Pigment granule translocation in red ovarian chromatophores from the palaemonid shrimp Macrobrachium olfersi (Weigmann, 1836): functional roles for the cytoskeleton and its molecular motors.

The binding of red pigment concentrating hormone (RPCH) to membrane receptors in crustacean chromatophores triggers Ca²âº/cGMP signaling cascades that activate cytoskeletal motors, driving pigment granule translocation. We investigate the distributions of microfilaments and microtubules and their associated molecular motors, myosin and dynein, by confocal and transmission electron microscopy, evaluating a functional role for the cytoskeleton in pigment translocation using inhibitors of polymer turnover and motor activity in vitro. Microtubules occupy the chromatophore cell extensions whether the pigment granules are aggregated or dispersed. The inhibition of microtubule turnover by taxol induces pigment aggregation and inhibits re-dispersion. Phalloidin-FITC actin labeling, together with tannic acid fixation and ultrastructural analysis, reveals that microfilaments form networks associated with the pigment granules. Actin polymerization induced by jasplaquinolide strongly inhibits RPCH-induced aggregation, causes spontaneous pigment dispersion, and inhibits pigment re-dispersion. Inhibition of actin polymerization by latrunculin-A completely impedes pigment aggregation and re-dispersion. Confocal immunocytochemistry shows that non-muscle myosin II (NMMII) co-localizes mainly with pigment granules while blebbistatin inhibition of NMMII strongly reduces the RPCH response, also inducing spontaneous pigment dispersion. Myosin II and dynein also co-localize with the pigment granules. Inhibition of dynein ATPase by erythro-9-(2-hydroxy-3-nonyl) adenine induces aggregation, inhibits RPCH-triggered aggregation, and inhibits re-dispersion. Granule aggregation and dispersion depend mainly on microfilament integrity although microtubules may be involved. Both cytoskeletal polymers are functional only when subunit turnover is active. Myosin and dynein may be the molecular motors that drive pigment aggregation. These mechanisms of granule translocation in crustacean chromatophores share various features with those of vertebrate pigment cells.

The effect of kinase, actin, myosin and dynamin inhibitors on host cell egress by Toxoplasma gondii.

Toxoplasma gondii is a protozoan parasite that can infect the nucleated cells of all warm-blooded animals. Despite its medical and veterinary importance, the egress of T. gondii from host cells has not been fully elucidated. This process is usually studied with calcium ionophores, which artificially trigger T. gondii egress. Among the diverse signaling events that take place during egress, kinases appear to play a crucial role. In this work we employed several kinase inhibitors to examine their role in egress: although parasite egress was only slightly impaired by treatment with the PI3K and PKC inhibitors wortmannin and staurosporine, the addition of the tyrosine kinase-specific inhibitor genistein efficiently blocked the exit of parasites by more than 50%. IPA-3, a non-ATP-competitive inhibitor of p21-activated kinases, which play a role in actin cytoskeleton remodeling inhibited egress of T. gondii by only 15%. The myosin motor inhibitor blebbistatin and the actin polymerization inhibitor cytochalasin D also blocked the egress of T. gondii. Nevertheless, dynasore, which is known to block the GTPase activity of dynamin, had little or no effect on T. gondii egress.

Effects of mercury on myosin ATPase in the ventricular myocardium of the rat.

Mercury reduces twitch and tetanic force development in isolated rat papillary muscles, and a putative toxic effect on the contractile machinery has been suggested. Based on that, the actions of HgCl2 on the myosin ATPase activity of the left ventricular myocardium were investigated. Samples for assay of myosin ATPase activity were obtained from rats' left ventricles. Increasing concentrations of HgCl2 reduced dose-dependently the activity of the myosin ATPase. This reduction was observed even at very small concentrations, 50 nM HgCl2. This effect was dependent on the presence of SH groups in the myosin molecule since DTT and glutathione protected the myosin ATPase against toxic effects of mercury; full activity being restored by using 500 nM DTT or 500 nM glutathione. Results also suggested that the metal acts as an uncompetitive inhibitor with a Ki of 200 nM HgCl2. Our results suggest that mercury reduces the activity of the myosin ATPase by an uncompetitive mechanism at a very low dose that does not depress force. DTT and glutathione are effective for protection against the actions of mercury suggesting that SH groups might be the sites of action of the metal on the myosin molecule.

Regulatory properties of recombinant tropomyosins containing 5-hydroxytryptophan: Ca2+-binding to troponin results in a conformational change in a region of tropomyosin outside the troponin binding site.

