Catalytic Mechanism of Mammalian Adenylyl Cyclase: A Computational Investigation.

Adenylyl cyclase (AC) catalyzes the synthesis of cyclic AMP, an important intracellular regulatory molecule, from ATP. We propose a catalytic mechanism for class III mammalian AC based on density functional theory calculations. We employ a model of the AC active site derived from a crystal structure of mammalian AC activated by Gα·GTP and forskolin at separate allosteric sites. We compared the calculated activation free energies for 13 possible reaction sequences involving proton transfer, nucleophilic attack, and elimination of pyrophosphate. The proposed most probable mechanism is initiated by deprotonation of 3'OH and water-mediated transfer of the 3'H to the γ-phosphate. Proton transfer is followed by changes in coordination of the two magnesium ion cofactors and changes in the conformation of ATP to enhance the role of 3'O as a nucleophile and to bring 3'O close to Pα. The subsequent phosphoryl transfer step is concerted and rate-limiting. Comparison of the enzyme-catalyzed and nonenzymatic reactions reveals that the active site residues lower the free energy barrier for both phosphoryl transfer and proton transfer and significantly shift the proton transfer equilibrium. Calculations for mutants K1065A and R1029A demonstrate that K1065 plays a significant role in shifting the proton transfer equilibrium, whereas R1029 is important for making the transition state of concerted phosphoryl transfer tight rather than loose.

MD + QM correlations with tryptophan fluorescence spectral shifts and lifetimes.

Principles behind quenching of tryptophan (Trp) fluorescence are updated and extended in light of recent 100-ns and 1-µs molecular dynamics (MD) trajectories augmented with quantum mechanical (QM) calculations that consider electrostatic contributions to wavelength shifts and quenching. Four studies are summarized, including (1) new insight into the single exponential decay of NATA, (2) a study revealing how unsuspected rotamer transitions affect quenching of Trp when used as a probe of protein folding, (3) advances in understanding the origin of nonexponential decay from 100-ns simulations on 19 Trps in 16 proteins, and (4) the correlation of wavelength with lifetime for decay-associated spectra (DAS). Each study strongly reinforces the concept that-for Trp-electron transfer-based quenching is controlled much more by environment electrostatic factors affecting the charge transfer (CT) state energy than by distance dependence of electronic coupling. In each case, water plays a large role in unexpected ways.

Simulations of tryptophan fluorescence dynamics during folding of the villin headpiece.

Protein folding kinetics is commonly monitored by changes in tryptophan (Trp) fluorescence intensity. Considerable recent discussion has centered on whether the fluorescence of the single Trp in the much-studied, fast-folding villin headpiece C-terminal domain (HP35) accurately reflects folding kinetics, given the general view that quenching is by a histidine cation (His(+)) one turn away in an α-helix (helix III) that forms early in the folding process, according to published MD simulations. To help answer this question, we ran 1.0 µs MD simulations on HP35 (N27H) and a faster-folding variant in its folded form at 300 K and used the coordinates and force field charges with quantum calculations to simulate fluorescence quenching caused by electron transfer to the local amide and to the His(+). The simulations demonstrate that quenching by His(+) in the fully formed helix III is possible only during certain Trp and His(+) rotamer and solvent conformations, the propensity of which is a variable that can allow Trp fluorescence to report the global folding rate, as recent experiments imply.

Ab initio prediction of tryptophan fluorescence quenching by protein electric field enabled electron transfer.

We report quantum mechanical-molecular mechanical (QM-MM) predictions of fluorescence quantum yields for 20 tryptophans in 17 proteins, whose yields span the range from 0.01 to 0.3, using ab initio computed coupling matrix elements for photoinduced electron transfer from the 1La excited indole ring to a local backbone amide. The average coupling elements span the range 140-1000 cm-1, depending on tryptophan rotamer conformation. The matrix elements were from the singles configuration interaction matrix, and were largely insensitive to which of the three basis sets was used. Large fluctuations were seen on the time scale of tens of femtoseconds, caused primarily by side chain and backbone torsional variations for 150 ps of dynamics at 300 K. The largest coupling occurs for the chi1 = -60 degrees rotamer and is purely through-bond. There is no apparent correlation between the coupling magnitude and quantum yield, which is still dominated by energy gap and reorganization energy. The source of error bars for predicted quenching rates using the weak coupling golden rule may be due to inaccurate averaged Franck-Condon weighted densities because of inadequate simulation times and parameters and/or to failure of the weak coupled golden rule used in these predictions because of the broad distribution of Landau-Zener probabilities arising from the large variable coupling.