BACKGROUND Allogeneic hematopoietic stem-cell transplantation for X-linked severe combined immunodeficiency (SCID-X1) often fails to reconstitute immunity associated with T cells, B cells, and natural killer (NK) cells when matched sibling donors are unavailable unless high-dose chemotherapy is given. In previous studies, autologous gene therapy with γ-retroviral vectors failed to reconstitute B-cell and NK-cell immunity and was complicated by vector-related leukemia. METHODS We performed a dual-center, phase 1–2 safety and efficacy study of a lentiviral vector to transfer IL2RG complementary DNA to bone marrow stem cells after low-exposure, targeted busulfan conditioning in eight infants with newly diagnosed SCID-X1. RESULTS Eight infants with SCID-X1 were followed for a median of 16.4 months. Bone marrow harvest, busulfan conditioning, and cell infusion had no unexpected side effects. In seven infants, the numbers of CD3+, CD4+, and naive CD4+ T cells and NK cells normalized by 3 to 4 months after infusion and were accompanied by vector marking in T cells, B cells, NK cells, myeloid cells, and bone marrow progenitors. The eighth infant had an insufficient T-cell count initially, but T cells developed in this infant after a boost of gene-corrected cells without busulfan conditioning. Previous infections cleared in all infants, and all continued to grow normally. IgM levels normalized in seven of the eight infants, of whom four discontinued intravenous immune globulin supplementation; three of these four in-fants had a response to vaccines. Vector insertion-site analysis was performed in seven infants and showed polyclonal patterns without clonal dominance in all seven. CONCLUSIONS Lentiviral vector gene therapy combined with low-exposure, targeted busulfan conditioning in infants with newly diagnosed SCID-X1 had low-grade acute toxic effects and resulted in multilineage engraftment of transduced cells, reconstitution of functional T cells and B cells, and normalization of NK-cell counts during a median follow-up of 16 months. (Funded by the American Lebanese Syrian Associated Charities and others; LVXSCID-ND ClinicalTrials.gov number, .)
Purpose Deficiency of adenosine deaminase 2 (DADA2) is an inherited inborn error of immunity, characterized by autoinflammation (recurrent fever), vasculopathy (livedo racemosa, polyarteritis nodosa, lacunar ischemic strokes, and intracranial hemorrhages), immunodeficiency, lymphoproliferation, immune cytopenias, and bone marrow failure (BMF). Tumor necrosis factor (TNF-α) blockade is the treatment of choice for the vasculopathy, but often fails to reverse refractory cytopenia. We aimed to study the outcome of hematopoietic cell transplantation (HCT) in patients with DADA2. Methods We conducted a retrospective study on the outcome of HCT in patients with DADA2. The primary outcome was overall survival (OS). Results Thirty DADA2 patients from 12 countries received a total of 38 HCTs. The indications for HCT were BMF, immune cytopenia, malignancy, or immunodeficiency. Median age at HCT was 9 years (range: 2–28 years). The conditioning regimens for the final transplants were myeloablative (n = 20), reduced intensity (n = 8), or non-myeloablative (n = 2). Donors were HLA-matched related (n = 4), HLA-matched unrelated (n = 16), HLA-haploidentical (n = 2), or HLA-mismatched unrelated (n = 8). After a median follow-up of 2 years (range: 0.5–16 years), 2-year OS was 97%, and 2-year GvHD-free relapse-free survival was 73%. The hematological and immunological phenotypes resolved, and there were no new vascular events. Plasma ADA2 enzyme activity normalized in 16/17 patients tested. Six patients required more than one HCT. Conclusion HCT was an effective treatment for DADA2, successfully reversing the refractory cytopenia, as well as the vasculopathy and immunodeficiency. Clinical Implications HCT is a definitive cure for DADA2 with > 95% survival.
