Forcing the reversibility of a mechanochemical reaction.

Mechanical force modifies the free-energy surface of chemical reactions, often enabling thermodynamically unfavoured reaction pathways. Most of our molecular understanding of force-induced reactivity is restricted to the irreversible homolytic scission of covalent bonds and ring-opening in polymer mechanophores. Whether mechanical force can by-pass thermodynamically locked reactivity in heterolytic bimolecular reactions and how this impacts the reaction reversibility remains poorly understood. Using single-molecule force-clamp spectroscopy, here we show that mechanical force promotes the thermodynamically disfavored SN2 cleavage of an individual protein disulfide bond by poor nucleophilic organic thiols. Upon force removal, the transition from the resulting high-energy unstable mixed disulfide product back to the initial, low-energy disulfide bond reactant becomes suddenly spontaneous, rendering the reaction fully reversible. By rationally varying the nucleophilicity of a series of small thiols, we demonstrate how force-regulated chemical kinetics can be finely coupled with thermodynamics to predict and modulate the reversibility of bimolecular mechanochemical reactions.

Development of a Reagentless Biosensor for Inorganic Phosphate, Applicable over a Wide Concentration Range.

A fluorescent reagentless biosensor for inorganic phosphate (Pi), based on the E. coli PstS phosphate binding protein, was redesigned to allow measurements of higher Pi concentrations and at low, substoichiometric concentrations of biosensor. This was achieved by weakening Pi binding of the previous biosensor, and different approaches are described that could enable this change in properties. The readout, providing response to the Pi concentration, is delivered by tetramethylrhodamine fluorescence. In addition to two cysteine mutations for rhodamine labeling at positions 17 and 197, the final variant had an I76G mutation in the hinge region between the two lobes that make up the protein. Upon Pi binding, the lobes rotate on this hinge and the mutation on the hinge lowers affinity ∼200-fold, with a dissociation constant now in the tens to hundreds micromolar range, depending on solution conditions. The signal change on Pi binding was up to 9-fold, depending on pH. The suitability of the biosensor for steady-state ATPase assays was demonstrated with low biosensor usage and its advantage in ability to cope with Pi contamination.

Hydrodynamic characterization of the SufBC and SufCD complexes and their interaction with fluorescent adenosine nucleotides.

Bacteria, as well as the plastid organelles of algae and higher plants, utilize proteins of the suf operon. These are involved in Fe-S cluster assembly, particularly under conditions of iron limitation or oxidative stress. Genetic experiments in some organisms found that the ATPase SufC is essential, though its role in Fe-S biogenesis remains unclear. To ascertain how interactions with other individual Suf proteins affect the activity of SufC we coexpressed it with either SufB or SufD from Thermotoga maritima and purified the resulting SufBC and SufCD complexes. Analytical ultracentrifuge and multiangle light-scattering measurements showed that the SufBC complex exists in solution as the tetrameric SufB(2)C(2) species, whereas SufCD exists as an equilibrium mixture of SufCD and SufC(2)D(2). Transient kinetic studies of the complexes were made using fluorescent 2'(3')-O-(N-methylanthraniloyl-(mant) analogues of ATP and ADP. Both SufBC and SufCD bound mantATP and mantADP much more tightly than does SufC alone. Compared to the cleavage step of the mantATPase of SufC alone, that of SufBC was accelerated 180-fold and that of SufCD only fivefold. Given that SufB and SufD have 20% sequence identity and similar predicted secondary structures, the different hydrodynamic properties and kinetic mechanisms of the two complexes are discussed.

Structural basis for AMP binding to mammalian AMP-activated protein kinase.

AMP-activated protein kinase (AMPK) regulates cellular metabolism in response to the availability of energy and is therefore a target for type II diabetes treatment. It senses changes in the ratio of AMP/ATP by binding both species in a competitive manner. Thus, increases in the concentration of AMP activate AMPK resulting in the phosphorylation and differential regulation of a series of downstream targets that control anabolic and catabolic pathways. We report here the crystal structure of the regulatory fragment of mammalian AMPK in complexes with AMP and ATP. The phosphate groups of AMP/ATP lie in a groove on the surface of the gamma domain, which is lined with basic residues, many of which are associated with disease-causing mutations. Structural and solution studies reveal that two sites on the gamma domain bind either AMP or Mg.ATP, whereas a third site contains a tightly bound AMP that does not exchange. Our binding studies indicate that under physiological conditions AMPK mainly exists in its inactive form in complex with Mg.ATP, which is much more abundant than AMP. Our modelling studies suggest how changes in the concentration of AMP ([AMP]) enhance AMPK activity levels. The structure also suggests a mechanism for propagating AMP/ATP signalling whereby a phosphorylated residue from the alpha and/or beta subunits binds to the gamma subunit in the presence of AMP but not when ATP is bound.

