Occurrence of caldesmon (a calmodulin-binding protein) in cultured cells: comparison of normal and transformed cells.

Caldesmon is a calmodulin-binding and F-actin-binding protein originally purified from chicken gizzard smooth muscle. This protein binds to F-actin filaments in a Ca2+- and calmodulin-dependent "flip-flop" fashion, thereby regulating the function of actin filaments. Here we report that various lines of cultured cells contain a Mr 77,000 protein that specifically reacts with the affinity-purified caldesmon antibody raised against chicken gizzard caldesmon . Among the fibroblast proteins that had been pulse-labeled with [35S]methionine, the Mr 77,000 protein was the only protein band detected on the NaDodSO4 gel that reacted with the anticaldesmon . The subcellular distribution of the Mr 77,000 protein was investigated by the indirect immunofluorescence technique using the anticaldesmon . In all fibroblast cell lines examined, the immunofluorescence localized along the cellular stress fibers and in leading edges of the cell. In Rous sarcoma virus-transformed cells (S7-1), however, the distribution of the fluorescence changed to a diffuse and blurred appearance. These staining patterns of anticaldesmon obtained with the normal and transformed cells coincided with those of antiactin in the corresponding states, strongly suggesting the functional linkage between the Mr 77,000 protein and actin filaments. We propose to refer to this Mr 77,000 protein as caldesmon 77. The cellular level of caldesmon 77 in transformed S7-1 cells decreased to about one-third of that in their normal counterparts (cell line no. 7). Essentially the same result was obtained with normal rat kidney cells infected with the temperature-sensitive transformation mutant Schmidt-Ruppin strain of Rous sarcoma virus (68 N2 clone). The cellular level of caldesmon 77 observed at a permissive temperature (35 degrees C) was about one-third of that at a nonpermissive temperature (38.5 degrees C). These changes of caldesmon 77 in transformed cells may correlate with the loss of Ca2+ regulation in the transformed state.