Francesca Dionisio

In vivo tracking of T cells in humans unveils decade-long survival and activity of genetically modified T memory stem cells

Genetically engineered T memory stem cells preserve differentiation activity for decades after patient infusion. Sealing T cell fate Clinical trials are a relatively untapped source of experimental data that can be leveraged to explore both basic and pathological biology in humans. Now, Biasco et al. take advantage of two different gene therapy trials for inherited immunodeficiency to track in the long term T cell fate in humans. They find that the recently described T memory stem cells (TSCM) are able to persist and preserve their precursor potential in human recipients for up to 12 years after genetic correction and infusion into patients. The safety and long-term survival of these cells not only strengthen our knowledge of human immunology but also support the use of TSCM cells for adoptive immunotherapy. A definitive understanding of survival and differentiation potential in humans of T cell subpopulations is of paramount importance for the development of effective T cell therapies. In particular, uncovering the dynamics in vivo in humans of the recently described T memory stem cells (TSCM) would be crucial for therapeutic approaches that aim at taking advantage of a stable cellular vehicle with precursor potential. We exploited data derived from two gene therapy clinical trials for an inherited immunodeficiency, using either retrovirally engineered hematopoietic stem cells or mature lymphocytes to trace individual T cell clones directly in vivo in humans. We compared healthy donors and bone marrow–transplanted patients, studied long-term in vivo T cell composition under different clinical conditions, and specifically examined TSCM contribution according to age, conditioning regimen, disease background, cell source, long-term reconstitution, and ex vivo gene correction processing. High-throughput sequencing of retroviral vector integration sites (ISs) allowed tracing the fate of more than 1700 individual T cell clones in gene therapy patients after infusion of gene-corrected hematopoietic stem cells or mature lymphocytes. We shed light on long-term in vivo clonal relationships among different T cell subtypes, and we unveiled that TSCM are able to persist and to preserve their precursor potential in humans for up to 12 years after infusion of gene-corrected lymphocytes. Overall, this work provides high-resolution tracking of T cell fate and activity and validates, in humans, the safe and functional decade-long survival of engineered TSCM, paving the way for their future application in clinical settings.

Update on the safety and efficacy of retroviral gene therapy for immunodeficiency due to adenosine deaminase deficiency

Adenosine deaminase (ADA) deficiency is a rare, autosomal-recessive systemic metabolic disease characterized by severe combined immunodeficiency (SCID). The treatment of choice for ADA-deficient SCID (ADA-SCID) is hematopoietic stem cell transplant from an HLA-matched sibling donor, although <25% of patients have such a donor available. Enzyme replacement therapy (ERT) partially and temporarily relieves immunodeficiency. We investigated the medium-term outcome of gene therapy (GT) in 18 patients with ADA-SCID for whom an HLA-identical family donor was not available; most were not responding well to ERT. Patients were treated with an autologous CD34(+)-enriched cell fraction that contained CD34(+) cells transduced with a retroviral vector encoding the human ADA complementary DNA sequence (GSK2696273) as part of single-arm, open-label studies or compassionate use programs. Overall survival was 100% over 2.3 to 13.4 years (median, 6.9 years). Gene-modified cells were stably present in multiple lineages throughout follow up. GT resulted in a sustained reduction in the severe infection rate from 1.17 events per person-year to 0.17 events per person-year (n = 17, patient 1 data not available). Immune reconstitution was demonstrated by normalization of T-cell subsets (CD3(+), CD4(+), and CD8(+)), evidence of thymopoiesis, and sustained T-cell proliferative capacity. B-cell function was evidenced by immunoglobulin production, decreased intravenous immunoglobulin use, and antibody response after vaccination. All 18 patients reported infections as adverse events; infections of respiratory and gastrointestinal tracts were reported most frequently. No events indicative of leukemic transformation were reported. Trial details were registered at www.clinicaltrials.gov as #NCT00598481.

