Calcium-mediated regulation of recombinant hybrids of full-length Physarum myosin heavy chain with Physarum/scallop myosin light chains.

Physarum myosin is a Ca(2+)-binding protein and its activity is inhibited by Ca(2+) In the present study, to clarify the light chains (LCs) from the different species (Physarum and scallop) and to determine the specific Ca(2+)-regulated effects, we constructed hybrid myosins with a Physarum myosin heavy chain (Ph·HC) and Physarum and/or scallop myosin LCs, and examined Ca(2+)-mediated regulation of ATPases and motor activities. In these experiments, it was found that Ca(2+) inhibited motilities and ATPase activities of Physarum hybrid myosin with scallop regulatory light chain (ScRLC) and Physarum essential light chain (PhELC) but could not inhibit those of the Physarum hybrid myosin mutant Ph·HC/ScRLC/PhELC-3A which lacks Ca(2+)-binding ability, indicating that PhELC plays a critical role in Ca(2+)-mediated regulation of Physarum myosin. Furthermore, the effects of Ca(2+) on ATPase activities of Physarum myosin constructs are in the following order: Ph·HC/PhRLC/PhELC > Ph·HC/ScRLC/PhELC > Ph·HC/PhRLC/ScELC > Ph·HC/ScRLC/ScELC, suggesting that the presence of PhRLC and PhELC leads to the greatest Ca(2+) sensitivity of Physarum myosin. Although we did not observe the motilities of Physarum hybrid myosin Ph·HC/PhRLC/ScELC and Ph·HC/ScRLC/ScELC, our results suggest that Ca(2+)-binding to the PhELC may alter the flexibility of the regulatory domain and induce a 'closed' state, which may consequently prevent full activity and force generation.

Calcium-dependent regulation of the motor activity of recombinant full-length Physarum myosin.

We successfully synthesized full-length and the mutant Physarum myosin and heavy meromyosin (HMM) constructs associated with Physarum regulatory light chain and essential light chain (PhELC) using Physarum myosin heavy chain in Sf-9 cells, and examined their Ca(2+)-mediated regulation. Ca(2+) inhibited the motility and ATPase activities of Physarum myosin and HMM. The Ca(2+) effect is also reversible at the in vitro motility of Physarum myosin. We demonstrated that full-length myosin increases the Ca(2+) inhibition more effectively than HMM. Furthermore, Ca(2+) did not affect the motility and ATPase activities of the mutant Physarum myosin with PhELC that lost Ca(2+)-binding ability. Therefore, we conclude that PhELC plays a critical role in Ca(2+)-dependent regulation of Physarum myosin.

Sphingosylphosphorylcholine induces stress fiber formation via activation of Fyn-RhoA-ROCK signaling pathway in fibroblasts.

Sphingosylphosphorylcholine (SPC), a bioactive sphingolipid, has recently been reported to modulate actin cytoskeleton rearrangement. We have previously demonstrated Fyn tyrosine kinase is involved in SPC-induced actin stress fiber formation in fibroblasts. However, Fyn-dependent signaling pathway remains to be elucidated. The present study demonstrates that RhoA-ROCK signaling downstream of Fyn controls stress fiber formation in SPC-treated fibroblasts. Here, we found that SPC-induced stress fiber formation was inhibited by C3 transferase, dominant negative RhoA or ROCK. SPC activated RhoA, which was blocked by pharmacological inhibition of Fyn activity or dominant negative Fyn. Constitutively active Fyn (ca-Fyn) stimulated stress fiber formation and localized with F-actin at the both ends of stress fibers, both of which were prevented by Fyn translocation inhibitor eicosapentaenoic acid (EPA). In contrast, inhibition of ROCK abolished only the formation of stress fibers, without affecting the localization of ca-Fyn. These results allow the identification of the molecular events downstream SPC in stress fiber formation for a better understanding of stress fiber formation involving Fyn.

Calcium regulation of the ATPase activity of Physarum and scallop myosins using hybrid smooth muscle myosin: the role of the essential light chain.