Summary Despite extensive investigation of the signals required for development of T helper type 1 (Th1) and type 2 (Th2) immune responses, the mechanisms involved are still not well‐defined. A critical role for Epstein–Barr virus‐induced gene 3 (EBI3) in these responses has been proposed. EBI3, initially discovered as a transcriptionally activated gene in Epstein–Barr virus‐infected B lymphocytes, codes for a subunit of the cytokine interleukin‐27 (IL‐27). While initial studies suggested that it had an important role in promoting Th1 responses, subsequent studies have revealed that EBI3 receptor signalling influences a variety of immune cell types and can inhibit both Th1 and Th2 responses. In the present study, we evaluated EBI3−/− mice for their ability to mount both Th1‐mediated and Th2‐mediated airway inflammatory responses. The EBI3−/− mice sensitized by exposure to inhaled ovalbumin plus a high dose of lipopolysaccharide, which normally results in Th1 responses in wild‐type (WT) mice, instead developed Th2 type airway inflammation, with increased numbers of eosinophils. The EBI3−/− mice that were exposed to inhaled ovalbumin with a low dose of lipopolysaccharide, which induces Th2 responses in WT mice, showed a marked enhancement of these responses, with increased airway eosinophils, increased serum IgE levels and increased levels of Th2 cytokines (IL‐4, IL‐5 and IL‐13) in culture supernatants of mediastinal lymph node cells. Increased production of Th2 cytokines was also seen when naive CD4+ T cells from EBI3−/− mice were stimulated in vitro compared with cells from WT mice. These results provide the first evidence that EBI3 may play an inhibitory role in allergic asthma development.
Atopic dermatitis (AD) is a chronic inflammatory skin disease with a complex pathogenesis. It is clinically well-defined and represents one manifestation of the atopic state, along with asthma, food allergy and/or allergic rhinitis. Within the last several decades, there has been much evidence to support the contribution of immune mechanisms in the pathogenesis of AD. It has also been documented that the prevalence of all atopic disease, including AD, has been increasing, although the environmental factors that may be contributing to this increase are not clearly defined. A better understanding of the underlying immunopathogenesis of AD should aid in better clinical management and development of new treatment options.
There are no universally approved re-vaccination guidelines for non-transplant pediatric cancer survivors. We hypothesized that by utilizing a response-based re-vaccination schedule, we could tailor vaccine schedules in off-treatment cancer survivors. Pre-vaccination antibody levels were obtained in 7 patients at an average of 20 days after the end of treatment date. In those without protective antibody levels, we administered vaccines 3 months after completion of treatment. Revaccinating patients 3 months after the end of treatment date resulted in protective antibody levels for most vaccines. We showed, on a preliminary basis, that vaccinating non-transplanted pediatric cancer survivors can be dynamically implemented in children with recovering immune function.
Early clinical studies of gene therapy for patients with X-linked Severe Combined Immunodeficiency (XSCID) only restored T cell immunity and carried a significant risk of iatrogenic leukemia. We developed a new gene therapy approach that utilizes a safety-modified lentiviral (LV) vector together with reduced exposure busulfan conditioning for newly diagnosed infants with XSCID (NCT01512888). Of the first enrolled 8 patients, 7 demonstrated robust reconstitution of T-, NK-, and B-cells with a median follow up of 16.4 months (range: 6.7 to 24.9 months; Mamcarz et al, N Engl J Med, 2019). Here we provide an update on our clinical study, which now includes 3 more patients (n=11 total), 8 months additional median follow-up (23.6 months; range: 1.5 to 33.9 months), more extensive analysis of T and B cell functional recovery, and detailed vector integration site studies. Overall, we successfully generated transduced autologous bone marrow (BM) CD34+ cells for all patients with a median vector copy number (VCN) of 0.45 VCN/cell (range: 0.16-1.13). Prior to the infusion of transduced CD34+ cells (median cell dose: 8.7 x106/kg; range: 4.5-19.0), patients received two daily doses of busulfan to target a cumulative area-under-the-curve (cAUC) of 22 mg*hr/L (achieved median: 22.3 mg*hr/L; range: 20.0-23.0). No severe adverse events, other than hematologic related to busulfan, were observed. All 11 patients had robust hematopoietic recovery within 3-4 weeks post cell infusion without blood product support. Nine patients, with a follow up of >3 months, achieved normal for age T-cell and NK-cell numbers within 3-4 months post gene