Excited state properties of the siderophore pyochelin and its complex with zinc ions.

The critical effects of pH on the electronic absorption and fluorescence characteristics of the siderophore, pyochelin, are investigated. A single anionic species is shown to be sufficient to explain the data obtained under alkaline conditions. In acidic solutions, several competing ground- and excited-state equilibria are present, which lead to fluorescence emissions from both the protonated form of pyochelin and its phenolate ion. From the spectroscopic data we are also able to show that pyochelin interacts with zinc ions in the ground state via its anionic form, thereby confirming that this siderophore does not bind Fe(III) ions uniquely.

Bound plasminogen is rate-limiting for cell-surface-mediated activation of plasminogen by urokinase.

The ability of U937 monocyte-like cells and KATO III cells (a human gastric carcinoma line) to potentiate activation of plasminogen by single-chain urokinase-type plasminogen activator (scu-PA), as mediated by the cell receptor for urokinase (u-PAR), was compared. It was observed that, although the concentration of u-PAR on these cell lines differed considerably (U937 cells: 5000 receptors/cell, Kd 0.35 nM; KATO III cells: 400 receptors/cell, Kd 0.85 nM), the rate of activation of plasminogen by scu-PA in the presence of the same density of each cell line was equivalent. From data generated in the presence of increasing concentrations of scu-PA, the kcat, for plasminogen activation in the presence of each cell line was calculated and found to differ by 26-fold (0.36 s-1 on U937 cells; 9.25 s-1 on KATO III cells). However, the Km for plasminogen with respect to the rate of formation of plasmin was lower than the Kd for binding (0.2 microM compared with 0.5 microM on U937 cells; 0.34 microM compared with 1.6 microM on KATO III cells). A rapid transformation from Glu-plasminogen (native plasminogen with N-terminal Glu) to Lys-plasminogen (plasmin-degraded plasminogen with primarily N-terminal Lys-77) occurred on the surface of U937 cells (unlike KATO III cells), but this transition did not coincide with faster rates of plasminogen activation. From this evidence it is concluded that the accessibility of bound plasminogen acts to limit the rate of activation by cell-bound urokinase. The significance of this proposal is that the proteolytic potential of the cell-mediated activation of plasminogen would be controlled by the accessibility of plasminogen for activation rather than by the concentration of u-PAR (the latter may act to localize proteolysis to appropriate domains on the surface of the cell).

Increased expression of procoagulant activity on the surface of human platelets exposed to heavy-metal compounds.

One of the essential roles for platelets in haemostasis is in the potentiation of blood clotting due to the contribution of anionic phospholipid from the surface of the cells, as an essential cofactor to the proteolytic reactions of coagulation (platelet procoagulant activity). Only a limited number of agonists are known to initiate platelet procoagulant activity. In this study the rate of thrombin formation on the platelet surface was observed to increase in a dose-dependent manner upon treatment of washed platelets with heavy-metal compounds. Unlike the immediate increase observed upon treatment of platelets with calcium ionophore, A23187, the change due to these agents was progressive, approaching a maximum after 10 min. The maximum-fold acceleration of the rate of thrombin formation compared with control platelets was calculated for HgCl2 (56-fold), AgNO3 (42-fold) phenylmercuriacetate (24-fold) and thimerosal (14-fold), compared with 70-fold observed for calcium ionophore. The increase in procoagulant activity due to HgCl2 coincided with a large increase in intracellular calcium and phosphorylation of 22 and 45 kDa proteins. It is considered that the mechanism responsible for the increase in procoagulant activity is exposure of anionic phospholipids. This was detected by a 2-fold increase in the binding of 125I-annexin V upon addition of HgCl2, compared with resting platelets (3-fold on treatment of platelets with calcium ionophore). In contrast to the generation of activity by A23187 and other known agonists of this reaction, heavy-metal compounds appeared to cause little or no release of microparticles from the platelet surface. Since HgCl2 did not cause aggregation of platelets or significant release of serotinin, these findings may give further support to the need for exposure and ligation of glycoprotein IIb:IIIa for vesiculization to occur. Treatment of platelets with heavy metals may constitute a new approach to investigating the early changes in the cell membrane which lead to increased expression of anionic phospholipid.

Use of HPLC to demonstrate variation of venom toxin composition in the Thailand cobra venoms Naja naja kaouthia and Naja naja siamensis.

The composition of the venoms of Naja naja kaouthia and Naja naja siamensis from different commercial sources has been investigated using both ion-exchange and reverse-phase high-pressure liquid chromatography (RP-HPLC) in order to investigate variation in toxin contents. The venoms contained identical major toxin components, although in different relative concentrations. The venom collected separately from the left and right glands of individual snakes were virtually the same as judged by RP-HPLC. The cytotoxin CT-II, which was previously only reported to be present in Naja naja siamensis venom, was detected in all the venoms investigated. Two long neurotoxin homologues have also been isolated.