Project description:Aggregation of the amyloid β-protein (Aβ) is believed to be involved in Alzheimer's disease pathogenesis. Here we have investigated the importance of the aromatic rings at positions 19 and 20 for the aggregation rate and mechanism by substituting phenylalanine with leucine. Aggregation kinetics were monitored as a function of time and peptide concentration by thioflavin T (ThT) fluorescence, the aggregation equilibrium by sedimentation assay, structural changes using circular dichroism spectroscopy and the presence of fibrillar material was detected with cryo-transmission electron microscopy. All peptides convert from monomer to amyloid fibrils in a concentration-dependent manner. Substituting F19 with leucine results in a peptide that aggregates significantly slower than the wild type, while substitution of F20 produces a peptide that aggregates faster. The effects of the two substitutions are additive, since simultaneous substitution of F19 and F20 produces a peptide with aggregation kinetics intermediate between F19L and F20L. Our results suggest that the aromatic side-chain of F19 favors nucleation of the aggregation process and may be an important target for therapeutic intervention.

Project description:The ability to design foldamers that mimic the defined structural motifs of natural biopolymers is critical for the continued development of functional biomimetic molecules. Peptoids, or oligomers of N-substituted glycine, represent a versatile class of foldamers capable of folding into defined secondary and tertiary structures. However, the rational design of discretely folded polypeptoids remains a challenging task, due in part to an incomplete understanding of the covalent and noncovalent interactions that direct local peptoid folding. We have found that simple, peptoid monomer model systems allow for the effective isolation of individual interactions within the peptoid backbone and side chains and can facilitate the study of the role of these interactions in restricting local peptoid conformation. Herein, we present an analysis of a set of peptoid monomers and an oligomer containing N-aryl side chains capable of hydrogen bonding with the peptoid backbone. These model peptoids were found to exhibit well-defined local conformational preferences, allowing for control of the ?, ?, and ? dihedral angles adopted by the systems. Fundamental studies of the peptoid monomers enabled the design and synthesis of an acyclic peptoid reverse-turn structure, in which N-aryl side chains outfitted with ortho-hydrogen bond donors were hypothesized to play a critical role in the stabilization of the turn. This trimeric peptoid was characterized by X-ray crystallography and 2D NMR spectroscopy and was shown to adopt a unique acyclic peptoid reverse-turn conformation. Further analysis of this turn revealed an n??*(C?O) interaction within the peptoid backbone, which represents the first reported example of this type of stereoelectronic interaction occurring exclusively within a polypeptoid backbone. The installation of N-aryl side chains capable of hydrogen bonding into peptoids is straightforward and entirely compatible with current solid-phase peptoid synthesis methodologies. As such, we anticipate that the strategic incorporation of these N-aryl side chains should facilitate the construction of peptoids capable of adopting discrete structural motifs, both turnlike and beyond, and will facilitate the continued development of well-folded peptoids.

Project description:Structural fluctuations of a protein are essential for a protein to function and fold. By using molecular dynamics (MD) simulations of the model ?/? protein VA3 in its native state, the coupling between the main-chain (MC) motions [represented by coarse-grained dihedral angles (CGDAs) ?(n) based on four successive C(?) atoms (n - 1, n, n + 1, n + 2) along the amino acid sequence] and its side-chain (SC) motions [represented by CGDAs ?(n) formed by the virtual bond joining two consecutive C(?) atoms (n, n + 1) and the bonds joining these C(?) atoms to their respective C(?) atoms] was analyzed. The motions of SCs (?(n)) and MC (?(n)) over time occur on similar free-energy profiles and were found to be subdiffusive. The fluctuations of the SCs (?(n)) and those of the MC (?(n)) are generally poorly correlated on a ps time-scale with a correlation increasing with time to reach a maximum value at about 10 ns. This maximum value is close to the correlation between the ?(n)(t) and ?(n)(t) time-series extracted from the entire duration of the MD runs (400 ns) and varies significantly along the amino acid sequence. High correlations between the SC and MC motions [?(t) and ?(t) time-series] were found only in flexible regions of the protein for a few residues which contribute the most to the slowest collective modes of the molecule. These results are a possible indication of the role of the flexible regions of proteins for the biological function and folding.

