NMR solution structure determination of RNAs.

During the past several years, there have been significant advances in NMR solution structure determination of macromolecules. The ability to easily measure residual dipolar couplings, to directly detect NHellipsisN hydrogen bonding interactions and to study much larger macromolecules by the application of heteronuclear experiments that select narrow lines in 2D and 3D spectra of isotopically labeled molecules promises to dramatically improve solution structure determination of nucleic acids.

Use of 1H-15N heteronuclear multiple-quantum coherence NMR spectroscopy to study the active site of aspartate aminotransferase.

Aspartate aminotransferase from Escherichia coli, an 88 kDa enzyme, was uniformly and selectively enriched with 15N and was studied by heteronuclear multiple-quantum coherence NMR spectroscopy in H2O. Good resolution was obtained for the downfield region (above 9.5 ppm chemical shift in the 1H dimension) for NH protons in the amide, indole, imidazole, and guanidinium group regions and several resonances were tentatively assigned. Two downfield resonances, at 12.6 and 11.36 ppm, appear to belong to oxygen- or sulfur-bound protons. The most downfield amide resonance at 11.78 ppm was assigned to the active site cysteine 192 whose peptide proton is 2.9 A away from the negatively charged carboxyl group of aspartate 199. Large downfield shifts (up to 1.15 ppm) of the indole NH resonance of the active site tryptophan 140 were observed upon binding of dicarboxylic inhibitors to the pyridoxal 5'-phosphate (PLP) form and of inorganic dianions to the pyridoxamine 5'-phosphate (PMP) form of the enzyme. We discuss these striking differences in the light of the available crystallographic data. Active sites of proteins, as well as specific inhibitory molecules, often contain negatively charged groups. These may be able to form hydrogen-bonds to NH groups and to shift the NH resonances downfield into a less crowded and therefore more readily observable region for many large proteins. Our approach, which makes use of both HMQC spectroscopy and NOE observations, should be widely applicable.

NMR studies of 1H resonances in the 10-18-ppm range for cytosolic aspartate aminotransferase.

Continuing a previous investigation (Kintanar, A., Metzler, C. M., Metzler, D. E., and Scott, R. D. (1991) J. Biol. Chem. 266, 17222-17229), we have recorded 1H NMR spectra at 500 MHz in the 10-18-ppm range for the 93-kDa porcine cytosolic aspartate aminotransferase and for four specific mutant forms of the enzyme in which histidine 68 has been replaced by lysine or histidine 143, 189, or 193 has been replaced by glutamine. We have correlated resonances for apoenzyme, pyridoxamine and pyridoxal phosphate forms, and dicarboxylate complexes and have assigned imidazole NH resonances of active site histidines. The chemical shifts of several resonances undergo pH-dependent changes around the pKa of the Schiff base proton at the active site. Other resonances shift upon binding of dicarboxylates or other ligands. Phosphate or carboxylate ions, which can also occupy the site of the substrate's alpha-carboxylate, cause rapid exchange of the Schiff base proton. Although most resonances in the 10-18-ppm range disappear rapidly in D2O, a few are retained for months in the presence of the dicarboxylate inhibitor glutarate. We demonstrate that changes in chemical shifts and in exchange rates are sensitive indicators of electronic interactions of the enzyme with ligands and of conformational change. Nuclear Overhauser effects from NH protons have allowed us to identify resonances of CH protons of the imidazole rings of histidines 143, 189, and 193. Observed and predicted chemical shifts have been compared. We conclude that the net charge on this histidine cluster is zero but that some negative charge from the aspartate 222 carboxylate is donated inductively into the histidine 143 ring. Studies of the related enzyme from Escherichia coli are provided in an accompanying paper (Metzler, D. E., Metzler, C. M., Scott, R. D., Mollova, E. T., Kagamiyama, H., Yano, T., Kuramitsu, S., Hayashi, H., Hirotsu, K., and Miyahara, I. (1994) J. Biol. Chem. 269, 28027-28033). Our approach should be applicable to the study of active sites of a broad range of relatively large proteins.

NMR studies of 1H resonances in the 10-18-ppm range for aspartate aminotransferase from Escherichia coli.

We have recorded 500-MHz 1H NMR spectra in the 10-18-ppm range for aspartate aminotransferase from Escherichia coli and for three specific mutant forms. Histidine 143 has been replaced by either alanine or asparagine. In the third mutant, tryptophan 140 has been replaced by phenylalanine. The NMR spectrum of the native enzyme is very similar to that of porcine cytosolic aspartate aminotransferase in the most downfield region. However, the resonances of the proton on the ring nitrogen of the pyridoxal 5'-phosphate (peak A) and on the His-143 imidazole ring (peak B) of the E. coli enzyme are broader and more readily lost at low pH or higher temperatures than those of the porcine enzyme. The possible role of tautomerism in promoting such broadening is discussed. In the histidine mutant proteins, peak A of the pyridoxal 5'-phosphate form is too broad to see under most conditions but is clearly present in the pyridoxamine phosphate form. Peak B is missing in the 2 histidine mutants. Observation of nuclear Overhauser effects further confirms the identity of B as the resonance of HN epsilon 2 of His-143 and that of peak D at approximately 11.8 ppm as HN epsilon 2 of His-189. The mutant spectra also provide insight into electronic interactions between groups in and near the active site which confirm and supplement conclusions drawn from spectra of porcine cAspAT. While no clear loss of a peak was observed for the Trp-140 mutant in its free form, the spectrum of the succinate complex lacked a strong band at 11.26 ppm. This may represent the Trp-140 indole NH proton which has been shifted downfield by binding to a succinate carboxylate group. While our results confirm the basic similarity of cytosolic aspartate aminotransferase and E. coli aspartate aminotransferase 1H NMR spectra, they also point out differences that may be useful in identifying resonances. A large number of mutant proteins have been prepared for the E. coli enzyme. The present results provide essential information for future study of these mutants and for study of NMR spectra of isotopically labeled enzyme.