Bifurcation enhances temporal information encoding in the olfactory periphery.

Kiri Choi, Will Rosenbluth, Isabella R Graf, Nirag Kadakia, Thierry Emonet
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Abstract

Living systems continually respond to signals from the surrounding environment. Survival requires that their responses adapt quickly and robustly to the changes in the environment. One particularly challenging example is olfactory navigation in turbulent plumes, where animals experience highly intermittent odor signals while odor concentration varies over many length- and timescales. Here, we show theoretically that Drosophila olfactory receptor neurons (ORNs) can exploit proximity to a bifurcation point of their firing dynamics to reliably extract information about the timing and intensity of fluctuations in the odor signal, which have been shown to be critical for odor-guided navigation. Close to the bifurcation, the system is intrinsically invariant to signal variance, and information about the timing, duration, and intensity of odor fluctuations is transferred efficiently. Importantly, we find that proximity to the bifurcation is maintained by mean adaptation alone and therefore does not require any additional feedback mechanism or fine-tuning. Using a biophysical model with calcium-based feedback, we demonstrate that this mechanism can explain the measured adaptation characteristics of Drosophila ORNs.

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分叉增强了嗅觉外围的时间信息编码。
生命系统不断对来自周围环境的信号做出反应。生存要求它们的反应能够快速、稳健地适应环境的变化。其中一个特别具有挑战性的例子是湍流羽流中的嗅觉导航,在这种情况下,动物会体验到高度间歇性的气味信号,而气味浓度则会在许多长度和时间尺度上发生变化。在这里,我们从理论上证明果蝇的嗅觉受体神经元(ORNs)可以利用接近其发射动态的分叉点来可靠地提取有关气味信号波动的时间和强度的信息,这些信息已被证明是气味引导导航的关键。接近分叉点时,系统对信号方差具有内在不变性,气味波动的时间、持续时间和强度等信息都能有效传递。重要的是,我们发现仅靠平均适应就能维持接近分叉点,因此不需要任何额外的反馈机制或微调。通过使用基于钙反馈的生物物理模型,我们证明这种机制可以解释果蝇 ORN 的测量适应特征。
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