Protein NMR-based screening in drug discovery.

Protein NMR as a screening tool in drug discovery has become prominent within the past ten years. Advances in protein manipulation, whether by biological means (labeling) or physical means (NMR), have created a powerful method that is able to observe ligand-target interactions in solution.

Structural basis for thermostability in aporubredoxins from Pyrococcus furiosus and Clostridium pasteurianum.

The structures of apo- and holorubredoxins from Pyrococcus furiosus (PfRd) and Clostridium pasteurianum (CpRd) have been investigated and compared using residual dipolar couplings to probe the origin of thermostability. In the native, metal (Fe or Zn) containing form, both proteins can maintain native structure at very high temperatures (>70 degrees C) for extended periods of time. Significant changes in either structure or backbone dynamics between 25 and 70 degrees C are not apparent for either protein. A kinetic difference with respect to metal loss is observed as in previous studies, but the extreme stability of both proteins in the presence of metal makes thermodynamic differences difficult to monitor. In the absence of metal, however, a largely reversible thermal denaturation can be monitored, and a comparison of the two apoproteins can offer insights into the origin of stability. Below denaturation temperatures apo-PfRd is found to have a structure nearly identical to that of the native holo form, except immediately adjacent to the metal binding site. In contrast, apo-CpRd is found to have a structure distinctly different from that of its holo form at low temperatures. This structure is rapidly lost upon heating, unfolding at approximately 40 degrees C. A PfRd mutant with the hydrophobic core mutated to match that of CpRd shows no change in thermostability in the metal-free state. A metal-free chimera with residues 1-15 of CpRd and the remaining 38 residues of PfRd is severely destabilized and is unfolded at 25 degrees C. Hence, the hydrophobic core does not seem to be the key determinant of thermostability; instead, data point to the hydrogen bond network centered on the first 15 residues or the interaction of these 15 residues with other parts of the protein as a possible contributor to the thermostability.

Direct measurement of 1H-1H dipolar couplings in proteins: a complement to traditional NOE measurements.

An intensity-based constant-time COSY (CT-COSY) method is described for measuring 1H-1H residual dipolar couplings of proteins in weakly aligned media. For small proteins, the overall sensitivity of this experiment is comparable to the NOESY experiment. In cases where the 1H-1H distances are defined by secondary structure, such as 1H(alpha)-1H(N) and 1H(N)-1H(N) sequential distances in alpha-helices and beta-sheets, these measurements provide useful orientational constraints for protein structure determination. This experiment can also be used to provide distance information similar to that obtained from NOE connectivities once the angular dependence is removed. Because the measurements are direct and non-coherent processes, such as spin diffusion, do not enter, the measurements can be more reliable. The 1/r3 distance dependence of directly observed dipolar couplings, as compared with the 1/r6 distance dependence of NOEs, also can provide longer range distance information at favorable angles. A simple 3D, 15N resolved version of the pulse sequence extends the method to provide the improved resolution required for application to larger biomolecules.

Variation of molecular alignment as a means of resolving orientational ambiguities in protein structures from dipolar couplings.

Residual dipolar couplings for pairs of proximate magnetic nuclei in macromolecules can easily be measured using high-resolution NMR methods when the molecules are dissolved in dilute liquid crystalline media. The resulting couplings can in principle be used to constrain the relative orientation of molecular fragments in macromolecular systems to build a complete structure. However, determination of relative fragment orientations based on a single set of residual dipolar couplings is inherently hindered by the multi-valued nature of the angular dependence of the dipolar interaction. Even with unlimited dipolar data, this gives rise to a fourfold degeneracy in fragment orientations. In this Communication, we demonstrate a procedure based on an order tensor analysis that completely removes this degeneracy by combining residual dipolar coupling measurements from two alignment media. Application is demonstrated on (15)N-(1)H residual dipolar coupling data acquired on the protein zinc rubredoxin from Clostridium pasteurianum dissolved in two different bicelle media.