Bioenergetic characterization of transient state phosphate uptake by the cyanobacterium Anacystis nidulans

A force flow relationship based on nonequilibrium thermodynamics was derived to analyze the variable transient state phosphate uptake phenomena of cyanobacteria seen under different growth conditions and external phosphate concentrations. This relationship postulates the following basic properties of the uptake system: First, a threshold value exists, below which incorporation is energetically impossible. Second, threshold values are influenced by the activity of the phosphate uptake system, such that a decrease of the activity increases the threshold level. Third, near the thermodynamic equilibrium the uptake rate is linearly dependent on the free energy of polyphosphate formation and the pH-gradient at the thylakoid membrane. Experiments performed with Anacystis nidulans showed that phosphate uptake characteristics conformed to the properties predicted by the linear force-flow relationship. Linearity extented into regions far form thermodynamic equilibrium, e.g. to high phosphate concentrations, when algae were preconditioned to high phosphate levels. Under phosphate limited growth linearity was confined to a small concentration range, threshold values decreased below 10 nM, and the external concentration approached threshold. The data suggest that the uptake system responds to changes in the external phosphate concentration in the same way as sensory systems to input stimuli by amplifying signals and adapting to them.Abbreviations chl chlorophyll - H_e⁺, H_C⁺, H_T⁺ protons in the external medium, the cytoplasmic and thylakoid space respectively - P_c phosphate in the cytoplasmic space - P_e phosphate in the external medium - P_n, P_n+1 polyphosphates - pH_T pH-gradient across the thylakoid membrane