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Cellular Therapies for the Treatment of Multiple Sclerosis Michael Carrithers, MD, PhD Wlliam Middleton Veterans Affairs Hospital and the University of Wisconsin, Madison Disclosures • Biogen-Idec (investigator-initiated study) • TEVA Overview • Gaps in existing treatments and need for repair strategies • Oligodendrocyte precursor (OPC) cell therapy • Immune-mediated cell therapy • Challenges for clinical translation Timeline of Treatments • 1993: Betaseron (first interferon trial funded in 1980). • 1996: Avonex and Copaxone (Copolymer 1 first developed in 1970’s). • 2002: Rebif. • 2004/2006: Tysabri (first animal study published in 1992). • 2010: Gilenya (FTY-720 developed for transplant patients, 1996). • 2013: DMF (Tecfidera). Survival in MS: A randomized cohort study 21 years after the start of the pivotal IFN-1b trial Objective: To examine the effects of interferon beta (IFN)-1b on all-cause mortality over 21 years in the cohort of 372 patients who participated in the pivotal randomized clinical trial (RCT), retaining (in the analysis) the original randomized treatment-assignments. Results: After a median of 21.1 years from RCT enrollment, 98.4% (366 of 372) of patients were identified, and, of these, 81 deaths were recorded (22.1% [81 of 366]). Patients originally randomly assigned to IFN-1b 250 mcg showed a significant reduction in all-cause mortality over the 21-year period compared with placebo (p 0.0173), with a hazard ratio of 0.532 (95% confidence interval 0.314–0.902). The hazard rate of death at long-term follow-up by KaplanMeier estimates was reduced by 46.8% among IFN-1b 250 mcg–treated patients (46.0% among IFN-1b 50 mcg–treated patients) compared with placebo. Baseline variables did not influence the observed treatment effect. Conclusions: There was a significant survival advantage in this cohort of patients receiving early IFN-1b treatment at either dose compared with placebo. Near-complete ascertainment, together with confirmatory findings from both active treatment groups, strengthens the evidence for an IFN-1b benefit on all-cause mortality. Neurology® 2012;78:1315–1322 Model for MS Immunopathogenesis 1. Peripheral activation of autoreactive T-cells, with encephalitogenic potential 2. Homing to the CNS 3. Migration across the BBB (via CAM attachment and MMP) 4. Reactivation of T-cell via autoantigen (i.e. MBP, MOG, MAG) on APCs 5. Secretion of pro-inflammatory cytokines 6. Antibody & complement cascade 7. Macrophage-mediated myelin destruction and oligodendrocyte death 8. Axonal degeneration Noseworthy et al. 2000 NEJM 343:938 Therapeutic Strategies for Repair • Pharmacological neuroprotection: growth factors, channel blockers. • Cell-based therapies: – embryonic stem cells – oligodendrocyte precursors – mesenchymal stem cells – immune-mediated repair The Oligodendrocyte Lineage Adult Neural Stem Cells What is the target for repair? Demyelinated plaque Potential outcomes No Treatment: Demyelinated axons susceptible to damage Chronic inflammation produces toxic mediators Demyelinated axons lack trophic support Following treatment: Remyelination Neuroprotection Chronic axonal death leads to increasing loss of function and disability Axonal loss Remyelination Remyelination will: 1. Restore conduction to demyelinated axons 2. Protect axons against subsequent injury and loss How can remyelination be achieved with stem cells? What is the experimental evidence of exogenous cell therapy success? Eight Weeks Later: Eight Weeks Later Can cells be transplanted at different levels of the CNS? Culture of CNP-EGFP oligospheres: label mature oligodendrocyte and Schwann cells Transplantation Brain (corpus callosum, bilateral) Spinal cord (thoracolumbar, dorsal column) Shi mice (n=14) P0-1 P21 Histology P120 Widespread migration of CNP-EGFP cells in the shi brain EGFP/MBP Widespread CNP-EGFP grafts in the shi spinal cord dorsal ventral CNP-EGFP CNP-EGFP MBP control cervical cord (same animal) Merge Propose d Trial: Asterias OPC1 Challenges to OPC Transplant in MS • Delivery to disseminated regions • Remyelination requires intact axons • Chronic inflammation within lesions and cell survival Immune-mediated Repair: T Regulatory Cells and Anti-inflammatory Macrophages Pharmacological vs Cell-based Treatments MS DMT’s Wang et al., 2011 Current Treg Clinical Trials Wang et al., 2011 Treg Therapy in MS • Can they enhance existing treatments? • Do they have a role in non-responders to existing immune treatments? • Is there a subset of Tregs that mediate repair in addition to inflammatory cell suppression? Immune-mediated Repair: Anti-inflammatory Macrophages Axonal Degeneration: Acute and Chronic Injury Bjarmatar et al, 2001 Macrophage-Microglia in Axonal Degeneration Bjartmar, 2001 Stem Cell Studies in Experimental Autoimmune Encephalomyelitis (EAE) • Embryonic and mesenchymal stem cells improve clinical EAE outcomes. • Capable of migration into the CNS. • Differentiate into CD11b positive cells. • Protection is likely mediated by alternatively activated macrophages. Immune-Mediated Repair: Macrophages Murray & Wynn, 2011 Overview: Macrophage SCN5A Channel • Identified as differentially expressed in immune-activated human macrophages by microarray analysis. • Human macrophages express intracellular, novel splice variants of a sodium channel gene, SCN5A (NaV1.5). • Macrophage SCN5A regulates endosomal function and anti-inflammatory signaling pathways. • The macrophage SCN5A splice variant is expressed in human and primate macrophages. Generation of Human Macrophage NaV1.5 Transgenic Mice Transfer of hSCN5A+ Macrophages into Mice with Severe EAE Leads to Clinical Recovery Transferred hSCN5A+ Macrophages Home to Regions of Injury and Express Anti-Inflammatory Markers Macrophage-mediated Immune Repair of the CNS • Formation of nodules of phagocytic cells may limit CNS tissue injury. • hSCN5A-expressing macrophages may be protective and useful in cell-based treatments. • Neuroprotective strategies that block sodium channels may have proinflammatory effects. Therapeutic Development • Cytometric: Cell selection • Genomic: – Microarray expression analysis – Promoter binding analysis • Proteomic: Protein-protein interactions • Broad Institute Connectivity Map (Cmap) SCN5A Signaling Network Lead Compound Identification Cell-based Immune Therapies: Advantages • Cells can have multiple actions as compared to pharmacologic approaches. • Transplants can be autologous. • Less tumorigenic and fewer regulatory issues as compared to stem cells. Cell-based Therapies: Challenges • Safety/Donor rejection. • Expansion of cells in vitro. • Does the approach clearly demonstrate enhanced efficacy? • FDA IND review and approval. • On-site GMP (Good Manufacturing Practice) facilities. • Patent issues/prior disclosures. Acknowledgements • Ian Duncan • • • • • • Elise Wojcik Matthew Subramani Kusha Rahgozar Erik Wright Casey Bresser Alexis Jones • • • • • VA Merit Award Biogen-Idec TEVA NMSS MMRRC/UC-Davis • “The contents do not represent the views of the Dept. of Veterans Affairs or the United States Government”
