A differential polarized phase fluorometric study of the effects of high hydrostatic pressure upon the fluidity of cellular membranes

Abstract

The effects of high hydrostatic pressure (up to 2 kbar) upon the fluidity and order of the synaptic and myelin membrane fractions of goldfish brain have been studied by using steady-state and differential polarized phase fluorometry. Probe motion provided a measure of membrane order (r infinity) and probe rotational rate (R). Membrane order became progressively greater as pressure was increased up to approximately 2 kbar. This effect was similar over the temperature range 5.6-34.3 degrees C. An increase in pressure of 1 kbar had an effect on membrane order that was equivalent to a 13-19 degrees C reduction in temperature. Membrane order was essentially identical during pressurization and depressurization. At 5.6 degrees C, pressurization caused a large increase in R, and similar, though less dramatic, anomalies occurred at higher temperatures. It is suggested that this is due to the segregation of probe molecules in highly ordered membranes, which leads either to excitation transfer between 1,6-diphenyl-1,3,5-hexatriene (DPH) molecules or to changes in the rotational motion of DPH from "sticking" to "slipping".