SUMMARYNeural activity has profound effects on the development of dendritic structure. Mechanisms that link neural activity to nuclear gene expression include activity-regulated factors, such as CREB, Crest or Mef2, as well as activity-regulated immediate-early genes, such as fos and jun. This study investigates the role of the transcriptional regulator AP-1, a Fos-Jun heterodimer, in activity-dependent dendritic structure development. We combine genetic manipulation, imaging and quantitative dendritic architecture analysis in a Drosophila single neuron model, the individually identified motoneuron MN5. First, D7 nicotinic acetylcholine receptors (nAChRs) and AP-1 are required for normal MN5 dendritic growth. Second, AP-1 functions downstream of activity during MN5 dendritic growth. Third, using a newly engineered AP-1 reporter we demonstrate that AP-1 transcriptional activity is downstream of D7 nAChRs and Calcium/calmodulin-dependent protein kinase II (CaMKII) signaling. Fourth, AP-1 can have opposite effects on dendritic development, depending on the timing of activation. Enhancing excitability or AP-1 activity after MN5 cholinergic synapses and primary dendrites have formed causes dendritic branching, whereas premature AP-1 expression or induced activity prior to excitatory synapse formation disrupts dendritic growth. Finally, AP-1 transcriptional activity and dendritic growth are affected by MN5 firing only during development but not in the adult. Our results highlight the importance of timing in the growth and plasticity of neuronal dendrites by defining a developmental period of activity-dependent AP-1 induction that is temporally locked to cholinergic synapse formation and dendritic refinement, thus significantly refining prior models derived from chronic expression studies.
Input-output computations of individual neurons may be affected by the three-dimensional structure of their dendrites and by the targeting of input synapses to specific parts of their dendrites. However, only few examples exist where dendritic architecture can be related to behaviorally relevant computations of a neuron. By combining genetic, immunohistochemical, and confocal laser scanning methods this study estimates the location of the spike initiating zone and the dendritic distribution patterns of putative synaptic inputs on an individually identified Drosophila flight motorneuron, MN5. MN5 is a monopolar neuron with more than 4000 dendritic branches. The site of spike initiation was estimated by mapping sodium channel immunolabel onto geometric reconstructions of MN5. Maps of putative excitatory cholinergic and of putative inhibitory GABAergic inputs on MN5 dendrites were created by charting tagged Dα7 nicotinic acetylcholine receptors and Rdl GABAA receptors onto MN5 dendritic surface reconstructions. Although these methods provided only an estimate of putative input synapse distributions, the data indicated that inhibitory and excitatory synapses were targeted preferentially to different dendritic domains of MN5, and thus, computed mostly separately. Most putative inhibitory inputs were close to spike initiation, which was consistent with sharp inhibition, as predicted previously based on recordings of motoneuron firing patterns during flight. By contrast, highest densities of putative excitatory inputs at more distant dendritic regions were consistent with the prediction that in response to different power demands during flight, tonic excitatory drive to flight motoneuron dendrites must be smoothly translated into different tonic firing frequencies.
Insect metamorphosis serves as a useful model to investigate postembryonic development in the central nervous system, because the transformation between larval and adult life is accompanied by a remodeling of neural circuitry. Most changes are controlled by ecdysteroids, but activity-dependent mechanisms and cell surface signals also play a role. This immunocytochemical study investigates the expression patterns of two isoforms of the neural cell adhesion molecule, fasciclin II (FasII), during postembryonic ventral nerve cord remodeling in the moth, Manduca sexta. Both the expression of the glycosyl-phosphatidylinositol (GPI)-linked isoform and the transmembrane isoform of Manduca FasII (TM-MFasII) are regulated in a stereotyped spatio-temporal pattern. TM-MFasII is expressed in a stage-specific manner in a subset of neurons. Subsets of central axons express high levels during outgrowth supporting a functional role for TM-FasII during pathfinding. Dendritic localization is not found at any stage of metamorphosis, suggesting no homophilic interactions of TM-MFasII during central synapse development. GPI-MFasII is expressed in a stage-specific manner, most likely only in glial cells. The larval and adult stages show almost no GPI-MFasII expression, whereas during pupal life, positive GPI-MFasII labeling is present around synaptotagmin-negative tracts or commissures, so that either homophilic stabilization of glial boundaries or heterophilic neuron-glial interactions possibly stabilize the axons within their tracts. GPI-MFasII expression is not co-localized with synaptotagmin-positive central terminals, rendering a role for synapse development unlikely. Neither isoform is expressed in all neurons of a specific class at any developmental stage, indicating that MFasII functions are restricted to specific subsets of neurons or to individual neurons.
Propofol, a powerful anesthetic, can be used safely in medical settings, but proves deadly when used recreationally. Propofol binds to the GABAA receptor, which consists of an integral ion channel protein embedded in the membrane of neurons in the brain that is activated by the neurotransmitter molecule gamma‐aminobutyric acid, or GABA. When propofol binds to the GABAA receptor, a conformational change occurs, holding the neurotransmitter GABA in its binding site and keeping the ion channel open. This allows more chloride ions to diffuse into the cell. Resting potential becomes more negative, so even with the diffusion of Na+ ions during nerve stimulation, the threshold cannot be reached and the action potential is not generated. Since the neurons cannot communicate normally, a person given propofol remains unconscious. The lower part of the GABAA receptor, located in the cytoplasm of a neuron, has an unidentified molecular structure. Phe 393 variants in the A and D chains prevent propofol from acting on the GABAA receptor. The DSHA SMART (Students Modeling A Research Topic) Team modeled the similar nicotinic receptor using 3D printing technology to better understand the structure of the GABAA receptor. A greater understanding of the structure of the GABAA receptor and the role of the Phe 393 variants in the action of propofol can lead to the development of more effective anesthetics.Support or Funding InformationThe MSOE Center for BioMolecular Modeling would like to acknowledge and thank the National Institutes of Health Science Education Partnership Award (NIH‐SEPA 1R25OD010505‐01) and the National Institutes of Health Clinical and Translational Science Award (NIH‐CTSA UL1RR031973) for their support in funding the 2017–2018 SMART Team Team program.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
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