The rate-determining steps in the phosphorylation of four tyrosine-containing peptides by the kinase domain of the nonreceptor tyrosine protein kinase v-fps were measured using viscosometric methods. The peptides were phosphorylated by a fusion protein of glutathione-S-transferase and the kinase domain of v-fps (GST-kin) and the initial velocities were determined by a coupled enzyme assay. Peptides I (EEEIYEEIE), II (EAEIYEAIE), and III (DADIYDAID) were phosphorylated by GST-kin with similar kinetic constants. The viscosogens, glycerol and sucrose, were found to have intermediate effects on kcat and no effect on kcat/Kpeptide for the phosphorylation of these three peptides. The data are interpreted according to the Stokes-Einstein equation and a simple three-step mechanism involving substrate binding, phosphoryl group transfer, and net product release. Two competitive inhibitors (EAEIFEAIE and DADIFDAID) exhibited K1 values that are 6-10-fold higher than the Kpeptide values for their analogous peptide substrates. The data imply that peptides I-III are in rapid equilibrium with the enzyme and that kcat is partially limited by both phosphoryl group transfer (40-100 s-1) and product release (17-22 s-1). GST-kin phosphorylates peptide IV (R5AENLEYamide) with a low Km (100 microM) and a kcat that is 40-fold lower than that for peptide I. No effect of solvent viscosity was observed for the phosphorylation of this peptide on either kcat or kcat/Kpeptide. This suggests that highly viscous solutions do not perturb structure and that the rate-determining step for this poor substrate is phosphoryl group transfer. The data indicate that the kinase domain of v-fps phosphorylates its best substrate with a chemical rate constant that is at least 5-fold lower than that for the serine-specific cAMP-dependent protein kinase and its best substrate LRRASLG (Adams & Taylor, 1992). Interestingly, both enzymes exhibit a similar affinity for their substrates and both enzymes release their products at a similar rate. This implies that the differences in catalytic efficiency between serine- and tyrosine-specific protein kinases lie exclusively in the rate constants for phosphoryl group transfer and not in substrate absorption or product desorption.
The activity of the kinase domain of the oncoprotein v-Fps was found to be sensitive to the concentration of magnesium ions. Plots of initial velocity versus free magnesium concentration are hyperbolic and do not extrapolate to the origin at stoichiometric ATP-Mg, indicating that there are two sites for metal chelation on the enzyme and the second is nonessential for catalysis. The second metal is strongly activating and increases the reaction rate constant almost 20-fold from 0.5 to 8.3 s-1 using 0.2 mM ATP-Mg and 1 mM peptide, EAEIYEAIE. This increase in rate is due to a large increase in the apparent affinity of ATP-Mg at high magnesium concentrations. At 0.5 and 10 mM free Mg2+, KATP-Mg is 3.6 and 0.22 mM, respectively. Extrapolation of the observed affinity of ATP-Mg to zero and infinite free metal indicates that KATP-Mg is greater than 8 mM in the absence of the second metal and 0.1 mM in the presence of the second metal, a minimum 80-fold enhancement. By comparison, free levels of the divalent ion do not influence maximum turnover (kcat) and have only a 2-fold effect on the Km for the peptide substrate between 0.5 and 20 mM free Mg2+. Viscosometric studies indicate that free Mg2+ does not influence the rates of phosphoryl transfer or net product release above 0.5 mM but does affect directly the dissociation constant for ATP-Mg. The Kd for ATP-Mg in the absence and presence of the second metal ion is >32 and 0.4 mM, respectively. At high magnesium concentrations, ATP-Mg and the peptide substrate bind independently, while at lower concentrations (0.5 mM), there is significant negative binding synergism suggesting that the second metal may help to reduce charge repulsion between ATP-Mg and the peptide. The data indicate that the first metal is sufficient for phosphoryl transfer. While the second metal could have some influence on phosphoryl transfer or product binding, it is a potent activator that functions minimally by controlling ATP-Mg binding.
A series of novel hybrids from natural product oridonin and nitrogen mustards were designed and synthesized to obtain more efficacious and less toxic antitumor agents. The antiproliferative evaluation showed that most conjugates were more potent than their parent compounds oridonin and clinically used nitrogen mustards against four human cancer cell lines (K562, MCF-7, Bel-7402, and MGC-803). Furthermore, the representative compounds 16a-c exhibited antiproliferative activities against the multidrug resistant cell lines (SW620/AD300 and NCI-H460/MX20). It was shown that the most effective compound 16b possesses a strong inhibitory activity with an IC50 value 21-fold lower than that of oridonin in MCF-7 cells and also exhibits selective cytotoxicity toward the cancer cells. Intriguingly, compound 16b has been demonstrated to significantly induce apoptosis and affect cell cycle progression in human hepatoma Bel-7402 cells.
Single crystalline VO 2 (A) nanowires were synthesized by a facile hydrothermal method. The structural transition and temperature-driven conductivity switching of the VO 2 (A) nanowires were investigated. Our experimental results show that VO 2 (A) nanowires exhibit a distinct structural transition accompanied with an order of magnitude change in resistance, and a clear temperature-dependent current switching hysteresis. In order to analyze experimental results, theoretically, the electrical conductivity behavior was found to be consistent with Mott's small polaron model, the first-principles calculations also indicated that the apical V-O bond changes were mainly responsible for the band gap evolution and hence led to the conductivity switching.
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