Project description:The aggregation of polypeptides into amyloid fibrils is associated with a number of human diseases. Because these fibrils--or intermediates on the aggregation pathway--play important roles in the etiology of disease, considerable effort has been expended to understand which features of the amino acid sequence promote aggregation. One feature suspected to direct aggregation is the ?-stacking of aromatic residues. Such ?-stacking interactions have also been proposed as the targets for various aromatic compounds that are known to inhibit aggregation. In the case of Alzheimer's disease, the aromatic side chains Phe19 and Phe20 in the wild-type amyloid beta (A?) peptide have been implicated. To explicitly test whether the aromaticity of these side chains plays a role in aggregation, we replaced these two phenylalanine side chains with leucines or isoleucines. These residues have similar sizes and hydrophobicities as Phe but are not capable of ?-stacking. Thioflavin-T fluorescence and electron microscopy demonstrate that replacement of residues 19 and 20 by Leu or Ile did not prevent aggregation, but rather enhanced amyloid formation. Further experiments showed that aromatic inhibitors of aggregation are as effective against Ile- and Leu-substituted versions of A?42 as they are against wild-type A?. These results suggest that aromatic ?-stacking interactions are not critical for A? aggregation or for the inhibition of A? aggregation.

Project description:Many ions are known to affect the activity, stability, and structural integrity of proteins. Although this effect can be generally attributed to ion-induced changes in forces that govern protein folding, delineating the underlying mechanism of action still remains challenging because it requires assessment of all relevant interactions, such as ion-protein, ion-water, and ion-ion interactions. Herein, we use two unnatural aromatic amino acids and several spectroscopic techniques to examine whether guanidinium chloride, one of the most commonly used protein denaturants, and tetrapropylammonium chloride can specifically interact with aromatic side chains. Our results show that tetrapropylammonium, but not guanidinium, can preferentially accumulate around aromatic residues and that tetrapropylammonium undergoes a transition at ?1.3 M to form aggregates. We find that similar to ionic micelles, on one hand, such aggregates can disrupt native hydrophobic interactions, and on the other hand, they can promote ?-helix formation in certain peptides.

Project description:Kinetic analysis of decarboxylation catalyzed by S154A, Q215A, and S154A/Q215A mutant yeast orotidine 5'-monophosphate decarboxylases with orotidine 5'-monophosphate (OMP) and with a truncated nucleoside substrate (EO) activated by phosphite dianion shows (1) the side chain of Ser-154 stabilizes the transition state through interactions with the pyrimidine rings of OMP or EO, (2) the side chain of Gln-215 interacts with the phosphodianion group of OMP or with phosphite dianion, and (3) the interloop hydrogen bond between the side chains of Ser-154 and Gln-215 orients the amide side chain of Gln-215 to interact with the phosphodianion group of OMP or with phosphite dianion.

Project description:Imidazole-3-glycerol phosphate synthase is a heterodimeric allosteric enzyme that catalyzes consecutive reactions in imidazole biosynthesis through its HisF and HisH subunits. The unusually slow unfolding reaction of the isolated HisF TIM barrel domain from the thermophilic bacteria, Thermotoga maritima, enabled an NMR-based site-specific analysis of the main-chain hydrogen bonds that stabilize its native conformation. Very strong protection against exchange with solvent deuterium in the native state was found in a subset of buried positions in α-helices and pervasively in the underlying β-strands associated with a pair of large clusters of isoleucine, leucine and valine (ILV) side chains located in the α7(βα)8(βα)1-2 and α2(βα)3-6β7 segments of the (βα)8 barrel. The most densely packed region of the large cluster, α3(βα)4-6β7, correlates closely with the core of stability previously observed in computational, protein engineering and NMR dynamics studies, demonstrating a key role for this cluster in determining the thermodynamic and structural properties of the native state of HisF. When considered with the results of previous studies where ILV clusters were found to stabilize the hydrogen-bonded networks in folding intermediates for other TIM barrel proteins, it appears that clusters of branched aliphatic side chains can serve as cores of stability across the entire folding reaction coordinate of one of the most common motifs in biology.

