Calcium control of macrophage cytoplasmic gelation: evidence for the involvement of the 70,000 Mr actin-bundling protein

Under appropriate conditions macrophage cytosolic extracts can form a three-dimensional gel network of cross-linked actin filaments. These cytoplasmic gels are mainly composed of actin, filamin, alpha-actinin, and two new proteins of about 70,000 and 55,000 Mr (70 and 55 K). The behaviour of 70 K protein was found to be remarkably affected by Ca2+. Ca2+ treatment of isolated cytoplasmic gels led to the selective solubilization of the 70 K protein along with a 17 K polypeptide. Half-maximal recovery in the supernatant fraction was obtained from about 0.15 microM free Ca2+. The cytoplasmic gel constituents solubilized in high ionic strength buffer were able to re-assemble into an insoluble actin network when returned to near physiological ionic conditions. However, the inclusion of micromolar Ca2+ prevented the re-association of 70 K protein with actin in these complexes. As compared to the 70 K protein, alpha-actinin was fully resistant to any variations in Ca2+ concentrations. On the other hand, purified 70 K protein displayed the property of assembling actin filaments into bundles at low Ca2+ concentrations (less than 0.15 microM). However, the bundling activity decreased progressively at higher Ca2+, as detected by co-sedimentation and electron microscopy of the 70 K protein-actin mixtures. Half-maximal inhibition was observed at about 0.3 microM free Ca2+. Re-assembly of actin filaments into bundles occurred after chelation of Ca2+ by EGTA, indicating that the inhibitory effect of Ca2+ was reversible. Severing of actin filaments by 70 K protein was not observed in any of the solution conditions used. The Ca2+-dependent inhibition of the ability of 70 K protein to interact with actin networks resulted in a marked distortion of the overall organization of actin filaments, as revealed by thin-section electron microscopy of cytoplasmic gels formed in the presence and absence of Ca2+. Large zones of oriented bundles of filaments were replaced by a looser mesh. When the actin gel constituents were re-assembled in the presence of Ca2+ and exogenous gelsolin, it was also observed that the filament bundles (essentially generated by alpha-actinin) collapsed into dense aggregates. Furthermore, gelsolin did not significantly affect the ability of actin to re-combine with other proteins. The data presented here and previously led us to suspect that the Ca2+ control of the functional state of 70 K protein might be one of the prime factors in the triggering of rapid assembly and disassembly of microfilaments within macrophages.