other: Spouse employment; Novartis: Other: Advisory board, Patents & Royalties, Research Funding; Kite Pharma: Other: Advisory board. Lacey:Novartis Pharmaceuticals Corporation: Research Funding; Tmunity: Research Funding; Novartis Pharmaceuticals Corporation: Patents & Royalties; Parker Foundation: Research Funding. Fraietta:Novartis: Patents & Royalties: WO/2015/157252, WO/2016/164580, WO/2017/049166. Frey:Novartis: Consultancy; Servier Consultancy: Consultancy. Young:Novartis: Patents & Royalties, Research Funding. Siegel:Novartis: Research Funding. June:Novartis Pharmaceutical Corporation: Patents & Royalties, Research Funding; Immune Design: Membership on an entity's Board of Directors or advisory committees; Tmunity Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding; Immune Design: Membership on an entity's Board of Directors or advisory committees; Celldex: Consultancy, Membership on an entity's Board of Directors or advisory committees; Novartis Pharmaceutical Corporation: Patents & Royalties, Research Funding; Tmunity Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding.