The archaeogastropod mollusc Haliotis iris: tissue and blood metabolites and allosteric regulation of haemocyanin function Available to Purchase

We investigated divalent cation and anaerobic end-product concentrations and the interactive effects of these substances and pH on haemocyanin oxygen-binding (Hc-O₂) in the New Zealand abalone Haliotis iris. During 24 h of environmental hypoxia (emersion), d-lactate and tauropine accumulated in the foot and shell adductor muscles and in the haemolymph of the aorta, the pedal sinus and adductor muscle lacunae, whereas l-lactate was not detected. Intramuscular and haemolymph d-lactate concentrations were similar, but tauropine accumulated to much higher levels in muscle tissues. Repeated disturbance and short-term exposure to air over 3 h induced no accumulation of d- or l-lactate and no change in [Ca²⁺], [Mg²⁺], pH and O₂-binding properties of the native haemolymph.

The haemolymph showed a low Hc-O₂ affinity, a large reverse Bohr effect and marked cooperativity. Dialysis increased Hc-O₂ affinity, obliterated cooperativity and decreased the pH-sensitivity of O₂ binding. Replacing Mg²⁺ and Ca²⁺ restored the native O₂-binding properties and the reverse Bohr shift. l- and d-lactate exerted minor modulatory effects on O₂-affinity. At in vivo concentrations of Mg²⁺ and Ca²⁺, the cooperativity is dependent largely on Mg²⁺, which modulates the O₂ association equilibrium constants of both the high-affinity (K_R) and the low-affinity (K_T) states (increasing and decreasing, respectively). This allosteric mechanism contrasts with that encountered in other haemocyanins and haemoglobins. The functional properties of H. iris haemocyanin suggest that high rates of O₂ delivery to the tissues are not a priority but are consistent with the provision of a large O₂ reserve for facultatively anaerobic tissues during internal hypoxia associated with clamping to the substratum.