Tracking genetically engineered lymphocytes long-term reveals the dynamics of T cell immunological memory

Antigen exposure and differentiation phenotype influence long-term persistence of memory T cells after hematopoietic stem cell transplant. Committing T cells to memory Adoptive cell transfer is an increasingly successful therapy for a variety of diseases; however, little is known about what regulates the survival of these cells in humans. Now, Oliveira et al. leverage patients who have received genetically modified hematopoietic stem cells to track T cells over time. They found labeled effector memory, central memory, and stem memory T cells 2 to 14 years after infusion in all patients. Antigen recognition was critical in driving persistence and expansion. The clones that survived long-term appeared to initiate preferentially from central and stem cell memory T cell populations. These data suggest that the original phenotype of infused cells may influence long-term persistence of adoptively transferred cells. Long-lasting immune protection from pathogens and cancer requires the generation of memory T cells able to survive long-term. To unravel the immunological requirements for long-term persistence of human memory T cells, we characterized and traced, over several years, T lymphocytes genetically modified to express the thymidine kinase (TK) suicide gene that were infused in 10 patients after haploidentical hematopoietic stem cell transplantation (HSCT). At 2 to 14 years after infusion and in the presence of a broad and resting immune system, we could still detect effectors/effector memory (TEM/EFF), central memory (TCM), and stem memory (TSCM) TK+ cells, circulating at low but stable levels in all patients. Longitudinal analysis of cytomegalovirus (CMV)– and Flu-specific TK+ cells indicated that antigen recognition was dominant in driving in vivo expansion and persistence at detectable levels. The amount of infused TSCM cells positively correlated with early expansion and with the absolute counts of long-term persisting gene-marked cells. By combining T cell sorting with sequencing of integration (IS), TCRα and TCRβ clonal markers, we showed that T cells retrieved long-term were enriched in clones originally shared in different memory T cell subsets, whereas dominant long-term clonotypes appeared to preferentially originate from infused TSCM and TCM clones. Together, these results indicate that long-term persistence of gene-modified memory T cells after haploidentical HSCT is influenced by antigen exposure and by the original phenotype of infused cells. Cancer adoptive immunotherapy might thus benefit from cellular products enriched in lymphocytes with an early-differentiated phenotype.

Shedding of clinical-grade lentiviral vectors is not detected in a gene therapy setting.

Gene therapy using viral vectors that stably integrate into ex vivo cultured cells holds great promises for the treatment of monogenic diseases as well as cancer. However, carry-over of infectious vector particles has been described to occur upon ex vivo transduction of target cells. This, in turn, may lead to inadvertent spreading of viral particles to off-target cells in vivo, raising concerns for potential adverse effects, such as toxicity of ectopic transgene expression, immunogenicity from in vivo transduced antigen-presenting cells and, possibly, gene transfer to germline cells. Here, we have investigated factors influencing the extent of lentiviral vector (LV) shedding upon ex vivo transduction of human hematopoietic stem and progenitor cells. Our results indicate that, although vector carry-over is detectable when using laboratory-grade vector stocks, the use of clinical-grade vector stocks strongly decreases the extent of inadvertent transduction of secondary targets, likely because of the higher degree of purification. These data provide supportive evidence for the safe use of the LV platform in clinical settings.

531. Computational Pipeline for the Identification of Integration Sites and Novel Method for the Quantification of Clone Sizes in Clonal Tracking Studies

