Identification of two discrete states of energized mitochondria: Experiments on single mitochondria

Dynamic phase microscopy was used to measure the refractivity of a single mitochondrion. Our previous studies showed that application of an electric potential to artificial and natural mitochondrial membranes sharply increases their refractivity. Under the conditions of proton pump activity, the refractivity of a single mitochondrion is 2 to 4 times higher than an average refractivity of deenergized mitochondria. This study demonstrates that the membrane potential of energized mitochondria varies depending on environmental conditions and is controlled by the mitochondrial osmoregulation system. The refractivity of energized mitochondria, i.e., the difference between the refraction indexes of a single mitochondrion and the medium, is 0.02 ± 0.01, i.e., several times lower than that of the energized mitochondria whose membranes bear an electric charge. Earlier it was shown that refractivity of model multilayer systems formed from purified natural lecithin depends linearly on the electric field strength. These data point to a relationship between the refractivity of a single mitochondrion and the membrane potential generated during operation of the proton pump. Under normal conditions (250 mOsm), the mitochondrion behaves as a dynamic system oscillating on a minute scale between two functional states with different values of the refractivity index and different membrane potentials. The transition time is 10–30 s; the lifetime of both states is several minutes. The histograms reflecting the distribution of refractivities of single energized mitochondria within a population (n = 20–30) revealed the presence of two independent peaks (fractions II and III) with average refractivity values of 0.05 ± 0.01 and 0.09 ± 0.01, respectively; these fractions correspond to two long-lived states of mitochondria. However, under hypotonic conditions (120 mOsm), only one (“static”) state was identified, in which oscillations were absent and the refractivity of the overall mitochondrial population does not exceed 0.05 ± 0.01 (fraction II). Studies on mitoplast showed that values of refractivity are related to the inner mitochondrial membrane. It is inferred from these data that there exist two discrete states of mitochondria. Analysis of low-amplitude fluctuations of the refractivity of single mitochondria revealed the presence of frequency components at 1–3 Hz, presumably generated in response to non-uniform functioning of mitochondrial proton pumps. It is suggested that frequency components at 1.8-2.6 Hz are more characteristic of the ATPase pump, while the 1–1.3 Hz frequencies predominate during the functioning of respiratory proton pumps.