therapy. T-cells matured appropriately as assessed by normal receptor excision circles (TREC) levels and TCRvb repertoire analysis. In addition, phytohemagglutinin (PHA) stimulation assays demonstrated normal T-cell function. So far, 5 patients are off IVIG of whom 3 responded to vaccines. As previously reported, patient #1 demonstrated poor immune reconstitution. He received a 2nd infusion of transduced CD34+ cells without conditioning one year after his initial infusion, which resulted in functional T-cell immune reconstitution. Clinically, all patients with a follow up >3 months recovered from pre-existing infections, are off protective isolation and prophylactic antimicrobials, and have normal growth in respect to height and weight. The median VCN at 12 months post gene therapy in seven patients, who have been followed for >12 months, was 2.25 VCN/cell (range: 1.24-3.03) in T cells, 0.34 VCN/cell (range: 0.23-1.25) in B cells, 1.55 VCN/cell (range 1.27-3.39) in NK cells, and 0.08 VCN/cell (range: 0.03-0.76) in myeloid cells in peripheral blood, and 0.10 (range: 0.05-0.66) in CD34+ bone marrow cells, respectively. Detailed integration sites analysis for the first 7 patients, who received a single infusion of transduced CD34+ cells, revealed that the majority of sites were located in introns and intergenic regions throughout the human genome. The integration site pattern was highly consistent across patients with integration site clusters that had been previously described by us and others after LV transduction. In conclusion, LV gene therapy for XSCID using low dose busulfan conditioning and a novel LV vector is well tolerated and results in the development of a functional normal immune system without evidence of malignant transformation with a median follow up of almost 2 years. Thus, our approach may present a promising alternative to current therapies, which rely in part on high dose chemotherapy followed by allogeneic hematopoietic cell transplantation. Disclosures Mamcarz: American Lebanese Syrian Associated Charities: Research Funding; UpToDate: Honoraria; NHLBI: Research Funding; ASSISI Foundation of Memphis: Research Funding; MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy; California Institute of Regenerative Medicine: Research Funding. Zhou:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Lockey:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Boi:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Koon-Kiu:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Cross:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy; NIH: Research Funding. Kang:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Ma:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Condori:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Dowdy:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Metais:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Langfitt:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Triplett:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Li:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Zhao:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Maron:Chimerix: Research Funding; MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy; Astellas: Research Funding. Janssen:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Weiss:GlaxoSmithKline: Consultancy; Cellarity INC: Consultancy; Esperian: Consultancy; Beam Therapeutics: Consultancy; Rubius INC: Consultancy. Youngblood:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Meagher:MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy. Puck:Pfeizer: Other: spouse serves on Rare Disease Advisory Board; NIAID: Research Funding; Invitae: Other: spouse employment. Cowan:NIH NIAD: Research Funding; Leadiant: Consultancy; Rocket Pharma: Consultancy; bluebird bio: Consultancy; California Institute Of Regenerative Medicine: Research Funding; Homology Medicine: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; UpToDate: Honoraria. Gottschalk:Tidal: Membership on an entity's Board of Directors or advisory committees; Merck: Consultancy; TESSA Therapeutics: Other: Research Collaboration; Patents and patent applications in the fields of T-cell & Gene therapy for cancer: Patents & Royalties; EMD Serono: Honoraria; California Institute for Regenerative Medicine: Research Funding; Sanofi: Honoraria; NHLBI: Research Funding; Inmatics: Membership on an entity's Board of Directors or advisory committees; MBIO: Other: St. Jude Children's Research Hospital has an existing exclusive license and ongoing partnership with Mustang Bio for the further clinical development and commercialization of this XSCID gene therapy; America Lebanese Syrian Associated Charities: Research Funding; ViraCyte: Consultancy; ASSISI fundation of Memphis: Research Funding.
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