Project description:Dynamic crosslinking of flexible polymer chains via attractive and reversible interactions is widely employed to obtain autonomously self-healable elastomers. However, this design leads to a trade-off relationship between the strength and self-healing speed of the material, i.e., strong crosslinks provide a mechanically strong elastomer with slow self-healing property. To address this issue, we report an "inversion" concept, in which attractive poly(ethyl acrylate-random-methyl acrylate) chains are dynamically crosslinked via repulsively segregated fluoroalkyl side chains attached along the main chain. The resulting elastomer self-heals rapidly (> 90% within 15 min) via weak but abundant van der Waals interactions among matrix polymers, while the dynamic crosslinking provides high fracture stress (≈2 MPa) and good toughness (≈17 MJ m-3). The elastomer has a nonsticky surface and selectively self-heals only at the damaged faces due to the surface segregation of the fluoroalkyl chains. Moreover, our elastomer strongly adheres to polytetrafluoroethylene plates (≈60 N cm-2) via hot pressing.

Project description:Voltage-gated sodium (NaV) channels mediate electrical excitability in animals. Despite strong sequence conservation among the voltage-sensor domains (VSDs) of closely related voltage-gated potassium (KV) and NaV channels, the functional contributions of individual side chains in Nav VSDs remain largely enigmatic. To this end, natural and unnatural side chain substitutions were made in the S2 hydrophobic core (HC), the extracellular negative charge cluster (ENC), and the intracellular negative charge cluster (INC) of the four VSDs of the skeletal muscle sodium channel isoform (NaV1.4). The results show that the highly conserved aromatic side chain constituting the S2 HC makes distinct functional contributions in each of the four NaV domains. No obvious cation-pi interaction exists with nearby S4 charges in any domain, and natural and unnatural mutations at these aromatic sites produce functional phenotypes that are different from those observed previously in Kv VSDs. In contrast, and similar to results obtained with Kv channels, individually neutralizing acidic side chains with synthetic derivatives and with natural amino acid substitutions in the INC had little or no effect on the voltage dependence of activation in any of the four domains. Interestingly, countercharge was found to play an important functional role in the ENC of DI and DII, but not DIII and DIV. These results suggest that electrostatic interactions with S4 gating charges are unlikely in the INC and only relevant in the ENC of DI and DII. Collectively, our data highlight domain-specific functional contributions of highly conserved side chains in NaV VSDs.

Project description:Early forms of the genetic code likely generated "statistical" proteins, with similar side chains occupying the same sequence positions at different ratios. In this scenario, groups of related side chains were treated by aminoacyl-tRNA synthetases as a single molecular species until a discrimination mechanism developed that could separate them. The aromatic amino acids tryptophan, tyrosine, and phenylalanine likely constituted one of these groups. A crystal structure of human tryptophanyl-tRNA synthetase was solved at 2.1 A with a tryptophanyl-adenylate bound at the active site. A cocrystal structure of an active fragment of human tyrosyl-tRNA synthetase with its cognate amino acid analog was also solved at 1.6 A. The two structures enabled active site identifications and provided the information for structure-based sequence alignments of approximately 45 orthologs of each enzyme. Two critical positions shared by all tyrosyl-tRNA synthetases and tryptophanyl-tRNA synthetases for amino acid discrimination were identified. The variations at these two positions and phylogenetic analyses based on the structural information suggest that, in contrast to many other amino acids, discrimination of tyrosine from tryptophan occurred late in the development of the genetic code.