MGTA-456, a First-in-Class Cell Therapy Produced from a Single Cord Blood Unit, Enables a Reduced Intensity Conditioning Regimen and Enhances Speed and Level of Human Microglia Engraftment in the Brains of NSG Mice

Background. Allogeneic bone marrow transplant (BMT) is a promising, curative approach for patients with inherited metabolic disorders (IMDs), a class of pediatric diseases characterized by a single enzyme deficiency. The goal of transplant is to provide cells that produce functional enzymes otherwis...

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Published in:Blood 2018-11, Vol.132 (Supplement 1), p.115-115
Main Authors: Goncalves, Kevin A., Li, Shuping, Brooks, Melissa L., Hyzy, Sharon L., Boitano, Anthony E., Cooke, Michael P.
Format: Article
Language:English
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Summary:Background. Allogeneic bone marrow transplant (BMT) is a promising, curative approach for patients with inherited metabolic disorders (IMDs), a class of pediatric diseases characterized by a single enzyme deficiency. The goal of transplant is to provide cells that produce functional enzymes otherwise deficient in these patients, and thereby prevent or ameliorate neurological complications associated with selected IMDs. Donor-derived microglial cells are protective, limiting neurological disease progression. For IMD patients who do not have an HLA matched, non-carrier related donor, cord blood (CB) is the preferred HSPC source given its rapid availability and superior clinical outcomes compared to other graft sources. CB, however, is associated with delayed hematopoietic recovery and relatively poor engraftment due to the limited numbers of hematopoietic stem cells (HSCs) in a CB unit, delaying enzyme/protein reconstitution and cross-correction of non-hematopoietic cells. An aryl hydrocarbon receptor antagonist (AHRa)-based culture has been shown to expand CB CD34+ and CD34+CD90+ cells 330-fold and 100-fold, respectively, leading to rapid hematopoietic recovery after infusion of the clinical product, MGTA-456 (Wagner et al., Cell Stem Cell 2016 and Orchard et al., ASH 2018). As microglia are thought to be derived from HSCs, we hypothesized that MGTA-456 might lead to faster and greater microglial engraftment and potentially enable reduced intensity conditioning. Here, we assessed human hematopoietic and brain engraftment in NSG mice after transplant with MGTA-456 and showed that microglia engrafted faster with MGTA-456, less conditioning was needed, and that, mechanistically, these cells are derived from the CD34+CD90+ cell fraction. Methods. CB CD34+ cells were expanded in growth factor-supplemented media with or without an AHRa for 10 days. NSG mice were transplanted with unmanipulated CB CD34+ cells or the expanded product after 200 cGy total body irradiation or busulfan (BU) dosed at 20 or 40 mg/kg ip. Microglial engraftment was measured by flow cytometry of homogenized brains, quantitating the number of CD45+CD11b+Iba1+ cells, and by immunohistochemistry of brain sections. Results. Relative to naïve, unmanipulated CB CD34+ cells, transplant of MGTA-456 into sublethally irradiated mice led to an 8-fold increase in hematopoietic engraftment and a 10-fold increase in microglial engraftment in the brain (p
ISSN:0006-4971
1528-0020
DOI:10.1182/blood-2018-99-118258