5-HT6 receptor blockade regulates primary cilia morphology in striatal neurons.

The 5-HT6 receptor has been implicated in a variety of cognitive processes including habitual behaviors, learning, and memory. It is found almost exclusively in the brain, is expressed abundantly in striatum, and localizes to neuronal primary cilia. Primary cilia are antenna-like, sensory organelles found on most neurons that receive both chemical and mechanical signals from other cells and the surrounding environment; however, the effect of 5-HT6 receptor function on cellular morphology has not been examined. We confirmed that 5-HT6 receptors were localized to primary cilia in wild-type (WT) but not 5-HT6 knockout (5-HT6KO) in both native mouse brain tissue and primary cultured striatal neurons then used primary neurons cultured from WT or 5-HT6KO mice to study the function of these receptors. Selective 5-HT6 antagonists reduced cilia length in neurons cultured from wild-type mice in a concentration and time-dependent manner without altering dendrites, but had no effect on cilia length in 5-HT6KO cultured neurons. Varying the expression levels of heterologously expressed 5-HT6 receptors affected the fidelity of ciliary localization in both WT and 5-HT6KO neurons; overexpression lead to increasing amounts of 5-HT6 localization outside of the cilia but did not alter cilia morphology. Introducing discrete mutations into the third cytoplasmic loop of the 5-HT6 receptor greatly reduced, but did not entirely eliminate, trafficking of the 5-HT6 receptor to primary cilia. These data suggest that blocking 5-HT6 receptor activity reduces the length of primary cilia and that mechanisms that regulate trafficking of 5-HT6 receptors to cilia are more complex than previously thought.

RiboTag is a flexible tool for measuring the translational state of targeted cells in heterogeneous cell cultures.

Primary neuronal cultures are a useful tool for measuring pharmacological- and transgene-regulated gene expression; however, accurate measurements can be confounded by heterogeneous cell types and inconsistent transfection efficiency. Here we describe our adaptation of a ribosomal capture strategy that was designed to be used in transgenic mice expressing tagged ribosomal subunits (RiboTag) in specific cell types, thereby allowing measurement of translating RNAs from desired cell types within complex tissues. Using this strategy we were able to isolate and analyze neuron-specific RNA despite the presence of glia by co-transfecting experimental plasmids with plasmids that selectively express RiboTag in neurons. RiboTag immunoprecipitation was capable of recovering high integrity RNA from small numbers of transfected cells that can then be interrogated by a variety of methods (e.g., RT-qPCR, PCR array, RNA-Seq) and compared with basal RNA expression of the entire culture. Additionally, we demonstrate how co-transfection of RiboTag with small hairpin RNA (shRNA) constructs can validate and accurately assess the degree of gene expression knockdown, and how RiboTag can be used to measure receptor-mediated gene regulation with transiently expressed designer receptors exclusively activated by designer drugs (DREADDs). RiboTag co-transfection represents a convenient and powerful tool to isolate RNA from a specific subset of cultured cells with a variety of applications for experiments in vitro.