Olfactory receptor neurons use gain control and complementary kinetics to encode intermittent odorant stimuli

Elife. 2017 Jun 28:6:e27670. doi: 10.7554/eLife.27670.

Abstract

Insects find food and mates by navigating odorant plumes that can be highly intermittent, with intensities and durations that vary rapidly over orders of magnitude. Much is known about olfactory responses to pulses and steps, but it remains unclear how olfactory receptor neurons (ORNs) detect the intensity and timing of natural stimuli, where the absence of scale in the signal makes detection a formidable olfactory task. By stimulating Drosophila ORNs in vivo with naturalistic and Gaussian stimuli, we show that ORNs adapt to stimulus mean and variance, and that adaptation and saturation contribute to naturalistic sensing. Mean-dependent gain control followed the Weber-Fechner relation and occurred primarily at odor transduction, while variance-dependent gain control occurred at both transduction and spiking. Transduction and spike generation possessed complementary kinetic properties, that together preserved the timing of odorant encounters in ORN spiking, regardless of intensity. Such scale-invariance could be critical during odor plume navigation.

Keywords: D. melanogaster; Weber's Law; adaptation; computational biology; gain-control; natural stimuli; neuroscience; nonlinear modeling; olfaction; systems biology.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Animals
  • Drosophila / physiology*
  • Odorants*
  • Olfactory Receptor Neurons / physiology*
  • Smell*