Both afferents converge onto dendritic spines, the critical site for synaptic integration in MSNs. In advanced PD there is a marked atrophy of dendrites and spines in these neurons, Androgen Receptor activity inhibition indicative of dysfunctional signal integration in the striatofugal pathway. Similar pathology, triggered by a dysregulation of intraspine Cav1.3 L-type Ca2+ channels (Day et al., 2006), has been observed in rodent and primate models of
PD (Day et al., 2006; Neely et al., 2007; Scholz et al., 2008). The significance of such dendritic atrophy and spine pruning for the symptoms and the treatment of PD has remained poorly understood. However, there is increasing awareness that these morphological alterations represent a major obstacle for therapeutic approaches
to enhance striatal function (Schuster et al., 2009). Most notably, the efficacy of dopamine cell replacement strategies, designed to restore nigrostriatal connectivity, may be hampered by striatal dendritic and spine PLX4032 mouse atrophy. In order for grafted dopamine neurons to re-establish functional connections, the morphological target of such reinnervation would need to be preserved or reestablished. In this issue of EJN, Soderstrom et al. (2010) report the results of a study on the impact of dendritic spine preservation in MSNs upon both anti-parkinsonian and prodyskinetic effect of fetal mesencephalic cell grafts. The authors elegantly and convincingly Methocarbamol show that administration of the L-type Ca2+ channel blocker nimodipine prevented loss of spines in MSNs in unilaterally lesioned rats that were grafted with embryonic ventral midbrain cells. Nimodipine treatment also resulted in improved therapeutic benefit and reduced graft-induced behavioral abnormalities of these hemi-parkinsonian rats. Specifically, the results indicate
that graft-mediated anti-parkinsonian efficacy was not potentiated by the prevention of spine loss; however, the impact of the graft- and levodopa-induced side-effects was greatly diminished by nimodipine treatment. Interestingly, these effects were not due to increased survival of grafted cells but correlated with a greater reinnervation of the affected striatum. These results underscore the importance of prevention (or reversal) of spine loss in striatofugal neurons for effective therapy based on dopamine cell replacement. They extend a previous report of reduced levodopa-induced dyskinesia by prior treatment with L-type Ca2+ channel antagonists (Schuster et al., 2009). The results described in Soderstrom et al. (2010) suggest that unless MSN spine loss and dendritic atrophy are reversed by appropriate pharmacological treatment, therapeutic interventions may be of limited efficacy or even cause unwarranted outcome. The findings and conclusions from the study by Soderstrom et al.