Department of Psychology, Institute of Neuroscience, University of Oregon, Eugene, OR, United States.
Front Neural Circuits. 2021 Apr 7;15:618881. doi: 10.3389/fncir.2021.618881. eCollection 2021.
Movement has a prominent impact on activity in sensory cortex, but has opposing effects on visual and auditory cortex. Both cortical areas feature a vasoactive intestinal peptide-expressing (VIP) disinhibitory circuit, which in visual cortex contributes to the effect of running. In auditory cortex, however, the role of VIP circuitry in running effects remains poorly understood. Running and optogenetic VIP activation are known to differentially modulate sound-evoked activity in auditory cortex, but it is unknown how these effects vary across cortical layers, and whether laminar differences in the roles of VIP circuitry could contribute to the substantial diversity that has been observed in the effects of both movement and VIP activation. Here we asked whether VIP neurons contribute to the effects of running, across the layers of auditory cortex. We found that both running and optogenetic activation of VIP neurons produced diverse changes in the firing rates of auditory cortical neurons, but with distinct effects on spontaneous and evoked activity and with different patterns across cortical layers. On average, running increased spontaneous firing rates but decreased evoked firing rates, resulting in a reduction of the neuronal encoding of sound. This reduction in sound encoding was observed in all cortical layers, but was most pronounced in layer 2/3. In contrast, VIP activation increased both spontaneous and evoked firing rates, and had no net population-wide effect on sound encoding, but strongly suppressed sound encoding in layer 4 narrow-spiking neurons. These results suggest that VIP activation and running act independently, which we then tested by comparing the arithmetic sum of the two effects measured separately to the actual combined effect of running and VIP activation, which were closely matched. We conclude that the effects of locomotion in auditory cortex are not mediated by the VIP network.
运动对感觉皮层的活动有显著影响,但对视觉和听觉皮层的影响相反。这两个皮层区域都有一个血管活性肠肽表达(VIP)的抑制性回路,它在视觉皮层中有助于跑步的效果。然而,在听觉皮层中,VIP 回路在跑步效果中的作用仍知之甚少。跑步和光遗传 VIP 激活已知会以不同的方式调节听觉皮层中声音诱发的活动,但尚不清楚这些效果在皮层层之间如何变化,以及 VIP 回路的分层差异是否有助于观察到的运动和 VIP 激活的效果的巨大多样性。在这里,我们询问 VIP 神经元是否有助于听觉皮层各层的跑步效果。我们发现,VIP 神经元的跑步和光遗传激活都会导致听觉皮层神经元的放电率产生不同的变化,但对自发活动和诱发活动的影响不同,且在皮层层之间的模式也不同。平均而言,跑步会增加自发放电率,但会降低诱发放电率,从而减少声音的神经元编码。这种声音编码的减少在所有皮层层中都观察到,但在 2/3 层中最为明显。相比之下,VIP 激活会增加自发和诱发放电率,对声音编码没有总体群体效应,但会强烈抑制 4 层窄峰神经元的声音编码。这些结果表明,VIP 激活和跑步独立作用,我们通过将分别测量的两种效果的算术和与跑步和 VIP 激活的实际组合效果进行比较来测试这一点,发现这两种效果非常匹配。我们得出结论,运动在听觉皮层中的作用不是由 VIP 网络介导的。
