eLife (Sep 2021)

Activity-dependent Golgi satellite formation in dendrites reshapes the neuronal surface glycoproteome

  • Anitha P Govind,
  • Okunola Jeyifous,
  • Theron A Russell,
  • Zola Yi,
  • Aubrey V Weigel,
  • Abhijit Ramaprasad,
  • Luke Newell,
  • William Ramos,
  • Fernando M Valbuena,
  • Jason C Casler,
  • Jing-Zhi Yan,
  • Benjamin S Glick,
  • Geoffrey T Swanson,
  • Jennifer Lippincott-Schwartz,
  • William N Green

DOI
https://doi.org/10.7554/eLife.68910
Journal volume & issue
Vol. 10

Abstract

Read online

Activity-driven changes in the neuronal surface glycoproteome are known to occur with synapse formation, plasticity, and related diseases, but their mechanistic basis and significance are unclear. Here, we observed that N-glycans on surface glycoproteins of dendrites shift from immature to mature forms containing sialic acid in response to increased neuronal activation. In exploring the basis of these N-glycosylation alterations, we discovered that they result from the growth and proliferation of Golgi satellites scattered throughout the dendrite. Golgi satellites that formed during neuronal excitation were in close association with endoplasmic reticulum (ER) exit sites and early endosomes and contained glycosylation machinery without the Golgi structural protein, GM130. They functioned as distal glycosylation stations in dendrites, terminally modifying sugars either on newly synthesized glycoproteins passing through the secretory pathway or on surface glycoproteins taken up from the endocytic pathway. These activities led to major changes in the dendritic surface of excited neurons, impacting binding and uptake of lectins, as well as causing functional changes in neurotransmitter receptors such as nicotinic acetylcholine receptors. Neural activity thus boosts the activity of the dendrite’s satellite micro-secretory system by redistributing Golgi enzymes involved in glycan modifications into peripheral Golgi satellites. This remodeling of the neuronal surface has potential significance for synaptic plasticity, addiction, and disease.

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