Here we describe several fundamental principles of olfactory processing in the Drosophila melanogaster antennal lobe (the analog of the vertebrate olfactory bulb), through the systematic analysis of input and output spike trains of seven identified glomeruli. Repeated presentations of the same odor elicit more reproducible responses in second-order projection neurons (PNs) than in their presynaptic olfactory receptor neurons (ORNs). PN responses rise and accommodate rapidly, emphasizing odor onset. Furthermore, weak ORN inputs are amplified in the PN layer but strong inputs are not. This nonlinear transformation broadens PN tuning and produces more uniform distances between odor representations in PN coding space. In addition, portions of the odor response profile of a PN are not systematically related to their direct ORN inputs, which probably indicates the presence of lateral connections between glomeruli. Finally, we show that a linear discriminator classifies odors more accurately using PN spike trains than using an equivalent number of ORN spike trains.
Copper is an essential transition metal with a critical role in the CNS. This requirement is underscored by Menkes disease, a fatal neurodegenerative disorder of childhood resulting from the absence or dysfunction of a copper-transporting P-type ATPase. To elucidate the cell biological mechanisms of copper homeostasis in the CNS, a polyclonal antisera against Menkes ATPase was used in immunoblot and immunohistochemical studies, demonstrating abundant expression of this copper transporter in hippocampal neurons. Consistent with this observation, immunofluorescent analysis revealed Menkes ATPase in the late Golgi of hippocampal neurons in primary culture. Glutamate receptor activation was found to result in the rapid and reversible trafficking of Menkes ATPase to neuronal processes, independent of the intracellular copper concentration and specific for activation of the NMDA-but not AMPA/kainate-type glutamate receptors. Metabolic studies revealed that trafficking of Menkes ATPase after NMDA receptor activation is associated with rapid release of copper from hippocampal neurons. Menkes ATPase is directly required for this copper efflux, because similar studies in hippocampal neurons derived from mice lacking a functional Menkes ATPase demonstrated no copper release. Together, these data reveal a critical role for Menkes ATPase in the availability of an NMDA receptor-dependent, releasable pool of copper in hippocampal neurons and demonstrate a unique mechanism linking copper homeostasis and neuronal activation within the CNS.
During cerebral ischemia, neurons undergo rapid alterations in dendritic structure consisting of focal swelling and spine loss. We used time-lapse microscopy to determine the fate of dendritic spines that disappeared after brief, sublethal hypoxic or excitotoxic exposures. Dendrite and spine morphology were assessed in cultured cortical neurons expressing yellow fluorescent protein or labeled with the fluorescent membrane tracer, DiI. Neurons exposed to NMDA, kainate, or oxygen-glucose deprivation underwent segmental dendritic beading and loss of approximately one-half of dendritic spines. Most spine loss was observed in regions of local dendritic swelling. Despite widespread loss, spines recovered within 2 hr after termination of agonist exposure or oxygen-glucose deprivation and remained stable over the subsequent 24 hr. Recovery was slower after NMDA than AMPA/kainate receptor activation. Time-lapse fluorescence imaging showed that the vast majority of spines reemerged in the same location from which they disappeared. In addition to spine recovery, elaboration of dendritic filopodia was observed in new locations along the dendritic shaft after dendrite recovery. Spine recovery did not depend on actin polymerization because it was not blocked by application of latrunculin-A, which eliminated filamentous actin staining in spines and blocked spine motility. Throughout spine loss and recovery, presynaptic and postsynaptic elements remained in physical proximity. These results suggest that elimination of dendritic spines is not necessarily associated with loss of synaptic contacts. Rapid reestablishment of dendritic spine synapses in surviving neurons may be a substrate for functional recovery after transient cerebral ischemia.
In both the vertebrate nose and the insect antenna, most olfactory receptor neurons (ORNs) respond to multiple odors. However, some ORNs respond to just a single odor, or at most to a few highly related odors. It has been hypothesized that narrowly tuned ORNs project to narrowly tuned neurons in the brain, and that these dedicated circuits mediate innate behavioral responses to a particular ligand. Here we have investigated neural activity and behavior downstream from two narrowly tuned ORN types in Drosophila melanogaster. We found that genetically ablating either of these ORN types impairs innate behavioral attraction to their cognate ligand. Neurons in the antennal lobe postsynaptic to one of these ORN types are, like their presynaptic ORNs, narrowly tuned to a pheromone. However, neurons postsynaptic to the second ORN type are broadly tuned. These results demonstrate that some narrowly tuned ORNs project to dedicated central circuits, ensuring a tight connection between stimulus and behavior, whereas others project to central neurons that participate in the ensemble representations of many odors.
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