Bioenergetics of membrane transport in Synechococcus R-2 (Anacystis nidulans, S.leopoliensis) PCC7942

Abstract

Specialized chemical probe techniques need to be used to measure the membrane potential (delta psii,o) or the intracellular pH (pHi) of the cyanobacterium Synechococcus R-2 (PCC7942). The pHi of Synechococcus is essentially a set point (7.3) over a wide range of extracellular pH (pHo) from 7 to 11. Maintenance of the pHo is strongly Na+-dependent and the cells cannot tolerate acid pHo. The 86Rb+-valinomycin method of measuring the delta psii,o has inherent limitations, the most obvious being that the valinomycin treatment itself might alter the membrane potential. 201Tl+ has been found in Synechococcus to distribute across the plasmalemma passively, and so the accumulation ratio of the ion ([Tl+]i/[Tl+]o or Tl+i,o) can be used to calculate the apparent delta psii,o. The two types of probe give comparable results in Synechococcus. Polarizations of the delta psii,o of cells, because of electrogenic transport of ions, can be detected from its effects upon the uptake rate of permeant cations using both the 86Rb+-valinomycin and 201Tl+ methods. HCO3- hyperpolarized delta psii,o, whereas NH4+, CH3NH3+, and K+ led to depolarization. Most active transport systems, including the HCO3- pump, in cyanophytes appear to be ATP binding cassette (ABC) type ATP pumps. Few cotransport (H+ or Na+) driven mechanisms have been identified. A substantial proportion of the power available from photosynthesis and respiration is used to maintain ionic gradients and the membrane potential and in the light a large part (10%) is used to import inorganic carbon.Key words: cyanobacteria, membrane potential, intracellular pH, electrochemical gradient, bioenergetics.