Highly sensitive: The azido analogue of methionine, azidohomoalanine (see picture), is shown to be a sensitive IR probe of protein structure, folding, and electrostatics, as demonstrated for ribosomal protein NTL9. It can be readily incorporated in to proteins, and the azido frequency is significantly blue‐shifted in the thermally unfolded state.
The use of noncoded amino acids as spectroscopic probes of protein folding and function is growing rapidly, in large part because of advances in the methodology for their incorporation. Recently p-cyanophenylalanine has been employed as a fluorescence and IR probe, as well as a FRET probe to study protein folding, protein-membrane interactions, protein-protein interactions and amyloid formation. The probe has been shown to be exquisitely sensitive to hydrogen bonding interactions involving the cyano group, and its fluorescence quantum yield increases dramatically when it is hydrogen bonded. However, a detailed understanding of the factors which influence its fluorescence is required to be able to use this popular probe accurately. Here we demonstrate the recombinant incorporation of p-cyanophenylalanine in the N-terminal domain of the ribosomal protein L9. Native state fluorescence is very low, which suggests that the group is sequestered from solvent; however, IR measurements and molecular dynamics simulations show that the cyano group is exposed to solvent and forms hydrogen bonds to water. Analysis of mutant proteins and model peptides demonstrates that the reduced native state fluorescence is caused by the effective quenching of p-cyanophenylalanine fluorescence via FRET to tyrosine side-chains. The implications for the interpretation of p-cyanophenylalanine fluorescence measurements and FRET studies are discussed.
The timescale for ordering of the polypeptide backbone relative to the side chains is a critical issue in protein folding. The interplay between ordering of the backbone and side chains is particularly important for the formation of β-sheet structures, as the polypeptide chain searches for the native stabilizing cross-strand interactions. We have studied these issues in the N-terminal domain of protein L9 (NTL9), a model protein with mixed α/β structure. We have developed a general approach for introducing site-specific IR probes for the side chains (azide) and backbone (13C=18O) using recombinant protein expression. T-jump, time-resolved IR spectroscopy combined with site-specific labeling enables independent measurement of the respective backbone and side chain dynamics with single residue resolution. We find that side chain ordering in a key region of the β-sheet structure occurs on a slower time scale than ordering of the backbone during the folding of NTL9, likely due to the transient formation of nonnative side chain interactions.
The thienopyrimidinone 5,6-dimethyl-2-(4-nitrophenyl)thieno[2,3-d]pyrimidin-4(3H)-one (DNTP) occupies the interface between the p66 ribonuclease H (RNase H) domain and p51 thumb of human immunodeficiency virus reverse transcriptase (HIV RT), thereby inducing a conformational change incompatible with catalysis. Here, we combined biochemical characterization of 39 DNTP derivatives with antiviral testing of selected compounds. In addition to wild-type HIV-1 RT, derivatives were evaluated with rationally-designed, p66/p51 heterodimers exhibiting high-level DNTP sensitivity or resistance. This strategy identified 3′,4′-dihydroxyphenyl (catechol)-substituted thienopyrimidinones with sub-micromolar in vitro activity against both wild type HIV-1 RT and drug-resistant variants. Thermal shift analysis indicates that, in contrast to active site RNase H inhibitors, these thienopyrimidinones destabilize the enzyme, in some instances reducing the Tm by 5°C. Importantly, catechol-containing thienopyrimidinones also inhibit HIV-1 replication in cells. Our data strengthens the case for allosteric inhibition of HIV RNase H activity, providing a platform for designing improved antagonists for use in combination antiviral therapy.
p-Cyanophenylalanine is an extremely useful fluorescence probe of protein structure which can be recombinantly and chemically incorporated into proteins. The probe has been used to study protein folding, protein-membrane interactions, protein-peptide interactions and amyloid formation, however the factors that control its fluorescence are not fully understood. Hydrogen bonding to the cyano group is known to play a major role in modulating the fluorescence quantum yield, but the role of potential side-chain quenchers has not yet been elucidated. A systematic study on the effects of different side-chains on p-cyanophenylalanine fluorescence is reported. Tyr is found to have the largest effect followed by deprotonated His, Met, Cys, protonated His, Asn, Arg, and protonated Lys. Deprotonated amino groups are much more effective fluorescence quenchers than protonated amino groups. Free neutral imidazole and hydroxide ion are also effective quenchers of p-cyanophenylalanine fluorescence with Stern-Volmer constants of 39.8 M−1 and 22.1 M−1, respectively. The quenching of p-cyanophenylalanine fluorescence by specific side-chains is exploited to develop specific, high sensitivity, fluorescence probes of helix formation. The approach is demonstrated with Ala based peptides that contain a p-cyanophenylalanine-His or a p-cyanophenylalanine-Tyr pair located at positions i and i+4. The p-cyanophenylalanine-His pair is most useful when the His side-chain is deprotonated and is, thus, complimentary to Trp-His pair which is most sensitive when the His side-chain is protonated.
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