IONIC TRIGGERS IN THE FERTILIZATION OF SEA URCHIN EGGS

Abstract

Summary: We have considered how a transient rise in calcium can occur and how it can result in the activation of the egg. Our evidence with the “artificial sperm”—the ionophore‐coated glass rod—suggests that even if sperm release calcium locally, this may be insufficient to completely propagate around the egg. Something else is needed and this something else can be mimicked by placing the eggs in higher than normal concentrations of potassium ion. A possibility is that the potassium effect results from inducing a membrane depolarization similar to the one that normally follows sperm‐egg binding. If correct, then the membrane depolarization might not only function in the block to polyspermy¹⁰ but could also be involved in “relaxing” or overcoming the normal calcium‐sequestering ability of the cell. A possible mechanism is a voltage‐dependent Ca⁺⁺ ‐induced Ca⁺⁺ release.The other question we have addressed is how this transient rise in calcium might act to trigger development of the egg. An obvious candidate is calmodulin and as noted this is indeed present in eggs in fairly high concentrations. Irrespective, one must then ask, “how does calmodulin act?” We propose that one site of calcium action, perhaps through calmodulin, is to initiate a brief bout of Na⁺– H⁺ exchange with a resultant rise in pH_i. Our data indicates that the sodium influx per se is not critical but that the resultant hydrogen efflux and the pH_i change is essential.This further suggests that during the normal formation of gametes the synthetic activity of the oocyte is turned off by a lowering of pH_i at the end of oogenesis and that at fertilization the pH_i is returned to a normal level through the brief episode of Na⁺– H⁺ exchange. Correlative evidence exists that the rise in pH_i is related to the well known increase in protein synthesis and that there may be a pH‐dependent unmasking of mRNA. The pH_i rise does not seem to be related to a 2.5‐fold increase in ribosomal transit time.The last question I wish to consider is whether these two ionic triggers, a transient rise in intracellular calcium and a permanent increase in intracellular pH, are used as triggers only once in the lifetime of an organism—i.e., only at fertilization—or whether these are general regulatory mechanisms used by many cells throughout the life history of the individual. The modulation of activity in adult cells by regulating Ca⁺² levels appears general; the role of calcium in controlling contraction of muscle and the permeability of nerves is well known and the presence of calmodulin in many cells further suggests that calcium is used as a general regulatory cation in these cells. Also, as detailed at this symposium, levels of calcium ion may be critical for regulating mitosis.The question of whether pH_i can be used as a regulatory element for cell activity is less clear. One problem, similar to that encountered in measuring calcium levels in cells, is the difficulty of in situ measurements. The two methods that are probably best suited are direct measurements with microelectrodes⁴⁷ and measurements based on phoning of weak acids, such as the DMO method.⁴⁸ Both of these procedures are almost in their infancy and still used in relatively few laboratories.In sea urchin eggs, the rise in pH_i is signaled by the concomitant efflux of hydrogen ions from the cell. Can this efflux be used as a simple indicator of whether there are similar intracellular pH changes accompanying other cell activities? Looking at fertilization, the preliminary indications would be that raises in pH_i are spotty. Acid release is seen in eggs of Urechis⁴⁹ (an echiuroid related to the annelids) and in Spisula (a mollusk).⁵⁰ However, acid release is not seen in other mollusks such as Mytilus and Acmaea⁴⁹ nor is it seen in the starfish and tunicate eggs.⁵¹ Yet, acid release is associated with activation of both starfish and tunicate sperm.^15,52These scanty results would suggest that although the potential for utilizing pH as a regulatory element is widespread it is not necessarily used as a regulator at fertilization. A probable scenario is that the rise in calcium is the universal response to fertilization but that the mechanisms by which calcium acts to activate metabolism vary. In the sea urchin egg, it appears to be through pH_i; in other eggs alternate regulatory factors, such as calcium‐dependent protein phosphorylation, may be more important. It remains to be seen whether pH_i is also utilized for regulation after fertilization, as during later development and in the cells of the adult organism.