Conformational preferences of beta- and gamma-aminated proline analogues

Silver assisted stereo-directed assembly of branched peptide nucleic acids into four-point nanostars

Branched chiral peptide nucleic acids br(4S/R)-PNA with three arms of PNA-C4 strands were constructed on a central chiral core of 4(R/S)-aminoproline as the branching center. The addition of Ag+ triggered the self-assembly of branched PNAs through the formation of C-Ag+-C metallo base pairing of the three PNA C4 arms leading to non-covalent dendrimers, whose architecture is directed by the C4(R/S)-stereocenter of core 4-aminoproline. The 4S-aminoprolyl core enabled the precise formation of four-pointed nanostars that was not realised with 4R-aminoprolyl or acyclic, achiral aminoethyl glycyl PNA cores. The dendritic assembly of 4 pointed nanostars exhibited net chirality of base stacks in CD spectra, while the base stack assembly from br(4R)-PNA 2 was overall achiral. The results demonstrate that the silver assisted, 4S-aminoproline core stereo selective chiral assembly of branched PNAs manifests into nanostar morphology. The chiral branched PNAs open new vistas in the supramolecular organization of nucleic acids.

Comparative effects of trifluoromethyl- and methyl-group substitutions in proline

What is the outcome of trifluoromethyl-/methyl-substitution in each position of the proline ring? Look inside to find out.

γ-(S)-Trifluoromethyl proline: evaluation as a structural substitute of proline for solid state (19)F-NMR peptide studies

γ-(4S)-Trifluoromethyl proline was synthesised according to a modified literature protocol with improved yield on a multigram scale. Conformational properties of the amide bond formed by the amino acid were characterised using N-acetyl methyl ester model. The amide populations (s-trans vs. s-cis) and thermodynamic parameters of the isomerization were found to be similar to the corresponding values for intact proline. Therefore, the γ-trifluoromethyl proline was suggested as a structurally low-disturbing proline substitution in peptides for their structural studies by (19)F-NMR. Indeed, the exchange of native proline for γ-trifluoromethyl proline in the peptide antibiotic gramicidin S was shown to preserve the overall amphipathic peptide structure. The utility of the amino acid as a selective (19)F-NMR label was demonstrated by observing the re-alignment of the labelled gramicidin S in oriented lipid bilayers.

Solvent-induced conformational flexibility of a bicyclic proline analogue: Octahydroindole-2-carboxylic acid

The conformational preferences of the N-acetyl-N'-methylamide derivatives of the four octahydroindole-2-carboxylic acid (Oic) stereoisomers have been investigated in the gas-phase and in aqueous solution using quantum mechanical calculations. In addition to the conformational effects provoked by the stereochemical diversity of Oic, which presents three chiral centers, results provide evidence of interesting and rather unusual features. The conformational preferences of the Oic stereoisomers in solution are only well described by applying a complete and systematic search process, results achieved by simple re-optimization of the gas-phase minima being very imprecise. This is because the conformational rigidity detected in the gas-phase, which is imposed by the chemical restrictions of the fused bicyclic skeleton, disappears in aqueous solution, the four stereoisomers behaving as flexible molecules in this environment. Thus, in general, the γ-turn is the only minimum energy conformation in the gas-phase while in aqueous solution the helical, polyproline-II and γ-turn motifs are energetically favored. Molecular dynamics simulations indicate that the conformational flexibility predicted by quantum mechanical calculations for the four Oic stereoisomers in solution is satisfactorily reproduced by classical force-fields.

