Abstract
Structural, functional, and molecular alterations in excitatory spine synapses are a common hall-mark of many neurodevelopmental disorders including intellectual disability and autism. Here, we describe an optimized methodology, based on combined use of DiI and immunofluorescence, for rapid and sensitive characterization of the structure and composition of spine synapses in native brain tissue. We successfully demonstrate the applicability of this approach by examining the properties of hippocampal spine synapses in juvenile Fmr1 KO mice, a mouse model of Fragile X Syndrome. We find that mutant mice display pervasive dysgenesis of spine synapses evidenced by an overabundance of both abnormally elongated thin spines and cup-shaped spines, in combination with reduced density of mushroom spines. We further find that mushroom spines expressing the actin-binding protein Synaptopodin – a marker for spine apparatus - are more prevalent in mutant mice. Previous work identified spines with Synaptopodin/spine apparatus as the locus of mGluR-LTD, which is abnormally elevated in Fmr1 KO mice. Altogether, our data suggest this enhancement may be linked to the preponderance of this subset of spines in the mutant. Overall, these findings demonstrate the sensitivity and versatility of the optimized methodology by uncovering a novel facet of spine dysgenesis in Fmr1 KO mice.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
luisa.speranza{at}einsteinmed.edu; Sarah.Goebel{at}einsteinmed.edu; anna.francesconi{at}ein-steinmed.edu
kardelendalim{at}gmail.com; perrone{at}unina.it; floriana.volpicelli{at}unina.it
salvatore.pulcrano{at}igb.cnr.it