An embryonic culture system for the investigation of striatal medium spiny neuron dendritic spine development and plasticity

Dendritic spines of striatal Medium Spiny Neurons (MSNs) receive converging dopaminergic and glutamatergic inputs. These spines undergo experience-dependent structural plasticity following repeated drug administration and during disease states like Huntington's and Parkinson's. Thus, understanding the molecular mechanisms leading to structural plasticity is an important step toward establishing a clear relationship between spine structure and function, and will ultimately contribute to understanding how changes in dendritic spine structure relate to behaviors or diseases. One major difficulty faced when studying MSN development is the lack of a detailed, standardized in vitro model system that produces MSNs with in vivo-like morphologies. For example, unlike cultured pyramidal neurons, MSNs grown in mono-cultures display stunted dendritic arborization and fail to develop a full cohort of mature dendritic spines.Here we report the generation of an embryonic mouse cortical–striatal co-culture that generates high cell yields from a single embryo. Unlike MSNs in striatal mono-culture, MSNs in co-culture develop in vivo-like morphologies and high densities of dendritic spines. Morphological identification of co-cultured MSNs expressing a soluble fluorescent protein can be confirmed by immunochemical detection of DARPP-32 (Dopamine and cyclic AMP regulated phosphoprotein of 32 kDa). Additionally, co-cultured MSN spines contain PSD-95 puncta and are apposed to SV2 puncta, indicating the spines express synaptic machinery. Finally, whole-cell recordings of co-cultured MSNs exhibit higher mEPSC frequency compared to mono-cultured MSNs, suggesting that the spines are functionally mature. These studies establish that this co-culture system is suitable for studying the morphological and physiological development and function of MSN dendritic spines.

► Use embryonic striatal and cortical tissue to culture medium spiny neurons (MSNs). ► Cultures can be made from a single embryo – good for studies with transgenics. ► Electroporated MSNs can retain expression for more than 21 days. ► Produces MSNs with complex dendritic morphology and abundant dendritic spines. ► MSNs have in vivo-like morphological and electrophysiological characteristics.