Gene-corrected cells in Gene Therapy (GT) treated patients can be tracked in vivo by means of vector integration site (IS) analysis, since each engineered clone becomes univocally and stably marked by an individual IS. As the proper IS identification and quantification is crucial to accurately perform clonal tracking studies, we designed a customizable and tailored pipeline to analyze LAM-PCR amplicons sequenced by Illumina MiSeq/HiSeq technology. The sequencing data are initially processed through a series of quality filters and cleaned from vector and Linker Cassette (LC) sequences with customizable settings. Demultiplexing is then performed according to the recognition of specific barcodes combination used upon library preparation and the sequences are aligned to the reference genome. Importantly, the human genome assembly Hg19 is composed of 93 contigs, among which the mitochondrial genome, unlocalized and unplaced contigs and some alternative haplotypes of chr6. While previous approaches aligned IS sequences only to the standard 24 human chromosomes, using the whole assembled genome allowed improving alignment accuracy and concomitantly increased the amount of detectable ISs. To date, we have processed 28 independent human sample sets retrieving 260,994 ISs from 189,270,566 sequencing reads. Although, sequencing read counts at each IS have been widely used to estimate the relative IS abundance, this method carries inherent accuracy constraints due to the rounds of exponential amplification required by LAM-PCR that might generate unbalances on the original clonal representation. More recently, a method based on genomic sonication has been proposed exploiting shear site counts to tag the number of original fragments belonging to each IS before PCR amplification. However, the number of cells composing a given clone could far exceed the number of fragments of different lengths that can be generated upon fragmentation in proximity of that given IS. This would rapidly saturate the available diversity of shear sites and progressively generate more and more same-site shearing on independent genomes. In order to overcome the described biases and reliably quantify ISs, we designed and tested a new LC encoding random barcodes. The new LC is composed of a known sequence of 29nt used as binding site for the primers upon amplification steps, a 6nt-random barcode, a fixed-anchor sequence of 6nt, a second 6nt-random barcode and a final known sequence of 22nt containing sticky ends for the three main restriction enzymes in use (MluI, HpyCH4IV and AciI). This peculiar design allowed increasing the accuracy of clonal diversity estimation since the fixed-anchor sequence acts as a control for sequencing reliability in the barcode area. The theoretical number of different available barcodes per clone (412=16,777,216) far exceeds the requirements for not saturating the original diversity of the analyzed sample (on average composed by around 50.000 cells). We validated this novel approach by performing assays on serial dilutions of individual clones carrying known ISs. The precision rate obtained was averagely around 99.3%, while the worst error rate reaches at most the 1.86%, confirming the reliability of IS quantification. We successfully applied the barcoded-LC system to the analysis of clinical samples from a Wiskott Aldrich Syndrome GT patient, collecting to date 50,215 barcoded ISs from 94,052,785 sequencing reads.

First Occurrence of Plasmablastic Lymphoma in Adenosine Deaminase-Deficient Severe Combined Immunodeficiency Disease Patient and Review of the Literature

Adenosine deaminase-deficient severe combined immunodeficiency disease (ADA-SCID) is a primary immune deficiency characterized by mutations in the ADA gene resulting in accumulation of toxic compounds affecting multiple districts. Hematopoietic stem cell transplantation (HSCT) from a matched donor and hematopoietic stem cell gene therapy are the preferred options for definitive treatment. Enzyme replacement therapy (ERT) is used to manage the disease in the short term, while a decreased efficacy is reported in the medium-long term. To date, eight cases of lymphomas have been described in ADA-SCID patients. Here we report the first case of plasmablastic lymphoma occurring in a young adult with ADA-SCID on long-term ERT, which turned out to be Epstein–Barr virus associated. The patient previously received infusions of genetically modified T cells. A cumulative analysis of the eight published cases of lymphoma from 1992 to date, and the case here described, reveals a high mortality (89%). The most common form is diffuse large B-cell lymphoma, which predominantly occurs in extra nodal sites. Seven cases occurred in patients on ERT and two after haploidentical HSCT. The significant incidence of immunodeficiency-associated lymphoproliferative disorders and poor survival of patients developing this complication highlight the priority in finding a prompt curative treatment for ADA-SCID.

Successful treatment with Harvoni® in an ADA‐SCID infant with HCV infection allowed gene therapy with Strimvelis®

Patients with inborn error diseases can be candidates for autologous haematopoietic stem cells (HSC) gene therapies (GT) but may require negative viral screening, including Hepatitis C (HCV), to allow HSC manipulation in Good Manufacturing Practices areas. In case of HCV positivity, patients might be excluded from life-saving treatments. As HCV antibodies could be negative in young infant immunodeficient patients due to their immature/impaired immune system, or positive due to maternal-fetal antibody transmission, the risk is usually also evaluated on the basis of the HCV-RNA. This article is protected by copyright. All rights reserved.

