Abstract
Excitatory synapses are often formed at small protrusions of dendrite, called dendritic spines, in most projection neurons, and the spine-head volumes show strong correlations with synaptic connectivity. We examined the dynamics of spine volume in the adult mouse visual cortex using time-lapse in vivo two-photon imaging with a resonant Galvano scanner. Contrary to expectations, we found that the spines in the adult neocortex showed fluctuations to a similar degree as that observed in young hippocampal preparations, but there were systematic differences in how the dynamics were dependent on spine volumes, thus allowing for fewer fluctuations in small spines, which could account for the relatively low turnover rates of neocortical spines in vivo. We found that spine volumes fluctuated to a greater extent in a mouse model (Fmr1 knockout) of fragile X mental retardation than in wild-type mice, and the spine turnover rates were also higher in Fmr1 knock-out mice. Such features of spine dynamics in Fmr1 knock-out mice could be represented by a single slope factor in our model. Our data and model indicate a small but significant change in the average spine volume and more eminent differences in the statistical distribution in Fmr1 knock-out mice even in adulthood, which reflects the abnormal in vivo dynamics of spine volumes.
Highlights
Excitatory glutamatergic synapses are formed at small protrusions of dendrites, called dendritic spines
Dynamics of spine-head volumes In vivo time-lapse imaging of the dendritic spines of the adult mouse visual cortex using two-photon microscopy was performed over 1 week to observe the longitudinal behavior of dendritic spines
We performed in vivo imaging of dendritic spines in the adult mouse visual cortex using a resonant scan twophoton confocal microscope
Summary
Excitatory glutamatergic synapses are formed at small protrusions of dendrites, called dendritic spines. As dendritic spines form synapses, their generation, enlargement, shrinkage, and elimination underlie the formation and maintenance of neuronal networks, and their head sizes strongly correlate with synaptic efficacy The authors declare no competing financial interests. 26221001 to H.K.), a Young Scientists (B; Grant 15K18333 to S.Y.), and Scientific Research on Innovative Areas (Grant 16H06396 to S.Y.) from The Japan Society for the Promotion of Science; Japan-EU Joint Workshop on Advanced Quantum Technology for Future Innovation (Grant JPMJCR1652 to H.K.) from the Japan Science and Technology Agency; Strategic Research Program for Brain Sciences Projects (17dm0107120h0002) from The Japan Agency for Medical Research and Development (to H.K.); and World Premier International Research Center Initiative from Ministry of Education, Culture, Sports, Science and Technology (to H.K.).
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