Conformational preferences of proline analogues with a fused benzene ring

The intrinsic conformational preferences of indoline-2-carboxylic acid (Inc) and its α-methylated derivative (αMeInc) have been investigated using quantum mechanical calculations. Specifically, the behavior of their N-acetyl-N'-methylamide derivatives, Ac-L-Inc-NHMe and Ac-L-αMeInc-NHMe, has been explored at the B3LYP/6-31+G(d,p) level. Such amino acids are analogues of proline and (α-methyl)proline, respectively, bearing a benzene ring fused to the C(γ)-C(δ) bond of the five-membered pyrrolidine ring. The additional aromatic group has been shown to significantly restrict the conformational space available to these residues by reducing the flexibility of both the five-membered cycle and the peptide backbone. The fused benzene ring also plays a critical role in determining the cis-trans arrangement of the amide bond involving the pyrrolidine nitrogen, which is also modulated by the presence of the α-methyl group in the αMeInc derivative. Furthermore, the influence of the environment on the conformational propensities of these compounds has been evaluated by using both a self-consistent reaction field model and a recently developed interface in a hybrid QM/MM scheme, in which the solvent molecules are treated explicitly with classical mechanics while the solute is described by quantum mechanics at the density functional theory level.

Conformational preferences and cis-trans isomerization of L-3,4-dehydroproline residue

The conformational study of N-acetyl-N'-methylamide of L-3,4-dehydroproline (Ac-Dhp-NHMe, the Dhp dipeptide) is carried out using hybrid density functional methods with the self-consistent reaction field method in the gas phase and in solution (chloroform and water). The incorporation of a double bond between C(beta) and C(gamma) into the prolyl ring results in the puckering, backbone population, and barriers to prolyl cis-trans isomerization different from those of the Pro dipeptide. For local minima of the Dhp dipeptide in the gas phase and in water, the C(beta)-C(gamma) bonds become shorter by approximately 0.2 A and the bond angles C(alpha)-C(beta)-C(gamma) and C(beta)-C(gamma)-C(delta) are widened by approximately 8 degrees than those of the Pro dipeptide, and the puckering amplitude is computed to be 0.01-0.07 A, indicating that the 3,4-dehydroprolyl ring is quite less puckered. However, polyproline-like conformations become preferred and the relative stability of the conformation tC with a C(7) intramolecular hydrogen bond decreases as the solvent polarity increases, as found for the Pro dipeptide. The barriers to cis-trans isomerization of the Ac-Dhp peptide bond increase with the increase of solvent polarity and the isomerization is likely to proceed through the clockwise rotation in water, as found for the prolyl peptide bond. The hydrogen bond between the prolyl nitrogen and the following amide N-H group seems to contribute in stabilizing the transition state structures.

Thermally denatured state determines refolding in lipase: mutational analysis

Irreversibility of thermally denatured proteins due to aggregation limits thermodynamic characterization of proteins and also confounds the identification of thermostable mutants in protein populations. Identification of mutations that prevent the aggregation of unfolded proteins provides insights into folding pathways. In a lipase from Bacillus subtilis, evolved by directed evolution procedures, the irreversibility due to temperature-mediated aggregation was completely prevented by a single mutation, M137P. Though the parent and the mutants unfold completely on heating, mutants having substitutions M137P, along with M134E and S163P, completely or partially prevent the formation of aggregation-prone intermediate(s) at 75 degrees C. The three mutants show only a marginal increase in free energy of unfolding (DeltaG(H(2)O)), however, the profiles of the residual activity with temperature shows remarkable shift to higher temperature compared to parent. The intermediate(s) were characterized by enhanced binding of bis-ANS, a probe to titrate surface hydrophobicity, aggregation profiles and by estimation of soluble protein. Inclusion of salt in the refolding conditions prevents the reversibility of mutant having charge substitution, while the reversibility of mutant with the introduction of proline was unaffected, indicating the role of charge mediated interaction in M134E in preventing aggregation. Partial prevention of thermal aggregation in wild-type lipase with single substitution, M137P, incorporated by site-directed mutagenesis, suggests that the affect of M137P is independent of the intrinsic thermostability of lipase. Various effects of the mutations suggest their role is in prevention of the formation of aggregation prone intermediate(s). These mutations, describe yet another strategy to enhance the thermotolerance of proteins, where their influence is observed only on the denatured ensemble.