Although dendrite arborization patterns are hallmarks of neuronal type and critical determinants of neuronal function, how dendritic arbors take shape is still largely unknown. Transcription factors play important roles in specifying neuronal types and have a profound influence on dendritic arbor size and complexity. The space that a dendritic arbor occupies is determined largely by a combination of growth-promoting signals that regulate arbor size, chemotropic cues that steer dendrites into the appropriate space, and neurite-neurite contacts that ensure proper representation of the dendritic field and appropriate synaptic contacts. Dendritic arbors are largely maintained over the neuron's lifetime, but in some cases, dendritic arbors are refined, in large part as a result of neuronal activity. In this review, we summarize our current understanding of the cellular and molecular mechanisms that regulate dendritic field formation and influence the shaping of dendritic arbors.
Dendrite arborization patterns are critical determinants of neuronal function. To explore the basis of transcriptional regulation in dendrite pattern formation, we used RNA interference (RNAi) to screen 730 transcriptional regulators and identified 78 genes involved in patterning the stereotyped dendritic arbors of class I da neurons in Drosophila. Most of these transcriptional regulators affect dendrite morphology without altering the number of class I dendrite arborization (da) neurons and fall primarily into three groups. Group A genes control both primary dendrite extension and lateral branching, hence the overall dendritic field. Nineteen genes within group A act to increase arborization, whereas 20 other genes restrict dendritic coverage. Group B genes appear to balance dendritic outgrowth and branching. Nineteen group B genes function to promote branching rather than outgrowth, and two others have the opposite effects. Finally, 10 group C genes are critical for the routing of the dendritic arbors of individual class I da neurons. Thus, multiple genetic programs operate to calibrate dendritic coverage, to coordinate the elaboration of primary versus secondary branches, and to lay out these dendritic branches in the proper orientation.[Keywords: Transcription; RNAi; Drosophila; neuron; dendrite] Supplemental material is available at http://www.genesdev.org.
Dendrites exhibit a wide range of morphological diversity, and their arborization patterns are critical determinants of proper neural connectivity. How different neurons acquire their distinct dendritic branching patterns during development is not well understood. Here we report that Spineless (Ss), the Drosophila homolog of the mammalian aryl hydrocarbon (dioxin) receptor (Ahr), regulates dendrite diversity in the dendritic arborization (da) sensory neurons. In loss-of-function ss mutants, class I and II da neurons, which are normally characterized by their simple dendrite morphologies, elaborate more complex arbors, whereas the normally complex class III and IV da neurons develop simpler dendritic arbors. Consequently, different classes of da neurons elaborate dendrites with similar morphologies. In its control of dendritic diversity among da neurons, ss likely acts independently of its known cofactor tango and through a regulatory program distinct from those involving cut and abrupt. These findings suggest that one evolutionarily conserved role for Ahr in neuronal development concerns the diversification of dendrite morphology.[Keywords: Drosophila; neuron; dendrite; axon; aryl hydrocarbon receptor; dioxin] Supplemental material is available at http://www.genesdev.org.
of Health (NIH) -F32-HL140729 (to S.C.) and R01 HL139365 (to M.S.) RUNNING TITLE: Vaped nicotine impairs mucociliary function preferentially via TRPA1 SUBJECT CATEGORY DESCRIPTOR: 6.17 Smoking Health Effects TOTAL WORD COUNT: 3985 AT A GLANCE COMMENTARY: Scientific Knowledge on the Subject E-cigarettes are marketed as safer alternatives to conventional cigarettes due to their defined composition and noncombustible nature. However, it is unclear how exposure to e-cigarette vapor, colloquially referred to as "vape", affects naïve airway epithelia. It is largely unknown to what extent individual constituents of vape, such as nicotine and flavoring agents, influence pulmonary function, if at all. The transient receptor potential ankyrin 1 (TRPA1) is a molecular target for vape effects due to its expression in airway epithelia and its reported gating by nicotine, reactive oxidants, and flavors, especially cinnamaldehyde. What This Study Adds to the FieldThis study implicates nicotine as a key "vape" constituent that acutely impairs airway mucociliary functions in vitro and in vivo (sheep). A functional, nicotine-sensitive TRPA1 receptor is natively expressed in human and sheep bronchial epithelial cells and mediates the effects of nicotine and e-cigarette vapors. Importantly, its inhibition prevents mucociliary dysfunction in vitro and in vivo. These findings implicate TRPA1 as a driver of mucociliary dysfunction induced by nicotine-containing e-cigarette vapor.ABSTRACT RATIONALE: Electronic cigarette (e-cig) use has been widely adopted under the perception of safety. However, possibly adverse effects of e-cig vapor in never-smokers are not well understood. OBJECTIVES:Effects of nicotine-containing e-cig vapors on airway mucociliary function were tested in differentiated human bronchial epithelial cells (HBECs) isolated from never-smokers and in the airways of a novel, ovine large animal model. METHODS:Mucociliary parameters were measured in HBECs and in sheep. Systemic nicotine delivery to sheep was quantified using plasma cotinine levels, measured by ELISA. MEASUREMENTS AND MAIN RESULTS:In vitro, exposure to e-cig vapor reduced airway surface liquid hydration and increased mucus viscosity of HBECs in a nicotinedependent manner. Acute nicotine exposure increased intracellular calcium levels, an effect primarily dependent on transient receptor potential ankyrin 1 (TRPA1). TRPA1 inhibition with A967079 restored nicotine-mediated impairment of mucociliary parameters including mucus transport in vitro. Sheep tracheal mucus velocity (TMV), an in vivo measure of mucociliary clearance, was also reduced by e-cig vapor. Nebulized e-cig liquid containing nicotine also reduced TMV in a dose-dependent manner and elevated plasma cotinine levels. Importantly, nebulized A967079 reversed the effects of e-cig liquid on sheep TMV. CONCLUSIONS:Our findings show that inhalation of e-cig vapor causes airway mucociliary dysfunction in vitro and in vivo. Furthermore, they suggest that the main Page 4 of 64 2 nicotine effect on mucociliary ...
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