CO2 uptake mechanism in Eremosphaera viridis

Abstract

Electrophysiological measurements of the acidophilic alga Eremosphaera viridis De Bary explored the effects of low CO2 levels on both membrane potential and resistance. This procedure incorporates a double-barreled microelectrode and suction pipette system, coupled with an approximately CO2-free environment. A key requirement is an artificial pond water perfusion media that has been purged of dissolved inorganic carbon by being boiled and bubbled with nitrogen gas. Both membrane potential and resistance were measured at pH5 in both low-CO2 conditions (2µM) and high-CO2 conditions (14µM) in both light, where CO2 transport is known to be active, and dark, where CO2 transport is not active. To avoid dissolved inorganic carbon contamination of the perfusion media, a special chamber was constructed, featuring a laminar flow of nitrogen gas over the solution, which allowed for the manipulation of cells while preventing any contamination by CO2 from the air. Results indicate that the uptake of CO2 by the alga is electrically silent and, therefore, not the result of a symport or antiport cotransport system that would "drive" CO2 uptake by coupling it to the electrochemical gradient of ions such as protons or sodium. The uptake is most likely facilitated by a transporter directly coupled with ATP hydrolysis.Key words: Eremosphaera viridis, dissolved inorganic carbon, CO2-ATPase, electrophysiology.