Primary cilia are nearly ubiquitous cellular appendages that provide important sensory and signaling functions. Ciliary dysfunction underlies numerous human diseases, collectively termed ciliopathies. Primary cilia have distinct functions on different cell types and these functions are defined by the signaling proteins that localize to the ciliary membrane. Neurons throughout the mammalian brain possess primary cilia upon which certain G protein-coupled receptors localize. Yet, the precise signaling proteins present on the vast majority of neuronal cilia are unknown. Here, we report that dopamine receptor 1 (D1) localizes to cilia on mouse central neurons, thereby implicating neuronal cilia in dopamine signaling. Interestingly, ciliary localization of D1 is dynamic and the receptor rapidly translocates to and from cilia in response to environmental cues. Notably, the translocation of D1 from cilia requires proteins mutated in the ciliopathy Bardet-Biedl syndrome (BBS) and we find that one of the BBS proteins, Bbs5, specifically interacts with D1.
No treatment exists for facioscapulohumeral muscular dystrophy (FSHD), one of the most common inherited muscle diseases. Although FSHD can be debilitating, little effort has been made to develop targeted therapies. This lack of focus on targeted FSHD therapy perpetuated because the genes and pathways involved in the disorder were not understood. Now, more than 2 decades after efforts to decipher the root cause of FSHD began, this barrier to translation is finally lowering. Specifically, several recent studies support an FSHD pathogenesis model involving overexpression of the myopathic DUX4 gene. DUX4 inhibition has therefore emerged as a promising therapeutic strategy for FSHD. In this study, we tested a preclinical RNA interference (RNAi)-based DUX4 gene silencing approach as a prospective treatment for FSHD. We found that adeno-associated viral (AAV) vector-delivered therapeutic microRNAs corrected DUX4-associated myopathy in mouse muscle. These results provide proof-of-principle for RNAi therapy of FSHD through DUX4 inhibition.
The ability of recombinant adeno-associated virus (AAV) to deliver transgenes to the CNS has allowed for several advancements in the field of gene therapy to treat brain disorders. Although most AAVs do not readily cross the blood-brain barrier and transduce the CNS following peripheral administration, AAV-PHP.B has recently been shown to transduce brains of mice with higher efficiency compared with its parent serotype, AAV9, following injection into the retro-orbital sinus.Here, we extended this foundational work by comparing AAV-PHP.B transduction efficiency in wild-type C57BL/6J mice using four clinically applicable delivery strategies including two intravascular (intra-jugular vein and intra-carotid artery) and two intra-cerebral spinal fluid (CSF) routes (intra-cisterna magna and intra-lateral ventricle). We scaled up these comparisons in a larger-animal model and evaluated transduction efficiency of AAV-PHP.B in the rhesus macaque. We found widespread and largely equal CNS transduction in mice following all four injection strategies, whereas we observed a differential pattern of transduction in macaques with broad cortical and spinal cord transduction seen after intrathecal administration and only very low transduction following intravascular administration. Taken together, these results suggest that AAV-PHP.B may be a useful gene therapy vector for neurological disorders, particularly those stemming from broad cortical or spinal cord neuropathology.
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