In general, the inorganic carbon ac

In general, the inorganic carbon acquisition and fixation by marine species depend upon changes in CO2 and/or HCO3− concentrations [108–110]. The carbonic anhydrases (CA) are enzymes that facilitate DIC uptake and fixation [33,30]. These enzymes catalyze the reversible hydration of CO2 to form bicarbonate [CO2 + H2O ↔ HCO3− + H+]. In typical physiological solutions, CO2(aq) is in equilibrium with HCO3− (aq). The HCO3− is negatively charged and poorly soluble in lipids, while CO2 is highly soluble in lipids. Therefore, CO2 can freely diffuse out of the cell but HCO3− must be transported across the cell membrane. However, some microorganisms such as cyanobacteria possess a transport system specialized for CO2 uptake by converting CO2 to HCO3− [111,112]. In addition, above pH 6.3, the equilibrium between these two species shifts toward HCO3− and thus poses problems in the maintenance of intracellular CO2 [30]. For trapping CO2 in the cell, HCO3− is enzymatically converted to CO2 and in this manner it facilitates its transport into the cell. In the cell, the RuBisCO enzyme is restricted to using CO2 for its function and the efficiency of CO2 fixation is enhanced by a specialized carbonic anhydrase that catalyzes dehydration of the cytoplasmic bicarbonate and ensures saturation of RuBisCO with its substrate [33,113].
Investigations of CAs in the model organism Riftia pachyptila, revealed the presence of several isoforms of this enzyme [31,32,34]. Inorganic carbon (CO2) is first acquired from the environment by diffusion across the plume, a branchial organ [26]. At the environment-branchial plume interface CO2 is converted to HCO3− [114,115] and is transported to trophosome cells mainly in the form of bicarbonate. HCO3− is converted to CO2 at the body fluid-bacteriocyte interface [31,32,34] and fixed by the bacterial symbionts enzyme RuBisCO form II [21].
In prokaryotes there are three phylogenetically distinct classes of CAs: α, β and γ. Interestingly all three of these classes of CA are present in the Thiomicrospira crunogena, a deep-sea hydrothermal vent sulfur-oxidizing chemolithoautotroph that lives in a spatially and thermally heterogeneous environment [33,116]. When the corresponding genes have been expressed in Escherichia coli, CA activity was detected for α-CA and β-CA, but not for the γ-CA-like protein [33].
As mentioned above, two general roles have been suggested for the known carbonic anhydrases; the transport of CO2 or HCO3− and provision of these substrates to cells [30]. Therefore, in addition to CO2 transport, the CAs can provide also HCO3− for various enzymes that can assimilate carbon. For example, the first enzymes, carbamylphosphate synthetase, in the arginine biosynthetic pathway and the pyrimidine de novo pathway use the inorganic HCO3− to initiate the biosynthesis [117,118]. The existence of these enzymes has been studied in all the tissues of Riftia. The results indicate that the first three enzymes of the de novo pyrimidine nucleotide pathway, carbamylphosphate synthetase, aspartate transcarbamylase and dihydroorotase are present only in the trophosome, the symbiont-harboring tissue [117]. Concerning the arginine biosynthetic pathway, it appears that the ammonium dependent carbamylphosphate synthetase is present in all the body parts of R. pachyptila as well as in the bacterial symbiont [118]. The unusual distribution of the enzymes of the de novo pyrimidine nucleotide pathway in all the tissues of R. pachyptila indicates that the metabolic relationship between R. pachyptila and its endosymbiont is clearly essential for the survival of both organisms.