Region-specific mechanosensation in Drosophila postural control behaviour

The relation between regional morphological features derived from the bilaterian body plan and the fundamental behaviours necessary to extract utility from such structures is not well understood. Here we use the Drosophila larva to investigate this problem focusing on the mapping of the regional stimuli that trigger an adaptive and evolutionarily conserved behaviour termed self-righting: a postural control system that allows the animal to restore its natural position if turned upside-down. Through the development of new methodologies that allow regionally-restricted mechanical stimulation and region-specific neuronal optogenetics, we find that multidendritic sensory neuron inhibition in anterior areas (thoracic/anterior abdominal) has a profound effect on self-righting performance, whilst inhibition of posterior sensory elements (mid and posterior abdomen) produces no effects. Using a deep neural network automated tracking method to examine how neuronal inhibition impacted different subcomponents of the self-righting sequence we learned that inhibition of anterior sensory neurons increases head casting behaviour, and that this is strongly correlated with abnormally long self-righting times. To explore the mechanistic bases of our behavioural observations, we considered the hypothesis that the Hox genes – well known for their roles in axial developmental patterning – might play a role in the functional specification of multidendritic sensory neurons along the body axis. Molecular expression analysis of FACS-sorted neural populations, fluorescent immunolabelling and neuron-specific knock-down experiments demonstrated that normal sensory neuron expression of the Hox genes Antennapedia and abdominal-b is necessary for self-righting in the Drosophila larva. Altogether, our work shows that region-specific mechanosensory processes mediated by multidendritic sensory neurons and instructed via Hox gene inputs are essential for self-righting, providing a link between regional structural features and an adaptive and widely evolutionarily conserved postural control behaviour.