Mesenchymal stem cell therapies promote wound healing by manipulating the local environment to enhance the function of host cells. Aggregation of mesenchymal stem cells (MSCs) into three-dimensional spheroids increases cell survival and augments their anti-inflammatory and proangiogenic potential, yet there is no consensus on the preferred conditions for maximizing spheroid function in this application. The objective of this study was to optimize conditions for forming MSC spheroids that simultaneously enhance their anti-inflammatory and proangiogenic nature. We applied a Design of Experiments (DOE) approach to determine the interaction between three input variables (number of cells/spheroid, oxygen tension, and inflammatory stimulus) on MSC spheroids by quantifying secretion of prostaglandin E2 (PGE2) and vascular endothelial growth factor (VEGF), two potent molecules in the MSC secretome. DOE results revealed that MSC spheroids formed with 40,000 cells/spheroid in 1% oxygen with an inflammatory stimulus (Spheroid 1) would exhibit enhanced PGE2 and VEGF production versus those formed with 10,000 cells/spheroid in 21% oxygen with no inflammatory stimulus (Spheroid 2). Compared to Spheroid 2, Spheroid 1 produced 5-fold more PGE2 and 4-fold more VEGF, providing the opportunity to simultaneously upregulate the secretion of these factors from the same spheroid. The spheroids induced macrophage polarization, sprout formation with endothelial cells, and keratinocyte migration in a human skin equivalent model – demonstrating efficacy on three key cell types that are dysfunctional in chronic non-healing wounds. We conclude that DOE-based analysis effectively identifies optimal culture conditions to enhance the anti-inflammatory and proangiogenic potential of MSC spheroids.
Key Points HSPCs are recruited to S aureus–infected skin wounds, differentiate into neutrophils, and hasten resolution of infection. Bacterial sensing via TLR2 elicits PGE2 production in HSPCs that provides autocrine feedback to meet the demand for local granulopoiesis.
The immune response to Staphylococcus aureus infection in skin involves the recruitment of neutrophils (PMN) from the bone marrow via the circulation and local granulopoiesis from hematopoietic stem and progenitor cells (HSPC) that also traffic to infected skin wounds. We focus on regulation of PMN number and function and the role of pore-forming alpha-toxin (AT), a virulence factor that causes host cell lysis and elicits inflammasome-mediated IL-1β secretion in wounds. Infection with wild type S. aureus enriched in AT reduced PMN recruitment and resulted in sustained bacterial burden and delayed wound healing. In contrast, PMN recruitment to wounds infected with an isogenic AT mutant strain (ΔAT) was unimpeded, exhibiting efficient bacterial clearance and hastened wound resolution. HSPC recruited to infected wounds was unaffected by AT production and were activated to expand PMN numbers in proportion to S. aureus abundance in a manner regulated by TLR2 and IL-1 receptor signaling. Immunodeficient MyD88 knockout mice infected with S. aureus experienced lethal sepsis that was reversed by PMN expansion mediated by injection of wild type HSPC directly into wounds. We conclude that AT induced IL-1β promotes local granulopoiesis and effective resolution of S. aureus-infected wounds, revealing a potential antibiotic free strategy for tuning the innate immune response to treat MRSA infection in immunodeficient patients.
Introduction Bone Marrow Transplant (BMT) is a potentially curative treatment for malignant and non-malignant blood disorders and has demonstrated impressive outcomes in autoimmune diseases. Prior to BMT, patients are prepared with high-dose chemotherapy alone or with total body irradiation, and both are associated with early and late morbidities, such as infertility, secondary malignancies and organ toxicity; and substantial risk of mortality. This greatly limits the use of BMT in malignant and non-malignant conditions. To address these issues, we are developing antibody drug conjugates (ADCs) targeting hematopoietic stem cells (HSCs) and immune cells to more safely condition patients for BMT. Results To enable simultaneous HSC and immune cell depletion for BMT we investigated targeting human CD45, a protein expressed exclusively on nearly all blood cells including HSCs. Antibody discovery campaigns identified several antibodies with sub-nanomolar affinities for human and non-human primate (NHP) CD45. We then created anti-CD45 ADCs with drug payloads including DNA-damaging, tubulin-targeting and RNA polymerase-inhibiting molecules. An ADC developed with alpha-amanitin (an RNA