Phosphorescence quenching method for measurement of intracellular P O 2 in isolated skeletal muscle fibers

Abstract

Values of skeletal muscle intracellular PO2 during conditions ranging from rest to maximal metabolic rates have been difficult to quantify. A method for measurement of intracellular PO2 in isolated single skeletal muscle fibers by using O2-dependent quenching of a phosphorescent-O2 probe is described. Intact single skeletal muscle fibers from Xenopus laevis were dissected from the lumbrical muscle and mounted in a glass chamber containing Ringer solution at 20 degreesC. The chamber was placed on the stage of an inverted microscope configured for epi-illumination. A solution containing palladium-meso-tetra (4-carboxyphenyl) porphine bound to bovine serum albumin was injected into single fibers by micropipette pressure injection. Phosphorescence-decay curves (average of 10 rapid flashes) were recorded every 7 s from single cells (n = 24) in which respiration had been eliminated with NaCN, while the PO2 of the Ringer solution surrounding the cell was varied from 0 to 159 Torr. For each measurement, the phosphorescence lifetime was calculated at the varied extracellular PO2 by obtaining a best-fit estimate by using a monoexponential function. The phosphorescence lifetime varied from 40 to 70 microseconds at an extracellular PO2 of 159 Torr to 650-700 microseconds at 0 Torr. The phosphorescent lifetimes for the varied PO2 were used to calculate, by using the Stern-Volmer relationship, the phosphorescence-quenching constant (100 Torr-1. s-1), and the phosphorescence lifetime in a zero-O2 environment (690 microseconds) for the phosphor within the intracellular environment. This technique demonstrates a novel method for determining intracellular PO2 in isolated single skeletal muscle fibers.