The adenosine-triphosphatase activity of desensitized actomysin

1. A simple procedure involving repeated washings of actomyosin, extracted as the complex from myofibrils (natural actomyosin) at ionic strength less than 0.002, is described for the preparation of a desensitized actomyosin. 2. The Mg(2+)-activated adenosine triphosphatase of natural actomyosin was markedly inhibited by ethylenedioxybis(ethyleneamino)tetra-acetic acid, whereas that of the desensitized actomyosin was unaffected. 3. The activity of the Ca(2+)-activated adenosine triphosphatase of natural actomyosin was generally lower than that of the Mg(2+)-activated adenosine triphosphatase, whereas in the desensitized actomyosin the difference between the activities was considerably less. In both natural and desensitized actomyosin the adenosine-triphosphatase activities in the presence of Mg(2+) were similar. 4. The conversion of the natural into the desensitized actomyosin was accompanied by the removal of a protein fraction containing the factors responsible for the sensitivity to ethylenedioxybis(ethyleneamino)tetra-acetic acid and for modifying the Ca(2+)-activated adenosine triphosphatase. When added to a desensitized actomyosin this fraction effected a reversal to the natural form. The recombination was facilitated by increasing the ionic strength of the medium. The two factors showed different stabilities to heat and tryptic digestion.     

The C. elegans unc-104 gene encodes a putative kinesin heavy chain-like protein.

Mutations in the unc-104 gene of the nematode C. elegans result in uncoordinated and slow movement. Transposon insertions in three unc-104 alleles (e2184, rh1016, and rh1017) were used as physical markers to clone the unc-104 gene. DNA sequence analysis of unc-104 cDNAs revealed an open reading frame capable of encoding a 1584 amino acid protein with similarities to kinesin heavy chain. The similarities are greatest in the amino-terminal ATPase and microtubule-binding domains. Although the primary sequence relatedness to kinesin is weak in the remainder of the molecule, the predicted secondary structure and regional isoelectric points are similar to kinesin heavy chain.     

Myosin Loop 2 Is Involved in the Formation of a Trimeric Complex of Twitchin, Actin, and Myosin

Molluscan smooth muscles exhibit a low energy cost contraction called catch. Catch is regulated by twitchin phosphorylation and dephosphorylation. Recently, we found that the D2 fragment of twitchin containing the D2 site (Ser-4316) and flanking immunoglobulin motifs (TWD2-S) formed a heterotrimeric complex with myosin and with actin in the region that interacts with myosin loop 2 (Funabara, D., Hamamoto, C., Yamamoto, K., Inoue, A., Ueda, M., Osawa, R., Kanoh, S., Hartshorne, D. J., Suzuki, S., and Watabe, S. (2007) J. Exp. Biol. 210, 4399–4410). Here, we show that TWD2-S interacts directly with myosin loop 2 in a phosphorylation-sensitive manner. A synthesized peptide, CAQNKEAETTGTHKKRKSSA, based on the myosin loop 2 sequence (loop 2 peptide), competitively inhibited the formation of the trimeric complex. Isothermal titration calorimetry showed that TWD2-S binds to the loop 2 peptide with a K_a of (2.44 ± 0.09) × 10⁵ m⁻¹ with two binding sites. The twitchin-binding peptide of actin, AGFAGDDAP, which also inhibited formation of the trimeric complex, bound to TWD2-S with a K_a of (5.83 ± 0.05) × 10⁴ m⁻¹ with two binding sites. The affinity of TWD2-S to actin and myosin was slightly decreased with an increase of pH, but this effect could not account for the marked pH dependence of catch in permeabilized fibers. The complex formation also showed a moderate Ca²⁺ sensitivity in that in the presence of Ca²⁺ complex formation was reduced.Molluscan smooth muscles, such as mussel anterior byssus retractor muscle (ABRM)² and adductor muscle, exhibit a low energy cost phase of tension maintenance termed catch. Catch muscle develops active tension following an increase of the intracellular [Ca²⁺] induced by secretion of acetylcholine. Myosin is activated by direct binding of Ca²⁺ to the regulatory myosin light chain and initiates a relative sliding between thick and thin filaments (1). After a decrease of intracellular [Ca²⁺] to resting levels, the catch state is formed where tension is maintained over long periods of time with little energy consumption (2, 3). Catch tension is abolished by secretion of serotonin and an increase of intracellular [cAMP] with the resulting activation of cAMP-dependent protein kinase and phosphorylation of twitchin (4, 5). Twitchin phosphorylation is required for relaxation of the muscle from catch. For this cycle to repeat, dephosphorylation of twitchin is necessary (6). Thus, in this scheme, twitchin is a major regulator of the catch state.Molluscan twitchin is known as a myosin-binding protein belonging to the titin/connectin superfamily. It is a single polypeptide of 530 kDa containing multiple repeats of immunoglobulin (Ig) and fibronectin type 3-like motifs in addition to a single kinase domain homologous to the catalytic domain of myosin light chain kinase of vertebrate smooth muscle (7). There are several possible phosphorylation sites in molluscan twitchin recognized by cAMP-dependent protein kinase, and two, D1 and D2, have been identified. The D1 phosphorylation site (Ser-1075) is in the linker region between the 7th and 8th Ig motifs (numbering from the N terminus). The D2 site (Ser-4316) is in the linker region between the 21st and 22nd Ig motifs. Additional sites are found close to D1, but are thought not to be vital for catch regulation.The molecular mechanisms underlying development and maintenance of the catch state have been controversial for several years. One theory proposes that catch reflected attached frozen or slowly cycling cross-bridges (8, 9). What distinguished the attached cross-bridge from the detached relaxed state is not clear. Also it was suggested that interactions between thick filaments, other than cross-bridges, or between thin and thick filaments are responsible for the catch contraction (10). In either of the latter cases, the cross-bridge (myosin head) was not involved.Recently we found that a twitchin fragment including the D2 phosphorylation site and its flanking Ig motifs (TWD2-S) interacted with myosin and actin in a phosphorylation-sensitive manner, and it was suggested that this trimeric complex contributed to tension maintenance in catch (11). TWD2-S bound to a region of the actin molecule known also to interact with loop 2 of myosin that is involved in the ATP-driven movement of myosin with actin (12). In the present study, we show that the myosin loop 2 binds to TWD2-S using competitive cosedimentation assays and isothermal titration calorimetry (ITC). These techniques were applied to also study in more detail the interactions of the twitchin-binding peptide of actin (identified in the previous study (11)). In addition, the effects of pH and Ca²⁺ on the binding of TWD2-S to myosin and actin were investigated.     

