Multiple sclerosis (MS) is an inflammatory demyelinating disease of the central nervous system (CNS), which has a profound, currently intractable, neurodegenerative component--a large, unmet clinical need. In many neurodegenerative diseases, one of the earliest degenerative events is synapse dysfunction and loss. There is also synapse loss in MS, but the underlying molecular mechanism(s) remains an open question. The overall hypothesis of this proposal is that complement-dependent signaling underlies synapse loss in demyelinating disease in a subset of vulnerable neurons. This is largely based on our initial findings in the developing retinogeniculate circuit demonstrating that classical complement cascade proteins C1q and C3 localize to synapses and that phagocytic microglia engulf and eliminate synapses via the C3 receptor, complement receptor 3 (CR3). Strikingly, we have new evidence that a subset of retinogeniculate synapses are also engulfed by microglia, leading to synapse loss, in MS and in multiple MS-relevant animal models of demyelinating disease (e.g. non-human primate and mouse experimental autoimmune encephalomyelitis (EAE) models). We further identified that this synapse loss can occur early prior to demyelination, axon degeneration, or cell death, but is coincident with peripheral immune cell infiltration, reactive microgliosis, and increased levels of complement C1q and C3. However, unlike development, C3, but not C1q, is localized to synapses. Finally, inhibiting C3 specifically at retinogeniculate synapses in mouse EAE prevents microglial synapse engulfment, synapse loss, and visual dysfunction. These experiments establish C3 and microglia as key regulators of synapse loss in MS-relevant demyelinating disease and open up several new questions that we will explore: 1) What cells produce complement necessary for synapse elimination in demyelinating disease (Aim 1)? 2) Does microglial complement receptor CR3 regulate synapse loss in demyelinating disease (Aim 2)? 3) Which RGCs are most vulnerable to complement-mediated synapse elimination and later degeneration (Aim 3)? To address these questions, we will continue to use the retinogeniculate circuit. This is a highly tractable and powerful system for studying synaptic changes and it is highly relevant to MS, where inflammation of the optic nerve (i.e. optic neuritis) occurs in upwards of 50% of patients and results in prolonged, often permanent, visual dysfunction. We will now use a combination of cell-specific molecular genetics and high-resolution imaging of retinogeniculate synapses in the mouse EAE model to molecularly dissect synapse loss in inflammatory demyelinating disease. Results could uncover novel targets aimed at slowing or preventing neurodegeneration in MS, which could be broadly applicable to other neurodegenerative disease with synapse loss and neuroinflammation (Alzheimer?s disease, frontotemporal dementia, etc.).
Schafer, Dorothy P. Project Narrative While multiple sclerosis (MS) is an inflammatory demyelinating disease, it is now becoming increasingly appreciated that there is extensive neurodegeneration, which is currently an unmet clinical need. One common feature of neurodegeneration in MS, as well as many other neurodegenerative diseases (Alzheimer?s disease, frontotemporal dementia, etc.), is early loss of synaptic connections. We will now shed new mechanistic light on how synapses are lost in the MS brain and, in the process, identify new strategies for neuroprotection in MS and other neurodegenerative disorders.
