Exposure to anoxia of the clam, Chamelea gallina II. Modulation of superoxide dismutase activity and expression in haemocytes.

In order to investigate the influence of anoxic stress on haemocyte immune response, specimens of Chamelea gallina were exposed to 24 and 48 h anoxia. To evaluate recovery capacity, clams were maintained, at the end of the anoxic phase, for 24 h in reoxygenated seawater. In this paper, activity and expression of the antioxidant enzyme superoxide dismutase (SOD) were studied on haemocyte lysate and haemolymph. Reported results have shown that the anoxic stress changed strongly the response of C. gallina blood cells. Indeed, at the end of the anoxic phase in both experiments (24 and 48 h of anoxia exposure), SOD activity in haemocyte lysate decreased significantly with respect to the control, likely because of a decreasing superoxide anion generation in anoxia. Expression analyses were coherent with activity values. In the first experiment (24 h anoxia), reoxygenation determined an increase in activity of both Cu/Zn-SOD and Mn-SOD, but with values that remained significantly lower than those of the controls. It seems that after the applied anoxic stress, 24 h of recovery is not sufficient to restore pre-anoxic conditions. In the second experiment (48 h anoxia), SOD isoforms showed a different response during the recovery of animals. Cu/Zn-SOD activity dropped below the values showed by haemocytes of anoxic bivalves, while Mn-SOD activity values exceeded significantly those of controls. The different haemocyte response could be probably due to a further stress suffered by the clams because of a massive spawning during the reoxygenation phase. Therefore, the high values of activity shown by Mn-SOD during the recovery are likely to be due to the high inducibility of this isoform. In Cu/Zn-SOD expression analyses, two immunoreactive bands were highlighted in both experiments. The former (apparent molecular weight of 16 kDa) corresponds to the expression of SOD1 and the latter (apparent molecular weight of 28–30 kDa) could be attributed to EC-SOD (SOD3), a Cu/Zn-SOD isoform located in extracellular ambient and identified both in vertebrates and invertebrates. The strong SOD3 expression during anoxia exposure and the further spawning stress (second experiment) testified its inducibility in C. gallina haemocytes and haemolymph in response to stressful conditions.