Publication date: 31 October 2017
Source:Cell Reports, Volume 21, Issue 5
Author(s): Mitchell H. Omar, Meghan Kerrisk Campbell, Xiao Xiao, Qiaonan Zhong, William J. Brunken, Jeffrey H. Miner, Charles A. Greer, Anthony J. Koleske
Synapses in the developing brain are structurally dynamic but become stable by early adulthood. We demonstrate here that an α5-subunit-containing laminin stabilizes synapses during this developmental transition. Hippocampal neurons deposit laminin α5 at synapses during adolescence as connections stabilize. Disruption of laminin α5 in neurons causes dramatic fluctuations in dendritic spine head size that can be rescued by exogenous α5-containing laminin. Conditional deletion of laminin α5 in vivo increases dendritic spine size and leads to an age-dependent loss of synapses accompanied by behavioral defects. Remaining synapses have larger postsynaptic densities and enhanced neurotransmission. Finally, we provide evidence that laminin α5 acts through an integrin α3β1-Abl2 kinase-p190RhoGAP signaling cascade and partners with laminin β2 to regulate dendritic spine density and behavior. Together, our results identify laminin α5 as a stabilizer of dendritic spines and synapses in the brain and elucidate key cellular and molecular mechanisms by which it acts.
Graphical abstract
Teaser
In the developing brain, synaptic structure transitions from dynamic to stable by early adulthood. Omar et al. identify a laminin molecule deposited at synapses in the brain that is essential for dendritic spine structural regulation and synapse stability between early postnatal development and adulthood.http://ift.tt/2gTAMSZ
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