Quinol-cytochrome c Oxidoreductase and Cytochrome c4 Mediate Electron Transfer during Selenate Respiration in Thauera selenatis

Selenate reductase (SER) from Thauera selenatis is a periplasmic enzyme that has been classified as a type II molybdoenzyme. The enzyme comprises three subunits SerABC, where SerC is an unusual b-heme cytochrome. In the present work the spectropotentiometric characterization of the SerC component and the identification of redox partners to SER are reported. The mid-point redox potential of the b-heme was determined by optical titration (E_m + 234 ± 10 mV). A profile of periplasmic c-type cytochromes expressed in T. selenatis under selenate respiring conditions was undertaken. Two c-type cytochromes were purified (∼24 and ∼6 kDa), and the 24-kDa protein (cytc-Ts4) was shown to donate electrons to SerABC in vitro. Protein sequence of cytc-Ts4 was obtained by N-terminal sequencing and liquid chromatography-tandem mass spectrometry analysis, and based upon sequence similarities, was assigned as a member of cytochrome c₄ family. Redox potentiometry, combined with UV-visible spectroscopy, showed that cytc-Ts4 is a diheme cytochrome with a redox potential of +282 ± 10 mV, and both hemes are predicted to have His-Met ligation. To identify the membrane-bound electron donors to cytc-Ts4, growth of T. selenatis in the presence of respiratory inhibitors was monitored. The specific quinol-cytochrome c oxidoreductase (QCR) inhibitors myxothiazol and antimycin A partially inhibited selenate respiration, demonstrating that some electron flux is via the QCR. Electron transfer via a QCR and a diheme cytochrome c₄ is a novel route for a member of the DMSO reductase family of molybdoenzymes.     

Inhibitory phosphorylation site for Rho-associated kinase on smooth muscle myosin phosphatase

It is clear from several studies that myosin phosphatase (MP) can be inhibited via a pathway that involves RhoA. However, the mechanism of inhibition is not established. These studies were carried out to test the hypothesis that Rho-kinase (Rho-associated kinase) via phosphorylation of the myosin phosphatase target subunit 1 (MYPT1) inhibited MP activity and to identify relevant sites of phosphorylation. Phosphorylation by Rho-kinase inhibited MP activity and this reflected a decrease in V(max). Activity of MP with different substrates also was inhibited by phosphorylation. Two major sites of phosphorylation on MYPT1 were Thr(695) and Thr(850). Various point mutations were designed for these phosphorylation sites. Following thiophosphorylation by Rho-kinase and assays of phosphatase activity it was determined that Thr(695) was responsible for inhibition. A site- and phosphorylation-specific antibody was developed for the sequence flanking Thr(695) and this recognized only phosphorylated Thr(695) in both native and recombinant MYPT1. Using this antibody it was shown that stimulation of serum-starved Swiss 3T3 cells by lysophosphatidic acid, thought to activate RhoA pathways, induced an increase in Thr(695) phosphorylation on MYPT1 and this effect was blocked by a Rho-kinase inhibitor, Y-27632. In summary, these results offer strong support for a physiological role of Rho-kinase in regulation of MP activity.