ABSTRACT
The perception of motion is an important function of vision. Neural wiring diagrams for extracting directional information have been obtained by connectome reconstruction. Direction selectivity in Drosophila is thought to originate in T4/T5 neurons through integrating inputs with different temporal filtering properties. Through genetic screening based on synaptic distribution, we isolated a new type of TmY neuron, termed TmY-ds, that form reciprocal synaptic connections with T4/T5 neurons. Its neurites responded to grating motion along the four cardinal directions and showed a variety of direction selectivity. Intriguingly, its direction selectivity originated from temporal filtering neurons rather than T4/T5. Genetic silencing and activation experiments showed that TmY-ds neurons are functionally upstream of T4/T5. Our results suggest that direction selectivity is generated in a tripartite circuit formed among these three neurons-temporal filtering, TmY-ds, and T4/T5 neurons, in which TmY-ds plays a role in the enhancement of direction selectivity in T4/T5 neurons.
Subject(s)
Animals , Neurites , Drosophila , Neurons , ConnectomeABSTRACT
@#Calcium is an important messenger in the mammalian nerve cells which mediates a variety of intracellular signal transduction pathways and plays critical roles in regulating the neuronal functions. Calcium signaling exerts its highly specific function in a defined sub-region of the cell, especially in the visual cortex of the brain. Detection of calcium signals in neurons is particularly important for the studying of neuronal function. The two-photon microscope has a unique advantage in the detection of calcium signal in the superficial cortex. In this paper, the application of two-photon in the <i>in vivo</i> detection of the visual cortical Ⅱ/Ⅲ layer of model animals are reviewed.