Mechanism of the Ca²+-dependent interaction between S100A4 and tail fragments of nonmuscle myosin heavy chain IIA.

The interaction between the calcium-binding protein S100A4 and the C-terminal fragments of nonmuscle myosin heavy chain IIA has been studied by equilibrium and kinetic methods. Using site-directed mutants, we conclude that Ca(2+) binds to the EF2 domain of S100A4 with micromolar affinity and that the K(d) value for Ca(2+) is reduced by several orders of magnitude in the presence of myosin target fragments. The reduction in K(d) results from a reduced dissociation rate constant (from 16 s(-1) to 0.3 s(-1) in the presence of coiled-coil fragments) and an increased association rate constant. Using peptide competition assays and NMR spectroscopy, we conclude that the minimal binding site on myosin heavy chain IIA corresponds to A1907-G1938; therefore, the site extends beyond the end of the coiled-coil region of myosin. Electron microscopy and turbidity assays were used to assess myosin fragment filament disassembly by S100A4. The latter assay demonstrated that S100A4 binds to the filaments and actively promotes disassembly rather than just binding to the myosin monomer and displacing the equilibrium. Quantitative modelling of these in vitro data suggests that S100A4 concentrations in the micromolar region could disassemble myosin filaments even at resting levels of cytoplasmic [Ca(2+)]. However, for Ca(2+) transients to be effective in further promoting dissociation, the elevated Ca(2+) signal must persist for tens of seconds. Fluorescence recovery after photobleaching of A431/SIP1 cells expressing green fluorescent protein-myosin IIA, immobilised on fibronectin micropatterns to control stress fibre location, yielded a recovery time constant of around 20 s, consistent with in vitro data.

Protonation, photobleaching, and photoactivation of yellow fluorescent protein (YFP 10C): a unifying mechanism.

Yellow fluorescent protein (YFP 10C) is widely used as a probe in biology, but its complex photochemistry gives rise to unusual behavior that requires fuller definition. Here we characterize the kinetics of protonation and reversible bleaching over time scales of picoseconds to hours. Stopped-flow and pressure-jump techniques showed that protonation of the fluorescent YFP(-) anion state is two-step with a slow transition that accounts for blinking of 527 nm emission at the single molecule level on the seconds time scale. Femtosecond spectroscopy revealed that the protonated excited-state (YFPH*) decayed predominantly by a radiationless mechanism, but emission at 460 nm was detected within the first picosecond. Limited excited-state proton transfer leads to 527 nm emission characteristic of the YFP(-*) anion. Prolonged continuous wave illumination at the peak of YFP(-) absorbance (514 nm) yields, irreversibly, a weakly fluorescent product that absorbs at 390 nm. This "photobleaching" process also gives a different species (YFPHrb) that absorbs at 350/430 nm and spontaneously regenerates YFP(-) in the dark on the time scale of hours but can be photoactivated by UV light to regenerate YFP(-) within seconds, via a ground-state protonated intermediate. Using a pulsed laser for photobleaching resulted in decarboxylation of YFP as indicated by the mass spectrum. These observations are accounted for in a unifying kinetic scheme.

Phosphatidylinositol phosphate kinase type 1gamma and beta1-integrin cytoplasmic domain bind to the same region in the talin FERM domain.

Talin is an essential component of focal adhesions that couples beta-integrin cytodomains to F-actin and provides a scaffold for signaling proteins. Recently, the integrin beta3 cytodomain and phosphatidylinositol phosphate (PIP) kinase type 1gamma (a phosphatidylinositol 4,5-bisphosphate-synthesizing enzyme) were shown to bind to the talin FERM domain (subdomain F3). We have characterized the PIP kinase-binding site by NMR using a 15N-labeled talin F2F3 polypeptide. A PIP kinase peptide containing the minimal talin-binding site formed a 1:1 complex with F2F3, causing a substantial number of chemical shift changes. In particular, two of the three Arg residues (Arg339 and Arg358), four of eight Ile residues, and one of seven Val residues in F3 were affected. Although a R339A mutation did not affect the exchange kinetics, R358A or R358K mutations markedly weakened binding. The Kd for the interaction determined by Trp fluorescence was 6 microm, and the R358A mutation increased the Kd to 35 microm. Comparison of these results with those of the crystal structure of a beta3-integrin cytodomain talin F2F3 chimera shows that both PIP kinase and integrins bind to the same surface of the talin F3 subdomain. Indeed, binding of talin present in rat brain extracts to a glutathione S-transferase integrin beta1-cytodomain polypeptide was inhibited by the PIP kinase peptide. The results suggest that ternary complex formation with a single talin FERM domain is unlikely, although both integrins and PIP kinase may bind simultaneously to the talin anti-parallel dimer.

Mechanistic aspects of the covalent flavoprotein dimethylglycine oxidase of Arthrobacter globiformis studied by stopped-flow spectrophotometry.

Dimethylglycine oxidase (DMGO) is a covalent flavoenzyme from Arthrobacter globiformis that catalyzes the oxidative demethylation of dimethylglycine to yield sarcosine, formaldehyde, and hydrogen peroxide. Stopped-flow and steady-state kinetic studies have been used to study the reductive and oxidative half-reactions using dimethylglycine and O2 as substrates. The reductive half-reaction is triphasic. The rate of the fast phase is dependent on substrate concentration, involves flavin reduction, and has a limiting rate constant of 244 s(-1). This phase also displays a kinetic isotope effect of 2.9. Completion of the first kinetic phase generates an intermediate with broad spectral signature between 350 and 500 nm, which is attributed to a reduced enzyme-iminium charge-transfer species, similar to the purple intermediate that accumulates in reactions of D-amino acid oxidase (DAAO) with alanine. The second phase (16 s(-1)) is independent of substrate concentration and is attributed to iminium hydrolysis/deprotonation. The third phase (2 s(-1)) is attributed to product release, the rate of which is less than the steady-state turnover rate (10.6 s(-1)). Flavin oxidation of dithionite- and dimethylglycine-reduced enzyme by O2 occurs in a single phase, and the rate shows a linear dependence on oxygen concentration, giving bimolecular rate constants of 342 and 201 mM(-1) x s(-1), respectively. Enzyme-monitored turnover experiments indicate that decay of the reduced enzyme-iminium intermediate is rate-limiting, consistent with rate constants determined from single turnover studies. A minimal kinetic mechanism is presented, which establishes a close relationship to the mechanism of action of DAAO. The covalent flavin in dimethylglycine oxidase is identified as an alphaN1-histidyl48-FAD, and equilibrium titration studies establish a single redox center that displays typical flavoprotein 'oxidase' characteristics.