An NMR analysis of the reaction of ubiquitin with [acetyl-1-13C]aspirin.

The acetylation of ubiquitin by [acetyl-1-13C]aspirin has been studied using 2D NMR methods. Studies performed in a 50:50 H2O:D2O medium show doubling of the acetyl carbonyl resonances, indicating that all of the stable adducts formed involved amide linkages. Assignment of the heteronuclear multiple quantum coherence (HMQC) resonances was accomplished based on comparison of resonance intensities with the results of an Edman degradation analysis, pH titration studies of acetylated ubiquitin, and analysis of two ubiquitin mutants, K33R and K63R. The presence of a single tyrosine residue in close proximity to lysine-48 suggested another assignment strategy. Nitration of tyrosine-59 resulted in a small, pH-dependent shift of the resonance assigned to lysine-48, with a pK of 7.0, close to that expected for the nitrotyrosyl hydroxyl group. An additional adduct resonance with very low intensity also was observed and tentatively assigned to the acetylated N-terminal methionine residue. The relative rates of acetylation of the various lysine residues were obtained from time-dependent HMQC studies. Since no sample preparation artifacts were introduced, the levels of modification of the various residues could be determined with relatively high accuracy. Based on the time-dependent intensity data, the relative rate constants for modification of K6, K48, K63, K11, K33, and M1 were 1.0, 0.59, 0.43, 0.26, 0.23, and 0.03, respectively. These results were in much better agreement with amino accessibility predictions based on the crystal structure of the ubiquitin monomer than with predictions based on the ubiquitin structure in the crystallized dimeric and tetrameric forms. This approach provides a useful basis for understanding how local environmental factors can influence protein adduct formation, as well as for comparing the extent and specificity of various acetylation reagents.

Cleavage of the X-Pro peptide bond by pepsin is specific for the trans isomer.

Fluorine nuclear magnetic resonance studies of the cleavage of peptides containing a 4-fluorophenylalanine (FPhe)-Pro bond have been performed in order to determine the conformational specificity of FPhe-Pro bond cleavage by pepsin. The peptides selected were substrates of HIV protease or of avian sarcoma virus protease, both of which have been reported to be cleaved specifically at X-Pro by pepsin as well as by the corresponding viral protease enzyme. By working at 0 degrees C, it was possible to separate kinetically cleavage and cis/trans isomerization. For the case of the protease substrate, Ser-Gln-Asn-FPhe-Pro-Ile-Val-Gln, cleavage was shown to be specific for the trans conformation. A value for the rate constant for hydrolysis of the trans peptide divided by the Michaelis constant, ktH/KMtrans = 0.3 min-1 mM-1 was obtained with this substrate, and the Michaelis constant appears to be considerably higher than the substrate concentration, 3.7 mM, used in the study. On a slower time scale, additional cleavages can readily be detected. For the avian leukemia virus protease substrate, Thr-Phe-Gln-Ala-FPhe-Pro-Leu-Arg-Glu-Ala, the cleavage was both slower and less specific. In addition to the primary cleavage at the FPhe-Pro site, cleavage also occurs at the Ala-FPhe bond on a somewhat slower time scale. In addition to the conformational specificity of the cleavage reaction, these results indicate that pepsin is a better model for HIV protease than for avian leukemia virus protease.

Conformational selectivity of HIV-1 protease cleavage of X-Pro peptide bonds and its implications.

Kinetic measurements on a fluorescent peptide analog of the p17/p24 cleavage site of the Gag polyprotein demonstrate the conformational selectivity of human immunodeficiency virus, type 1 protease for the trans conformation of the Tyr-Pro bond. A mean cis/trans ratio of 0. 3, and a cis --> trans isomerization rate constant of 0.022 s-1 are determined at T = 22 degrees C. This rate is in excellent agreement with that predicted by 19F NMR studies of structurally analogous peptides containing a fluorine/hydroxyl substitution on the tyrosyl residue. Addition of recombinant human cyclophilin resulted in a significant enhancement of this rate, and it is proposed that this enzyme, which has been shown to be associated with the Gag protein, functions as an auxiliary enzyme for the protease during cleavage in the virion.

NMR study of G.A and A.A pairing in (dGCGAATAAGCG)2.

One- and two-dimensional NMR, UV absorption experiments, and molecular mechanics calculations were conducted on an oligonucleotide duplex (dGCGAATAAGCG)2 which will be referred to as the T-11-mer. This oligonucleotide forms a duplex that is primarily B-form and contains two adjacent G.A and A.A base pairs and two 3' unpaired guanosines. The adjacent mismatch base pairs have an unusual structure which includes overwinding the helix and stacking with the base from the complementary strand (A4 with A8 and G3 with A7) instead of stacking with the base which is sequential on the strand. The exchangeable and nonexchangeable proton NMR spectra of the duplex have been characterized in H2O and D2O solution at neutral and acidic pH. The duplex is stabilized upon protonation; however, no additional hydrogen bonds are formed. We have observed the amino protons of adenosines A4 and A8 and guanosine G3 as a function of temperature and pH. These amino protons are involved in hydrogen bonds with the purine N3 or N7 acting as acceptors. Through the observation of a variety of NOE signals, the structure of the G.A and A.A mismatch base pairs has been defined.

Thermodynamic characterization of deoxyribooligonucleotide duplexes containing bulges.

Ultraviolet absorption techniques were used to study the thermodynamics of duplex formation for a DNA decamer, d(GCGAAAAGCG).d(CGCTTTTCGC), and a series of related duplexes, each of which contains a bulged base centered in the A.T tract. Thermodynamic parameters were obtained from nonlinear least-squares fits of the melting curves and the concentration dependences of the melting temperatures. Duplexes containing a localized single-base bulge were found to be 3.5-4.6 kcal/mol less stable than the decamer at 37 degrees C. These results indicate that both the identity of the bulged base and the strand in which it is located may influence the amount by which the duplex is destabilized. Bulged bases located in the T-strand, d(CGCTTYTTCGC), in position Y, were observed to be slightly more destabilizing than those located in the A-strand, d(GCGAAXAAGCG), in position X. Bulged purines may be more destabilizing than bulged pyrimidines.