We have introduced tryptophan codons at different positions of the chicken alpha-tropomyosin cDNA (Monteiro, P. B., Lataro, R. C., Ferro, J. A., and Reinach, F. C. (1994) J. Biol. Chem. 269, 10461-10466) and employed a trp auxotrophic Escherichia coli strain to express the proteins in media containing either normal tryptophan, 5-hydroxytrptophan, or 7-azatryptophan. The fluorescence of these latter two tryptophan analogues is excitable at 312-315 nm at which the natural fluorescence of other thin filament proteins (actin, troponin) is not excited. The recombinant tropomyosins have tryptophans or analogues located at amino acid positions 90, 101, 111, 122, or 185 of the protein, all on the external surface of the tropomyosin coiled-coil (positions "c" or "f" of the hydrophobic heptad repeat). The first four mutations are located within the third actin-binding zone of tropomyosin, a region not expected to interact directly with troponin or with neighboring tropomyosin molecules in muscle thin filaments, while position 185 is located in a region that has been implicated in interactions with the globular domain of troponin. The fluorescence intensity of the mutant containing 5-hydroxytryptophan at position 122 (5OH122W) is sensitive to actin binding and sensitive to Ca2+-binding to thin filaments reconstituted with troponin. Assuming that the globular domain of troponin binds to a site between residues 150 and 190 of tropomyosin, the distance between the troponin-binding site and the fluorescent probes at position 122 can be estimated to be 4.2-10.2 nm. While X-ray diffraction and electron micrograph reconstitution studies have provided evidence of Ca2+-induced changes in tropomyosin's interactions in the thin filament, their resolution was not sufficient to distinguish between changes involving the whole tropomyosin molecule or only that region directly interacting with troponin. Here we provide a clear demonstration that Ca2+-binding to troponin results in a conformational change in a region of tropomyosin outside the troponin binding site which is probably associated with a changed interaction with actin.

Interaction of heparin with myosin ATPase: possible involvement with the hemorrhagic activity and a correlation with antithrombin III high affinity-heparin molecules.

Up to 50% of [35S]-heparin molecules prepared from rat skin bind to rabbit muscle myosin ATPase, in a concentration dependent manner, producing a stable complex with a dissociation constant of 3 x 10(-7) M. The [35S]-heparin in the complex has a distinct electrophoretic behaviour and is precipitated by TCA together with myosin. Other [35S]-glycosaminoglycans, namely, heparan sulfate, dermatan sulfate and chondroitin sulfate also prepared from rat tissues are unable to form complexes with the enzyme. Among the sulfated glycosaminoglycans obtained from different sources only heparin is able to displace the bound [35S]-heparin from the ATPase. Heparin with high affinity for antithrombin III, prepared by antithrombin-affinity chromatography, dislodges up to 90% of the bound [35S]-heparin. Furthermore, antithrombin III-high affinity heparin shows a high affinity for myosin ATPase when compared to antithrombin III-low affinity heparin which shows a low affinity for the enzyme. It is also shown that myosin ATPase inhibits the "in vitro" plasma anticoagulant activity of heparin. These are suggestive that the special structure of the heparin molecules needed for the binding to antithrombin and myosin ATPase bears important similarities. The mechanism of the hemorrhagic effect of heparin is discussed in view of these interactions.

Dependence of the C-6 sulfate of the glucosamine moiety and 1----4 glycosidic linkage of heparin disaccharides for production of hemorrhage: reversal of the antihemostatic activity of heparin and their fragments by adenosine triphosphate and myosin.

Topical application or intraperitoneal injection of heparin and heparin oligosaccharides produces a potent inhibition of skin hemostasis. Studies conducted with disaccharides derived from heparin, heparan sulfate, and chondroitin sulfates have shown that delta-4,5-uronyl-(1----4)-glucosamine, bearing a sulfate at the C-6 position of the glucosamine residue, is the minimum structure for the antihemostatic activity. The disaccharides with this basic structure produce uncontrollable hemorrhage from small blood vessels, similar to that observed for heparin. The finding that other sulfated disaccharides, with the same sulfate to hexosamine to uronic acid ratios but with the sulfate at a different position (C-2) or with a different glycosidic linkage (1----3), were inactive as inhibitors of hemostasis indicates that a specific structure is needed to produce the effect. The inhibitory activity of the normal hemostatic process produced by heparin and its products could be reversed either by ATP or myosin. Molecular models show that part of the disaccharide inhibitors and ATP have a similar structural conformation.