Dendritic signal integration in a Drosophila Mushroom Body Output Neuron (MBON) essential for learning and memory

Abstract

AbstractThe ability to associate neutral stimuli with either positive or negative valence forms the basis for most forms of decision making. Long-term memory formation then enables manifestation of these associations to guide behavioral responses over prolonged periods of time. Despite recent advances in the understanding of the neuronal circuits and cellular mechanisms controlling memory formation, the computational principles at the level of individual information processing modules remain largely unknown. Here we use the Drosophila mushroom body (MB), the learning and memory center of the fly, as a model system to elucidate the cellular basis of memory computation. Recent studies resolved the precise synaptic connectome of the MB and identified the synaptic connections between Kenyon cells (KCs) and mushroom body output neurons (MBONs) as the sites of sensory association. We build a realistic computational model of the MBON-α3 neuron including precise synaptic connectivity from the 948 upstream KCs innervating the αβ MB lobes. To model membrane properties reflecting in vivo parameters we performed patch-clamp recordings of MBON-α3. Based on the in vivo data we model synaptic input of identified individual cholinergic KC>Mbon synapses by local conductance changes at the dendritic sections defined by the electron microscopic reconstruction. Modelling of activation of all individual synapses confirms prior results demonstrating that this neuron is electrotonically compact. As a likely consequence, activation pattern of individual KCs with identical numbers of synaptic connection but innervating different sections of the MBON-α3 dendritic tree result in highly similar depolarization voltages at its soma and likely spike initiation zone. Furthermore, we show that KC input patterns reflecting physiological activation by individual odors in vivo are sufficient to robustly drive MBON spiking. Our data suggest that the sparse innervation by KCs can efficiently control or modulate MBON activity, with minimal requirements on the specificity of synaptic localization. The KC>Mbon architecture therefore provides a suitable module to incorporate different olfactory associative memories based on stochastically encoded odor-specificity of KCs.