To examine the role of two light chains (LCs) of the myosin II on Ca2+ regulation, we produced hybrid heavy meromyosin (HMM) having LCs from Physarum and/or scallop myosin using the smooth muscle myosin heavy chain. Ca2+ inhibited motility and ATPase activity of hybrid HMMs with LCs from Physarum myosin but activated those of hybrid HMM with LCs from scallop myosin, indicating an active role of LCs. ATPase activity of hybrid HMMs with LCs from different species showed the same effect by Ca2+ even though they did not support motility. Our results suggest that communication between the original combinations of LC is important for the motor function.

Involvement of Fyn tyrosine kinase in actin stress fiber formation in fibroblasts.

Lysophosphatidic acid (LPA) and sphingosylphosphorylcholine (SPC) activated Fyn tyrosine kinase and induced stress fiber formation, which was blocked by pharmacological inhibition of Fyn, gene silencing of Fyn, or dominant negative Fyn. Overexpressed constitutively active Fyn localized at both ends of F-actin bundles and triggered stress fiber formation, only the latter of which was abolished by Rho-kinase (ROCK) inhibition. SPC, but not LPA, induced filopodia-like protrusion formation, which was not mediated by Fyn and ROCK. Thus, Fyn appears to act downstream of LPA and SPC to specifically stimulate stress fiber formation mediated by ROCK in fibroblasts.

Myosin light chain kinase stimulates smooth muscle myosin ATPase activity by binding to the myosin heads without phosphorylating the myosin light chain.

Myosin light chain kinase (MLCK) is a multifunctional regulatory protein of smooth muscle contraction [IUBMB Life 51 (2001) 337, for review]. The well-established mode for its regulation is to phosphorylate the 20 kDa myosin light chain (MLC 20) to activate myosin ATPase activity. MLCK exhibits myosin-binding activity in addition to this kinase activity. The myosin-binding activity also stimulates myosin ATPase activity without phosphorylating MLC 20 [Proc. Natl. Acad. Sci. USA 96 (1999) 6666]. We engineered an MLCK fragment containing the myosin-binding domain but devoid of a catalytic domain to explore how myosin is stimulated by this non-kinase pathway. The recombinant fragment thus obtained stimulated myosin ATPase activity by V(max)=5.53+/-0.63-fold with K(m)=4.22+/-0.58 microM (n=4). Similar stimulation figures were obtained by measuring the ATPase activity of HMM and S1. Binding of the fragment to both HMM and S1 was also verified, indicating that the fragment exerts stimulation through the myosin heads. Since S1 is in an active form regardless of the phosphorylated state of MLC 20, we conclude that the non-kinase stimulation is independent of the phosphorylating mode for activation of myosin.

Comparison of the sequences of Turbo and Sulculus indoleamine dioxygenase-like myoglobin genes.

Some archaeogastropodic molluscs, including Sulculus and Turbo, contain an unusual approximately 40 kDa myoglobin in their buccal masses. This myoglobin can bind oxygen reversibly, but has a lower oxygen affinity than vertebrate and invertebrate myoglobins. Amino acid sequences clearly show that Sulculus and Turbo myoglobins evolved not from the globin gene but from the gene for indoleamine dioxygenase (IDO), a tryptophan-degrading enzyme. The Turbo myoglobin gene has been determined to consist of 14 exons and 13 introns. Compared with the known Sulculus IDO-like myoglobin gene, all splice junctions except two are conserved exactly between the two genes. The exon/intron organization of these myoglobin genes is also highly homologous with human IDO (ten exon/nine intron structure); splice junctions of six introns were exactly conserved among the three genes, suggesting that these introns have been conserved for at least 600 million years. To look for putative IDO genes in Turbo or Sulculus, we re-examined the genomic DNA fragments amplified by PCR in full detail, and found intron 2 in two distinct Sulculus fragments (A and B). Fragment A with a 576 bp intron corresponded exactly to the myoglobin gene of Sulculus. On the other hand, fragment B, containing a 239 bp intron, differed significantly from fragment A in nucleotide and translated amino acid sequences. Detailed sequence comparison suggests that fragment B may be derived from a putative IDO gene of Sulculus.