Calaxin is essential for the transmission of Ca2+-dependent asymmetric waves in sperm flagella

ABSTRACTRegulation of waveform asymmetry in sperm flagella is critical for changes in sperm swimming trajectory as seen during sperm chemotaxis towards eggs. Ca2+ is known as an important regulator of asymmetry in flagellar waveforms. A calcium sensor protein, calaxin, which is associated with the outer arm dynein, plays a key role in the sperm waveform regulation in a Ca2+-dependent manner. However, the molecular mechanism underlying the regulation of asymmetric waves by Ca2+ and calaxin remains unclear. We performed experiments using caged ATP to elucidate the formation and propagation of asymmetric flagellar waves in the sperm of the ascidian Ciona intestinalis. Demembranated sperm cells were suspended in a solution containing caged ATP and reactivated using UV flash photolysis. Initial bends were formed at the base and propagated towards the tip of flagella; however, the bend direction was different between asymmetric and symmetric waves. A calaxin inhibitor, repaglinide, had no effect on initial bend formation, but significantly inhibited the generation of the second flagellar bend in the reverse direction, resulting in the failure of asymmetric wave formation and propagation. These results suggest that calaxin plays a critical role in Ca2+-dependent transmission of flagellar asymmetric waveforms.

On the functional use of the membrane compartmentalized pool of ATP by the Na+ and Ca++ pumps in human red blood cell ghosts

Previous evidence established that a sequestered form of adenosine triphosphate (ATP pools) resides in the membrane/cytoskeletal complex of red cell porous ghosts. Here, we further characterize the roles these ATP pools can perform in the operation of the membrane's Na+ and Ca2+ pumps. The formation of the Na+- and Ca2+-dependent phosphointermediates of both types of pumps (ENa-P and ECa-P) that conventionally can be labeled with trace amounts of [γ-3P]ATP cannot occur when the pools contain unlabeled ATP, presumably because of dilution of the [γ-3P]ATP in the pool. Running the pumps forward with either Na+ or Ca2+ removes pool ATP and allows the normal formation of labeled ENa-P or ECa-P, indicating that both types of pumps can share the same pools of ATP. We also show that the halftime for loading the pools with bulk ATP is 10–15 minutes. We observed that when unlabeled “caged ATP” is entrapped in the membrane pools, it is inactive until nascent ATP is photoreleased, thereby blocking the labeled formation of ENa-P. We also demonstrate that ATP generated by the membrane-bound pyruvate kinase fills the membrane pools. Other results show that pool ATP alone, like bulk ATP, can promote the binding of ouabain to the membrane. In addition, we found that pool ATP alone functions together with bulk Na+ (without Mg2+) to release prebound ouabain. Curiously, ouabain was found to block bulk ATP from entering the pools. Finally, we show, with red cell inside-outside vesicles, that pool ATP alone supports the uptake of 45Ca by the Ca2+ pump, analogous to the Na+ pump uptake of 22Na in this circumstance. Although the membrane locus of the ATP pools within the membrane/cytoskeletal complex is unknown, it appears that pool ATP functions as the proximate energy source for the Na+ and Ca2+ pumps.