A simple method for determining the ligand affinity toward a zinc-enzyme model by using a TAMRA/TAMRA interaction.

Thiolate coordination to zinc(ii) ions occurs widely in such functional biomolecules as zinc enzymes or zinc finger proteins. Here, we introduce a simple method for determining the affinity of ligands toward the zinc-enzyme active-center model tetramethylrhodamine (TAMRA)-labeled 1,4,7,10-tetraazacyclododecane (cyclen)-zinc(ii) complex (TAMRA-ZnL). The 1 : 1 complexation of TAMRA-labeled cysteine (TAMRA-Cys) with TAMRA-ZnL (each at 2.5 µM), in which the TAMRA moieties approach one another closely, induces remarkable changes in the visible absorption and fluorescence spectra at pH 7.4 and 25 °C. The 1 : 1 complex formation constant (K = [thiolate-bound zinc(ii) complex]/[uncomplexed TAMRA-ZnL][uncomplexed TAMRA-Cys], M-1) was determined to be 106.7 M-1 from a Job's plot of the absorbances at 552 nm. By a ligand-competition method with the 1 : 1 complexation equilibrium, analogous K values for thiol-containing ligands, such as N-acetyl-l-cysteine, l-glutathione, and N-acetyl-l-cysteinamide, were evaluated to have similar values of about 104 M-1. As a result of the ligand affinities to TAMRA-ZnL, nonlabeled zinc(ii)-cyclen induced remarkable stabilization of the reduced form of l-glutathione and a cysteine-containing enolase peptide to aerial oxidation in aqueous solution at pH 7.4 and 25 °C.

TAMRA/TAMRA Fluorescence Quenching Systems for the Activity Assay of Alkaline Phosphatase.

We introduce two types of fluorescence-quenching assay for alkaline phosphatases (APs) by using a carboxytetramethyl-rhodamine (TAMRA)-labeled phosphate-binding tag molecule (TAMRA-Phos-tag). In the first assay, TAMRA-labeled O-phosphorylethanolamine (TAMRA-PEA) was used as an artificial AP-substrate. TAMRA-Phos-tag specifically captured TAMRA-PEA to form a 1:1 complex at pH 7.4; the intensity of the fluorescence peak of the complex at 580 nm (λex = 523 nm) was significantly reduced to 32% of the average value for the two individual components as a result of the mutual approach of the TAMRA moieties. As TAMRA-PEA was dephosphorylated by AP, the resulting TAMRA-labeled ethanolamine dissociated and the fluorescence increased in a manner dependent on the AP dose and the time. In the second assay, pyrophosphate (PP), a natural AP-substrate, was used as a bridging ligand to form a dimeric TAMRA-Phos-tag complex. The dimerization reduced the fluorescence intensity to 49% of that in the absence of PP. As pyrophosphate was hydrolyzed to two orthophosphate moieties by AP, the 580-nm fluorescence recovered in a time-dependent manner. By examining the initial slope of this time-dependent fluorescence recovery, we succeeded in evaluating the 50% inhibitory concentrations of orthovanadate toward two AP isozymes under near-physiological conditions.

A novel thiol-affinity micropipette tip method using zinc(II)-cyclen-attached agarose beads for enrichment of cysteine-containing molecules.

Cysteine-containing biomolecules are attractive targets in the study of thiol biology. Here we introduce a novel method for the selective enrichment of thiol-containing molecules using a thiol-capture zinc(II) complex of 1,4,7,10-tetraazacyclododecane (Zn(2+)-cyclen). Recognition of N-acetylcysteine amide by Zn(2+)-cyclen has been studied by potentiometric pH titration, revealing formation of a 1:1 thiolate-bound Zn(2+)-cyclen complex with a large thiolate-affinity constant of 10(6.2)M(-1) at 25°C and I=0.10M (NaCl). The Zn(2+)-bound thiolate anion is unexpectedly stable in aqueous solution at pH 7.8 under atmospheric conditions for a few days. These findings have contributed to the development of a convenient method for separation of thiol compounds by using a micropipette tip. A 200µL micropipette tip containing 10µL of hydrophilic cross-linked agarose beads attached to Zn(2+)-cyclen moieties was prepared. All steps for thiol-affinity separation (binding, washing, and eluting) are conducted using aqueous buffers at room temperature. The entire separation protocol requires less than 15min per sample. We demonstrate practical example separations of cysteine-containing molecules. This micropipette tip method would be used preferentially as an alternative to existing tools for reliable enrichment of thiol-containing molecules.

Profiling of protein thiophosphorylation by Phos-tag affinity electrophoresis: evaluation of adenosine 5'-O-(3-thiotriphosphate) as a phosphoryl donor in protein kinase reactions.

Adenosine 5'-O-(3-thiotriphosphate) (ATPγS) has been widely used as a phosphoryl donor to trace protein kinase activities. However, the question remains whether particular kinases accept ATPγS as readily as they accept natural ATP. We investigated the characteristics of several kinase reactions in the presence of ATPγS by using Phos-tag affinity electrophoresis. The Phos-tag gel permitted quantitative analysis of thiophosphorylated proteins produced by kinase reactions in vitro and it identified differences in the efficiencies of utilization of ATPγS and ATP in these reactions. Using the method, we evaluated the utility of ATPγS as a phosphoryl donor in studies on bacterial two-component systems. Histidine kinases accepted ATPγS as readily as they accepted ATP in autophosphorylation reactions. However, downstream phosphotransfer reactions with ATPγS were markedly slower than the corresponding reactions with ATP. In an analysis of the sluggish thiophosphate transfer, we found that detergent-denatured thiophosphorylated histidine kinases gradually hydrolyzed at the P-N bond, even at neutral pH, during incubation for 24 h, whereas the native form of the thiophosphorylated enzymes were much more stable. Profiling of protein thiophosphorylation by using Phos-tag affinity electrophoresis might provide new insights into the characteristics of various types of kinase reactions with ATPγS.