A Steady-State Model of Spreading Depression Predicts the Importance of an Unknown Conductance in Specific Dendritic Domains

• Published in: Biophysical journal Vol. 92; no. 12; pp. 4216 - 4232
• Main Authors: Makarova, Julia, Ibarz, José M., Canals, Santiago, Herreras, Oscar
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 15.06.2007; Biophysical Society
• Subjects: Animals; Biophysical Theory and Modeling; Biophysics; Cells; Computer Simulation; Conductivity; Cortical Spreading Depression - physiology; Dendrites - physiology; Humans; Membrane Potentials - physiology; Membranes; Models, Neurological; Models, Statistical; Nerve Net - physiology; Neurons; Pyramidal Cells - physiology; Synaptic Transmission - physiology
• ISSN: 0006-3495; 1542-0086
• DOI: 10.1529/biophysj.106.090332

Spreading depression (SD) is a pathological wave of transient neuronal inactivation. We recently reported that the characteristic sustained complete depolarization is restricted to specific cell domains where the input resistance ( R in) first becomes negligible before achieving partial recovery, whereas in adjacent, more polarized membranes it drops by much less. The experimental study of the participating membrane channels is hindered by their mixed contribution and heterogeneous distribution. Therefore, we derived a biophysical model to analyze the conductances that replicate the subcellular profile of R in during SD. Systematic variation of conductance densities far beyond the ranges reported failed to fit the experimental values. Besides standard potassium, sodium, and Glu-mediated conductances, the initial opening and gradual closing of an as yet undetermined large conductance is required to account for the evolution of R in. Potassium conductances follow in the relative contribution and their closing during the late phase is also predicted. Large intracellular potential gradients from zero to rest are readily sustained between shunted and adjacent SD-spared membranes, which remain electroregenerative. The gradients are achieved by a combination of high-conductance subcellular domains and transmembrane ion redistribution in extended but discrete dendritic domains. We conclude that the heterogeneous subcellular behavior is due to local membrane properties, some of which may be specifically activated under extreme SD conditions.