Proteins with beta-(thienopyrrolyl)alanines as alternative chromophores and pharmaceutically active amino acids.

L-beta-(Thieno[3,2-b]pyrrolyl)alanine and L-beta-(thieno[2,3-b]pyrrolyl)alanine are mutually isosteric and pharmaceutically active amino acids that mimic tryptophan with the benzene ring in the indole moiety replaced by thiophene. Sulfur as a heteroatom causes physicochemical changes in these tryptophan surrogates that bring about completely new properties not found in the indole moiety. These synthetic amino acids were incorporated into recombinant proteins in response to the Trp UGG codons by fermentation in a Trp-auxotrophic Escherichia coli host strain using the selective pressure incorporation method. Related protein mutants expectedly retain the secondary structure of the native proteins but show significantly changed optical and thermodynamic properties. In this way, new spectral windows, fluorescence, polarity, thermodynamics, or pharmacological properties are inserted into proteins. Such an engineering approach by translational integration of synthetic amino acids with a priori defined properties, as shown in this study, proved to be a novel and useful tool for protein rational design.

Noninvasive tracing of recombinant proteins with "fluorophenylalanine-fingers".

High-level residue-specific replacement of phenylalanine residues in recombinant human annexin V and azurin from Pseudomonas aeruginosa with o-fluorophenylalanine, m-fluorophenylalanine, and p-fluorophenylalanine has been achieved using the selective pressure incorporation method. Incorporation was confirmed analytically and by UV spectroscopy while the secondary and tertiary structures of these protein mutants in solution remained unchanged upon the effected substitutions. Fluorinated phenylalanines alone and when integrated into proteins exhibit two characteristic and prominent shoulders ("fingers") in the UV spectrum in the range of 260-270 nm, which do not overlap with the contributions of tyrosine and tryptophan residues in the protein UV spectra. Thus, the presence of such "fluorophenylalanine fingers" ("FF fingers") opens a new spectral window to identify the labeled target protein among other nonlabeled cellular proteins in preparative work by simple UV spectroscopy. In the coming era of proteomics such a reliable, cheap, and easy reproducible methodology might have a great potential for speeding up the identification and characterization of target molecules in the total protein output from the genomes of a variety of organisms.

Atomic mutations at the single tryptophan residue of human recombinant annexin V: effects on structure, stability, and activity.

The single tryptophan residue (Trp187) of human recombinant annexin V, containing 320 residues and 5328 atoms, was replaced with three different isosteric analogues where hydrogen atoms at positions 4, 5, and 6 in the indole ring were exchanged with fluorine. Such single atom exchanges of H --> F represent atomic mutations that result in slightly increased covalent bond lengths and inverted polarities in the residue side-chain structure. These minimal changes in the local geometry do not affect the secondary and tertiary structures of the mutants, which were identical to those of wild-type protein in the crystal form. But the mutants exhibit significant differences in stability, folding cooperativity, biological activity, and fluorescence properties if compared to the wild-type protein. These rather large global effects, resulting from the minimal local changes, have to be attributed either to the relatively strong changes in polar interactions of the indole ring or to differences in the van der Waals radii or to a combination of both facts. The changes in local geometry that are below resolution of protein X-ray crystallographic studies are probably of secondary importance in comparison to the strong electronegativity introduced by the fluorine atom. Correspondingly, these types of mutations provide an interesting approach to study cooperative functions of integrated residues and modulation of particular physicochemical properties, in the present case of electronegativity, in a uniquely structured and hierarchically organized protein molecule.

Toward the experimental codon reassignment in vivo: protein building with an expanded amino acid repertoire.

The high precision and fidelity of the genetic message transmission are ensured by numerous proofreading steps, from DNA replication and transcription to protein translation. The key event for translational fidelity is the proper codon assignment for 20 canonical amino acids. An experimental codon reassignment is possible for noncanonical amino acids in vivo using artificially constructed expression hosts under efficient selective pressure. However, such amino acids may interfere with the cellular metabolism and thus do not belong to the 'first' or 'restricted' part of the universal code, but rather to a second or 'relaxed' part, which is limited mainly by the downstream proofreading in the natural translational machinery. Correspondingly, not all possible alpha-amino acids can be introduced into proteins. The aim of this study is to discuss biological and evolutionary constraints on possible candidates for this second coding level of the universal code. Engineering of such a 'second' code is expected to have great academic as well as practical impact, ranging from protein folding studies to biomedicine.