polymerase II inhibitor) enabled potent in vitro killing of primary human CD34+ HSCs and immune cells (40-120 picomolar IC50s). With this anti-CD45 amanitin ADC (CD45-AM), we explored depletion of HSCs and immune cells in vivo using humanized NSG mice. A single dose of 1 or 3 mg/kg CD45-AM enabled >95% depletion of human CD34+ cells in the bone marrow as assessed 7 or 14 days post-administration (Figure, n = 3/group, p values < 0.05); >95% depletion of human B-, T- and myeloid cells was observed in the periphery and bone marrow (Figure, p values < 0.05). Control non-targeting isotype matched-ADCs and anti-CD45 antibody not bearing a toxin had minimal effect on either HSC or immune cells. In hematopoietic malignancies, an anti-CD45 ADC would ideally reduce disease burden and enable BMT. In a model of acute lymphoblastic leukemia (REH cell line, n = 10 mice/group), and 3 patient-derived models of FLT3+NPM1+ acute myeloid leukemia (n = 4-5 mice/group per model), a single dose of 1 mg/kg CD45-AM more than doubled the median survival and several mice survived disease-free (p values < 0.001). Anti-CD45 antibodies have been investigated for BMT conditioning in patients as naked antibodies that rely on Fc-effector function to deplete lymphocytes (Biol Blood Marrow Transplant. 2003 9(4): 273-81); or as radioimmunotherapy (Blood. 2006 107(5): 2184-2191). These agents demonstrated infusion-related toxicities likely due to effector function elicited by the wild-type IgG backbone. To address this issue, we created anti-CD45 antibodies with reduced Fc-gamma receptor binding that prevented cytokine release in vitro and in humanized mice. As BMT will likely require fast clearing ADCs to avoid depleting the incoming graft, we also created fast-half-life CD45-AM variants with a t½ of 8-15 hours in mice. To determine the safety and pharmacokinetic properties of regular and fast half-life Fc-silent variants in an immune-competent large animal we tested these in cynomolgus monkeys. Single doses (3 mg/kg, iv, n = 3/group) of fast and regular half-life Fc-silent unconjugated anti-CD45 antibodies were both well tolerated in cynomolgus monkeys and displayed pharmacokinetic properties suitable for BMT. Conclusion These results demonstrate that targeting CD45 with an amanitin ADC results in potent in vitro and in vivo human HSC and immune cell depletion. This new CD45-AM ADC also significantly reduced disease burden in multiple leukemia models. Our results indicate Fc-silencing may avoid infusion-related toxicities observed with previous CD45 mAbs. An alpha-amanitin ADC targeted to CD45 may be appropriate for preparing patients for BMT since we hypothesize it may i) be non-genotoxic; ii) effectively deplete both HSC and immune cells; iii) avoid bystander toxicity, due to amanitin's poor cell permeability as a free toxin; and iv) kill cycling and non-cycling cells, the latter being necessary for effective HSC depletion. As our anti-CD45 ADCs are cross-reactive, we are currently investigating their HSC and immune cell depletion activity in vivo in NHPs to enable further preclinical development of these transplant conditioning agents. Disclosures Palchaudhuri: Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties; Harvard University: Patents & Royalties. Pearse:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Proctor:Magenta Therapeutics: Employment, Equity Ownership. Hyzy:Magenta Therapeutics: Employment, Equity Ownership. Aslanian:Magenta Therapeutics: Employment, Equity Ownership. McDonough:Magenta Therapeutics: Employment, Equity Ownership. Sarma:Magenta Therapeutics: Employment, Equity Ownership. Brooks:Magenta Therapeutics: Employment, Equity Ownership. Bhat:Magenta Therapeutics: Employment. Ladwig:Magenta Therapeutics: Employment, Equity Ownership. McShea:Magenta Therapeutics: Employment, Equity Ownership. Kallen:Magenta Therapeutics: Employment, Equity Ownership. Li:Magenta Therapeutics: Employment, Equity Ownership. Panwar:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Dushime:Magenta Therapeutics: Employment, Equity Ownership. Sawant:Magenta Therapeutics: Employment, Equity Ownership. Adams:Magenta Therapeutics: Employment, Equity Ownership. Falahee:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Lamothe:Magenta Therapeutics: Employment, Equity Ownership. Gabros:Magenta Therapeutics: Employment, Equity Ownership. Kien:Magenta Therapeutics: Employment, Equity Ownership. Gillard:Magenta Therapeutics: Employment, Equity Ownership. McDonagh:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Boitano:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Cooke:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties.
