Voltage-Dependent Membrane Properties Shape the Size But Not the Frequency Content of Spontaneous Voltage Fluctuations in Layer 2/3 Somatosensory Cortex

• Published in: The Journal of neuroscience Vol. 39; no. 12; pp. 2221 - 2237
• Main Authors: Fernandez, Fernando R, Noueihed, Jad, White, John A
• Format: Journal Article
• Language: English
• Published: United States Society for Neuroscience 20.03.2019
• Subjects: Amplitudes; Animals; Conductance; Cortex (somatosensory); Depolarization; Electric potential; Female; Fluctuations; Interneurons; Interneurons - physiology; Intracellular; Male; Membrane capacitance; Membrane Potentials - physiology; Membrane resistance; Mice, Inbred C57BL; Motor Activity - physiology; Properties (attributes); Pyramidal cells; Pyramidal Cells - physiology; Resistance; Somatosensory Cortex - physiology; Time constant; Vibrissae - physiology; Voltage; cortex; somatosensory; spontaneous; correlations; high conductance
• ISSN: 0270-6474; 1529-2401
• DOI: 10.1523/JNEUROSCI.1648-18.2019

Under awake and idling conditions, spontaneous intracellular membrane voltage is characterized by large, synchronous, low-frequency fluctuations. Although these properties reflect correlations in synaptic inputs, intrinsic membrane properties often indicate voltage-dependent changes in membrane resistance and time constant values that can amplify and help to generate low-frequency voltage fluctuations. The specific contribution of intrinsic and synaptic factors to the generation of spontaneous fluctuations, however, remains poorly understood. Using visually guided intracellular recordings of somatosensory layer 2/3 pyramidal cells and interneurons in awake male and female mice, we measured the spectrum and size of voltage fluctuation and intrinsic cellular properties at different voltages. In both cell types, depolarizing neurons increased the size of voltage fluctuations. Amplitude changes scaled with voltage-dependent changes in membrane input resistance. Because of the small membrane time constants observed in both pyramidal cells and interneuron cell bodies, the low-frequency content of membrane fluctuations reflects correlations in the synaptic current inputs rather than significant filtering associated with membrane capacitance. Further, blocking synaptic inputs minimally altered somatic membrane resistance and time constant values. Overall, these results indicate that spontaneous synaptic inputs generate a low-conductance state in which the amplitude, but not frequency structure, is influenced by intrinsic membrane properties. In the absence of sensory drive, cortical activity in awake animals is associated with self-generated and seemingly random membrane voltage fluctuations characterized by large amplitude and low frequency. Partially, these properties reflect correlations in synaptic input. Nonetheless, neurons express voltage-dependent intrinsic properties that can potentially influence the amplitude and frequency of spontaneous activity. Using visually guided intracellular recordings of cortical neurons in awake mice, we measured the voltage dependence of spontaneous voltage fluctuations and intrinsic membrane properties. We show that voltage-dependent changes in membrane resistance amplify synaptic activity, whereas the frequency of voltage fluctuations reflects correlations in synaptic inputs. Last, synaptic activity has a small impact on intrinsic membrane properties in both pyramidal cells and interneurons.