Atomic mutations in annexin V--thermodynamic studies of isomorphous protein variants.

We have recently developed methods for specific and high-level replacement of methionine with 2-aminohexanoic acid, selenomethionine and telluromethionine as isosteric and atomic analogues for structural investigations of human recombinant annexin V. The variants formed isomorphic crystals and retained the parent three-dimensional fold and bioactivities. Folding parameters were determined from thermal and chemical unfolding to partially denatured states. Stabilities estimated from guanidinium chloride unfolding equilibria are not changed significantly for the atomic mutants (S-->Se-->Te) while the denaturation midpoint is shifted toward lower values with an increase of the m values at the increase of hydrophobicity. In contrast, stabilities in urea are considerably affected by the atomic substitutions, decreasing together with the m and [D]1/2 values. The methylene and selenium variants are identical within the limits of error of all measurements performed here. The physical parameters of the amino acid analogues and the values derived from the slopes of the unfolding data are highly correlated. This approach demonstrates how systematic variations in atomic number at the site of replacement (atomic mutations) can provide a method to probe specific folding properties of proteins.

Residue-specific bioincorporation of non-natural, biologically active amino acids into proteins as possible drug carriers: structure and stability of the per-thiaproline mutant of annexin V.

Residue-specific bioincorporation of 1,3-thiazolidine-4-carboxylic acid [thiaproline, Pro(S)], a non-natural amino acid analog of proline, into human recombinant annexin V was achieved with a proline-auxotrophic Escherichia coli strain by fermentation procedures in minimal medium. Quantitative replacement of proline with thiaproline was confirmed by mass-spectrometric, amino acid, and x-ray crystallographic analyses. The wild-type protein and its per-Pro(S) mutant were found to crystallize isomorphously and to show identical three-dimensional structures in crystals. In solution the dichroic properties of the wild-type and per-Pro(S) protein confirmed nearly identical overall folds. From thermal denaturation experiments, however, a reduced Tm (-4.5 K) value was determined whereas the van't Hoff enthalpy and entropy were not significantly affected. Therefore, protein mutants containing bioactive amino acid analogs like thiaproline at multiple sites would be expected to fully retain their functional properties, including immunogenicity, and thus could serve as promising vehicles for targeted drug delivery.

Chalcogen-analogs of amino acids. Their use in X-ray crystallographic and folding studies of peptides and proteins.

Using methionine-auxotrophic Escherichia coli strains quantitative biosynthetic replacement of the methionine residues by seleno- and telluromethionine but not by methoxinine was achieved in various model proteins, clearly indicating a limited tolerance in the editing range of methionyl-tRNA synthetase. For expression of the protein variants the acetyl derivatives of the chalcogen-analogs of methionine, obtained by a new and highly efficient synthetic procedure, proved to be the ideal source in the growth media as they were found to be significantly more stable than the underivatized methionine analogs. The conformational properties in solution, the folding and unfolding parameters as well as X-ray crystallographic data confirmed the highly isomorphous character of the atomic mutants and thus the usefulness of this concept in X-ray analysis of proteins. Quantitative replacement of cysteine residues by selenocysteine has recently been achieved using cysteine-auxotrophic E. coli strains, but a selective replacement of cysteine residues by employing the natural translational machinery of selenocysteine is also conceivable. We have therefore performed a detailed study on synthetic selenocysteine-peptides in order to determine the redox potential of this cysteine analog, and thus the ability of related peptide and protein analogs to undergo the correct oxidative folding. Since the redox potential of selenocysteine was found to be significantly more reducing than that of the parent amino acid, selective formation of a diselenide bridge in presence of additional cysteine residues is highly favored as well documented in the case of the synthetic bis-selenocysteine-endothelin I analog. These results confirm that even cysteine residues may represent an interesting target for the design and expression of isomorphous heteroatomic analogs of proteins.