The kinetic mechanism of the SufC ATPase: the cleavage step is accelerated by SufB.

Protein products of the suf operon are involved in iron-sulfur metabolism. SufC is an ATPase that can interact with SufB in the absence of nucleotide. We have studied the transient kinetics of the SufC ATPase mechanism using the fluorescent ATP analogue, 2'(3')-O-N-methylanthraniloyl-ATP (mantATP). mantATP initially binds to SufC weakly. A conformational change of the SufC.mantATP complex then occurs followed by the very slow cleavage of mantATP to mantADP and the rapid release of Pi. In the presence of SufB, the cleavage step is accelerated and the release of mantADP is inhibited. Both of these effects promote the formation of a SufC.mantADP complex. In the absence and presence of SufB, mantADP remains more tightly bound to SufC than mantATP. These studies provide a basis for how the SufB and -C proteins interact in the processes involved in regulating iron-sulfur transfer.

The 2'-O- and 3'-O-Cy3-EDA-ATP(ADP) complexes with myosin subfragment-1 are spectroscopically distinct.

Ribose-modified highly-fluorescent sulfoindocyanine ATP and ADP analogs, 2'(3')-O-Cy3-EDA-AT(D)P, with kinetics similar to AT(D)P, enable myosin and actomyosin ATPase enzymology with single substrate molecules. Stopped-flow studies recording both fluorescence and anisotropy during binding to skeletal muscle myosin subfragment-1 (S1) and subsequent single-turnover decay of steady-state intermediates showed that on complex formation, 2'-O- isomer fluorescence quenched by 5%, anisotropy increased from 0.208 to 0.357, and then decayed with turnover rate k(cat) 0.07 s(-1); however, 3'-O- isomer fluorescence increased 77%, and anisotropy from 0.202 to 0.389, but k(cat) was 0.03 s(-1). Cy3-EDA-ADP.S1 complexes with vanadate (V(i)) were studied kinetically and by time-resolved fluorometry as stable analogs of the steady-state intermediates. Upon formation of the 3'-O-Cy3-EDA-ADP.S1.V(i) complex fluorescence doubled and anisotropy increased to 0.372; for the 2'-O- isomer, anisotropy increased to 0.343 but fluorescence only 6%. Average fluorescent lifetimes of 2'-O- and 3'-O-Cy3-EDA-ADP.S1.V(i) complexes, 0.9 and 1.85 ns, compare with approximately 0.7 ns for free analogs. Dynamic polarization shows rotational correlation times higher than 100 ns for both Cy3-EDA-ADP.S1.V(i) complexes, but the 2'-O-isomer only has also a 0.2-ns component. Thus, when bound, 3'-O-Cy3-EDA-ADP's fluorescence is twofold brighter with motion more restricted and turnover slower than the 2'-O-isomer; these data are relevant for applications of these analogs in single molecule studies.

Oligomerization and kinetic mechanism of the dynamin GTPase.

Dynamin is a large molecular weight GTPase. Amongst other biological processes, it is involved in clathrin-dependent endocytosis. It can self-assemble or assemble on other macromolecular structures that result in an increase in its GTPase activity. Its role in endocytosis has been variously attributed to being a force-generating enzyme or a signalling protein. Here we review evidence for the oligomeric state of dynamin at high and low ionic strength conditions. We also review work on the elementary processes of the dynamin GTPase at high ionic strength and compare these to the ATPase of the force-generating protein myosin and the GTPase of the signalling protein Ras. New data on the interaction of dynamin with a fluorescent derivative of GTPgammaS are also presented. The possible mechanism by which assembly of dynamin leads to an increase in its GTPase activity is discussed.