A giant local interneuron modulates the rhythmic activities of the antennal lobe in Pupae Drosophila.

In Drosophila, olfaction is tightly related to feeding and reproduction. There are three classes of neurons forming synapses in the olfactory circuit: the olfactory receptor neurons (ORNs), projection neurons (PNs), and local interneurons (LNs). Here, we showed that giant local interneurons named GLNs, which were different from the classical neurons in the olfactory circuits, displayed distinctive rhythmic activities in the dorsolateral side of antennal lobe (AL) in Drosophila Pupae. Anatomically, GLNs were much larger than ipsilateral LNs and extended arborizations throughout the AL. Electrophysiologically, GLN exhibited typical 4-phased rhythmic spontaneous membrane activities, and the surrounding cells were dye-coupled when biocytin was injected into the cell body of GLN. Our study demonstrated that spontaneous activities of GLNs correlated with that of LNs and PNs. After the GLNs were damaged, the membrane activities of ipsilateral LNs and PNs became smaller, but faster. By depressing the firing frequencies of PNs and LNs, GLNs modulated the synchronization of AL and might play an important role as a "modulator" in the local circuit.

A pair of identified giant visual projection neurons demonstrates rhythmic activities before eclosion.

A small set of neurons acting as an internal clock in the Drosophila brain is critical for regulating circadian activities behavior and pre-adult development. However, the cell basis for the circadian rhythm in correlation with light sensitivity is not fully understood. Here we identified a pair of giant visual projection neurons located laterally to the calyx of the mushroom bodies, and investigated their electrophysiological, morphological characteristics, as well as the development pathways during eclosion. The typical morphology of these giant neurons showed the size of the soma (16.0±0.6 microns in diameter) and its processes. Interestingly during development, the three major branches shrunk significantly along with gradually decreased rhythmic spikes. Furthermore, the electrical activity of the giant visual projection neurons is circadian-regulated, shown with significantly higher resting membrane potential, increase in frequency of spontaneous action potential firing, and burst firing pattern during circadian day and night time. The similarities in the morphological characteristics with other visual projection neurons highly suggest that this neuron is a type of novel visual projection neurons in this area, which has special properties in light sensitivities and rhythmic activities. Our data provided supporting evidence for the visual projection neurons with light sensitivities, and pointed to the potential correlation of visual projection neurons and circadian rhythms during the eclosion period or an adaptive development for higher sensitivity of light in adult visual systems.

Static magnetic field modulates rhythmic activities of a cluster of large local interneurons in Drosophila antennal lobe.

With the development of superconducting magnets, the chances of exposure to intense static magnetic fields (SMFs) have increased. Therefore, safety concerns related to magnetic field exposure need to be studied, especially the effects of magnetic field exposure on the central nervous system. Only a limited number of studies prove a direct connection between magnetic fields and electrophysiological signal processing. Here we described a cluster of large local interneurons (LNs) located laterally to each antennal lobe of Drosophila melanogaster, which exhibit extensive arborizations throughout the whole antennal lobe. Dual recordings showed that these large LNs demonstrated rhythmic spontaneous activities that correlated with other LNs and projection neurons (PNs) in the olfactory circuit. The results suggest that 3.0-T SMF can interfere with the properties of the action potential, rhythmic spontaneous activities of large LNs, and correlated activity in pairs of ipsilateral large LN/LN in the olfactory circuit. This indicates that Drosophila can be an ideal intact neural circuit model and that the activities of the olfactory circuit can be used to evaluate the effects of magnetic field stimulations.

Permethrin modulates cholinergic mini-synaptic currents by partially blocking the calcium channel.

Pyrethroid insecticide modulation of the voltage-gated sodium channel (VGSC) is proposed to underlie their effects on neuronal excitability by inhibiting channel inactivation and increasing channel open time. However, some in vitro evidences indicate that target sites other than VGSCs could contribute to pyrethroid disruption of neuronal activity. Cholinergic excitability in Drosophila, as in other insects and mammals, is important for activity in the central nervous system. The effects of permethrin, a putative calcium antagonist, on calcium current and cholinergic mini-synaptic transmission were investigated in the Drosophila brain. At concentration of 2.5µM, permethrin significantly decreased the calcium current and cholinergic mini-synaptic current. However, the permethrin could not antagonize the calcium current completely. Removal of calcium from the external solution produced a significant decrease of cholinergic mini-synaptic transmission. The results are consistent with the hypothesis that permethrin may modulate cholinergic mini-synaptic currents by partially blocking the calcium channel.