Cell Reports (Aug 2019)

Complement C3 Is Activated in Human AD Brain and Is Required for Neurodegeneration in Mouse Models of Amyloidosis and Tauopathy

  • Tiffany Wu,
  • Borislav Dejanovic,
  • Vineela D. Gandham,
  • Alvin Gogineni,
  • Rose Edmonds,
  • Stephen Schauer,
  • Karpagam Srinivasan,
  • Melanie A. Huntley,
  • Yuanyuan Wang,
  • Tzu-Ming Wang,
  • Maj Hedehus,
  • Kai H. Barck,
  • Maya Stark,
  • Hai Ngu,
  • Oded Foreman,
  • William J. Meilandt,
  • Justin Elstrott,
  • Michael C. Chang,
  • David V. Hansen,
  • Richard A.D. Carano,
  • Morgan Sheng,
  • Jesse E. Hanson

Journal volume & issue
Vol. 28, no. 8
pp. 2111 – 2123.e6

Abstract

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Summary: Complement pathway overactivation can lead to neuronal damage in various neurological diseases. Although Alzheimer’s disease (AD) is characterized by β-amyloid plaques and tau tangles, previous work examining complement has largely focused on amyloidosis models. We find that glial cells show increased expression of classical complement components and the central component C3 in mouse models of amyloidosis (PS2APP) and more extensively tauopathy (TauP301S). Blocking complement function by deleting C3 rescues plaque-associated synapse loss in PS2APP mice and ameliorates neuron loss and brain atrophy in TauP301S mice, improving neurophysiological and behavioral measurements. In addition, C3 protein is elevated in AD patient brains, including at synapses, and levels and processing of C3 are increased in AD patient CSF and correlate with tau. These results demonstrate that complement activation contributes to neurodegeneration caused by tau pathology and suggest that blocking C3 function might be protective in AD and other tauopathies. : Wu et al. show that loss of the central complement component C3, which is elevated and activated in brains and cerebrospinal fluid from AD patients, ameliorates synapse loss and neurodegeneration in amyloidosis and tauopathy AD mouse models despite ongoing glial activation. Keywords: Alzheimer’s disease, C3, complement, amyloidosis, tauopathy, synapse, neurodegeneration, neuroinflammation, astrocyte, microglia