MicroRNA-Dependent Control of Sensory Neuron Function Regulates Posture Behavior in Drosophila

All what we see, touch, hear, taste, or smell must first be detected by the sensory elements of our nervous system. Sensory neurons, therefore, represent a critical component in all neural circuits and their correct function is essential for the generation of behavior and adaptation to the environme...

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Bibliographic Details
Published in:The Journal of neuroscience 2021-10, Vol.41 (40), p.8297-8308
Main Authors: Klann, Marleen, Issa, A Raouf, Pinho, Sofia, Alonso, Claudio R
Format: Article
Language:English
Subjects:
Adaptive control
Animals
Behavior
Circuits
Critical components
Defects
Drosophila
Drosophila melanogaster
Evolution
Female
Flow cytometry
Fluorescence
Fruit flies
Gene expression
Helix-loop-helix proteins (basic)
Insects
Larvae
Male
MicroRNAs
MicroRNAs - biosynthesis
MicroRNAs - genetics
miRNA
Motor task performance
Movement - physiology
Mutants
Nervous system
Neural networks
Neurons
Olfaction
Position sensing
Posture
Posture - physiology
Reflex, Righting - physiology
Ribonucleic acid
RNA
Sensory evaluation
Sensory neurons
Sensory properties
Sensory Receptor Cells - physiology
Smell
Three dimensional motion
Touch
Transcription factors
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Summary:All what we see, touch, hear, taste, or smell must first be detected by the sensory elements of our nervous system. Sensory neurons, therefore, represent a critical component in all neural circuits and their correct function is essential for the generation of behavior and adaptation to the environment. Here, we report that the evolutionarily-conserved microRNA (miRNA) plays a key behavioral role in through effects on the function of larval sensory neurons. Several independent experiments (in 50:50 male:female populations) support this finding: first, miRNA expression analysis, via reporter expression and fluorescent-activated cell sorting (FACS)-quantitative PCR (qPCR) analysis, demonstrate expression in larval sensory neurons. Second, behavioral tests in null mutants show defects in self-righting, an innate and evolutionarily conserved posture-control behavior that allows larvae to rectify their position if turned upside-down. Third, competitive inhibition of in sensory neurons using a "sponge" leads to self-righting defects. Fourth, systematic analysis of sensory neurons in mutants shows no detectable morphologic defects in their stereotypic pattern, while genetically-encoded calcium sensors expressed in the sensory domain reveal a reduction in neural activity in mutants. Fifth, null mutants show reduced "touch-response" behavior and a compromised response to sound, both characteristic of larval sensory deficits. Furthermore, bioinformatic miRNA target analysis, gene expression assays, and behavioral phenocopy experiments suggest that might exert its effects, at least in part, through repression of the basic helix-loop-helix (bHLH) transcription factor Altogether, our study suggests a model in which miRNA-dependent control of transcription factor expression affects sensory function and behavior. Sensory neurons are key to neural circuit function, but how these neurons acquire their specific properties is not well understood. Here, we examine this problem, focusing on the roles played by microRNAs (miRNAs). Using , we demonstrate that the evolutionarily-conserved miRNA controls sensory neuron function allowing the animal to perform an adaptive, elaborate three-dimensional movement. Our work thus shows that microRNAs can control complex motor behaviors by modulating sensory neuron physiology, and suggests that similar miRNA-dependent mechanisms may operate in other species. The work contributes to advance the understanding of the molecular basis of behavio
ISSN:0270-6474
1529-2401
DOI:10.1523/JNEUROSCI.0081-21.2021