Background . The majority of hematopoietic stem cell (HSC) transplants are performed using peripheral blood mobilized with granulocyte-colony stimulating factor (G-CSF) given over 5 days. The goal of a successful transplant is to reliably mobilize optimal numbers of HSCs necessary for rapid and consistent multilineage engraftment. Infusion of mobilized allogeneic grafts results in significant acute and chronic graft-versus-host disease (GvHD) in up to 80% of allogeneic transplant recipients. A reliable and rapid method to mobilize HSC-rich grafts with reduced GvHD potential would be clinically meaningful. In a Phase 1 study of normal volunteers, MGTA-145 (GroβT), a CXCR2 agonist, when combined with plerixafor, a CXCR4 inhibitor, robustly and rapidly mobilized sufficient HSCs for a safe transplant after only a single day of dosing and apheresis/collection. Here, we phenotypically and functionally profile these mobilized grafts obtained from human volunteers and show that MGTA-145 + plerixafor mobilizes grafts with >10-fold higher engraftment potential (as measured by SCID-repopulating units in NSG mice), a marked reduction in xenogeneic GvHD, and enhanced overall survival compared to G-CSF or plerixafor alone grafts. Results . In healthy donors, a peak of 40 CD34+ cells/μL were mobilized with MGTA-145 + plerixafor (n=12 donors). 11 of 12 (92%) of these donors mobilized >20 CD34+ cells/μL with single day dosing compared to only 8 of 14 (57%) achieving the same CD34+ cell target treated with plerixafor alone. Eight donors were mobilized with a single dose of MGTA-145 + plerixafor and apheresed on the same day. A median of 4x106 (1.5-7.0x106) CD34+ cells/kg were obtained (n=8 donors) from a median 20 (13-20) L collection. 35.8 (18.5-40.9)% of these cells were CD90+CD45RA-, a CD34+ subset enriched for HSCs, compared to only 6.9 (5.3-9.0)% with G-CSF (p<0.001, n=3 donors). Mechanistically, MGTA-145 bound to CXCR2 on neutrophils and led to a modest and transient increase in plasma concentrations of matrix metalloproteinase 9 (MMP- 9), a downstream target on neutrophils. To assess engraftment, we transplanted mobilized peripheral blood cells from healthy donors after a 5-day regimen of G-CSF or a single dose of plerixafor alone or MGTA-145 + plerixafor at limit dilution into sublethally irradiated primary and secondary NSG mouse recipients (n=3 cell doses, n=7-8 mice/group). Multilineage human engraftment was measured by flow cytometry 16 weeks post-transplant and SCID-repopulating cell (SRC) number was calculated (Figure 1A). MGTA-145 + plerixafor mobilized grafts (n=4 donors) led to a 23-fold increase in engraftment compared to G-CSF mobilized grafts (p<0.001, n=3 donors) and 11-fold higher engraftment compared to plerixafor mobilized grafts (p<0.001, n=3 donors). Immune cell subsets (B, T, and NK cells and cell subsets) mobilized by MGTA-145 + plerixafor were similar to those mobilized by plerixafor alone. While CD3+ T-cell numbers were comparable between MGTA-145 + plerixafor and plerixafor alone, MGTA-145 + plerixafor mobilized 0.2 (0.0-0.6) x108/kg CD8+ T-cells, constituting 1.8 (0.5-4.8)% of the graft, a number and proportion significantly lower than that mobilized by either G-CSF or plerixafor alone. To determine the effect of the mobilization regimen on xenogeneic GvHD, we developed a xenograft GvHD model in NSG mice where 6x106 PBMCs from various graft sources were infused into sublethally-irradiated animals (n=3-6 donors per graft source). Notably, MGTA-145 + plerixafor mobilized grafts resulted in significantly less GvHD than G-CSF (p<0.01) or plerixafor (p<0.001) grafts (Figure 1B). In vivo cellular subset depletion studies suggested that the GvHD protective effect in MGTA-145 + plerixafor grafts may be in part due to immunosuppressive monocytes which were not present, or present to a lesser degree, in grafts from donors mobilized with G-CSF or plerixafor. Conclusions . These data demonstrate that MGTA-145 + plerixafor is a rapid, reliable, and G-CSF free method to obtain high numbers of HSCs with durable engraftment potential and a graft with highly immunosuppressive properties. These data suggest that MGTA-145 + plerixafor is an effective single-day mobilization/collection regimen for both autologous and allogeneic stem cell transplantation resulting in enhanced engraftment and reduced GvHD in this xenograft model. Disclosures Goncalves: Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company, Patents & Royalties. Hyzy:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Hammond:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Falahee:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Howell:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Pinkas:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Schmelmer:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Hoggatt:Magenta Therapeutics: Consultancy, Current equity holder in publicly-traded company. Scadden:Magenta Therapeutics: Consultancy, Current equity holder in publicly-traded company, Membership on an entity's Board of Directors or advisory committees. Devine:Magenta Therapeutics: Consultancy. DiPersio:Magenta Therapeutics: Membership on an entity's Board of Directors or advisory committees. Savage:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company. Davis:Magenta Therapeutics: Current Employment, Current equity holder in publicly-traded company.
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