Dynamics of genetically engineered hematopoietic stem and progenitor cells after autologous transplantation in humans

Hematopoietic stem and progenitor cells (HSPC) are endowed with the role of generating and maintaining lifelong the extremely diverse pool of blood cells1. Clinically, transplantation of human HSPC from an allogeneic healthy donor or infusion of autologous gene-corrected HSPC can effectively replenish defective blood cell production caused by congenital or acquired disorders2–9. However, due to methodological and ethical constraints that have limited the study of human HSPC primarily to in vitro assays10 or xenotransplantation models11,12, the in vivo activity of HSPC has to date remained relatively unexplored in humans13–16. Here we report a comprehensive study of the frequencies, dynamics and output of seven HSPC subtypes in humans that was performed by tracking 148,093 individual clones in six patients treated with lentiviral gene therapy using autologous HSPC transplantation and followed for up to 5 years. We discovered that primitive multipotent progenitor and hematopoietic stem cell (HSC) populations have distinct roles during the initial reconstitution after transplant, compared with subsequent steady-state phases. Furthermore, we showed that a fraction of in vitro–activated HSC are resilient and undergo a defined delayed activation period upon transplant. Finally, our data support the concept that early lymphoid-biased progenitors might be capable of long-term survival, such that they can be maintained independently of their continuous production from HSC. Overall, this study provides comprehensive data on HSPC dynamics after autologous transplantation and gene therapy in humans.In vivo tracking of hematopoietic stem and progenitor cells in humans treated with lentiviral gene therapy unveils the resilience of hematopoietic stem cells and the long-term survival of lymphoid-biased precursors.

476. Clonal Tracking of Engineered Hematopoiesis In Vivo in Humans By Insertional Barcoding

Upon gene therapy (GT) for adenosine deaminase (ADA) deficient-SCID and Wiskott-Aldrich Syndrome (WAS), gene-corrected hematopoietic stem/progenitor cells (HSPC) generated a stable genetically engineered hematopoietic system where each vector-marked cell is univocally barcoded by a vector integration site (IS). To study the dynamics of human hematopoietic system, we collected by LAM-PCR+Illumina sequencing 28.539.414 sequence reads corresponding to 89.373 IS tagging clones belonging to 13 different cell types purified from the bone marrow and the peripheral blood of 4 WAS patients up to 48 months after GT. We firstly identified identical IS shared among CD34+ progenitors, and mature Myeloid/Lymphoid cells as markers of the real-time clonal output of vector-marked HSPC clones in vivo. We unraveled the nature and timing of short, intermediate and long term HSPC output showing that CD34+ clones active at 3-6 months after GT are not detectable at later follow up. Distinct waves of HSPC diversity were observed during the first 6-9 months after GT reaching a homeostatic equilibrium only by 12 months. By unsupervised clustering of IS similarities among lineages we unveiled diverse HSPC output towards lymphoid, myeloid and megakaryo-erythroid cells showing hints of a NK cells origin distinct from T and B cells. We exploited IS similarities to infere and test hematopoietic hierarchies by combining conditional probability distributions and static/dynamic graphical models of dependencies. We also estimated by mark-recapture approaches that just few thousands clones (1185-2884) are responsible for the long-term maintenance of the whole genetically engineered hematopoietic system. The ongoing analyses on IS collected from 7 distinct CD34+ subtypes isolated from GT patients will further increase HSPC tracking resolution. To evaluate the preservation of activity by transplanted HSPC we exploited data derived from the IS-based tracking of 4.845 clones in ADA-SCID patients performed for up to 6 years after GT. We showed that identical IS are consistently detected at multiple lineages level even several years after GT. Strikingly, by semi-quantitative PCRs on specific vector-genome junctions we tracked a fluctuating but consistent output of marked HSPC over a period of 5 years without the manifestation of clonal quiescence phases. Since gamma-retroviral vector used in this GT trial actively transduce only replicating cells, this provide the first evidence that HSPC, awaken from dormancy in vitro, can still retain in vivo long-term activity. Overall our work constitute the first molecular tracking of hematopoietic system in humans. The information gathered are crucial for the design of therapeutic approaches for a broad spectrum of hematological diseases and tumors.