Design of anti-BVDV drug based on common chemical features, their interaction, and scaffolds of TLR8 agonists.

In the absence of an experimental bTLR8 structure, recent studies have called attention to the fact that bTLR8 can also be activated by hTLR7/hTLR8 agonist, such as antiviral imidazoquinoline derivatives of resiquimod (R848) and imiquimod (R837) as well as some guanine nucleotide analogs with a scaffold structure related to the nucleic acids of ssRNA virus. In particular, the known small agonists (namely CL075, CL097 and R848) have been targeted to determine distinguishable deciding factors in complex with dimeric bTLR8-ECDs in comparison to ligand-induced activated hTLR8-ECDs. According to basic knowledge, the deciding eligibility criteria can be subsequently applied in our bTLR8 model to characterize the 3D-arrangement of chemical features (pharmacophore) and to investigate the distinct restrictions affecting species-specificity on dual TLR7/TLR8 small agonists suggested in previous works. Despite the lack of extensive structural biology studies regarding the interaction of bTLR8-ECDs with the agonists, our complex models of bTLR8-ECDs and the known agonists were applied to identify the deciding factors required for the interactions from agonist-based and (bTLR8-agonist complexes) structure-based pharmacophores. These pharmacophore constraints impose their essential chemical features to active bTLR8 receptors. The characterized pharmacophores all were employed in the virtual screening of candidates with a further acting factor of calf immune enhancer. Two hits were suggested as satisfying all decision factors to identify a potent bTLR8-specific agent with novel scaffolds dissimilar to imidazoquinoline analogues lacking overall homogeneity.

Annular anionic lipids stabilize the integrin αIIbß3 transmembrane complex.

Cationic membrane-proximal amino acids determine the topology of membrane proteins by interacting with anionic lipids that are restricted to the intracellular membrane leaflet. This mechanism implies that anionic lipids interfere with electrostatic interactions of membrane proteins. The integrin αIIbß3 transmembrane (TM) complex is stabilized by a membrane-proximal αIIb(Arg(995))-ß3(Asp(723)) interaction; here, we examine the influence of anionic lipids on this complex. Anionic lipids compete for αIIb(Arg(995)) contacts with ß3(Asp(723)) but paradoxically do not diminish the contribution of αIIb(Arg(995))-ß3(Asp(723)) to TM complex stability. Overall, anionic lipids in annular positions stabilize the αIIbß3 TM complex by up to 0.50 ± 0.02 kcal/mol relative to zwitterionic lipids in a headgroup structure-dependent manner. Comparatively, integrin receptor activation requires TM complex destabilization of 1.5 ± 0.2 kcal/mol, revealing a sizeable influence of lipid composition on TM complex stability. We implicate changes in lipid headgroup accessibility to small molecules (physical membrane characteristics) and specific but dynamic protein-lipid contacts in this TM helix-helix stabilization. Thus, anionic lipids in ubiquitous annular positions can benefit the stability of membrane proteins while leaving membrane-proximal electrostatic interactions intact.

Sequence and membrane determinants of the random coil-helix transition of α-synuclein.

A random coil-helix transition underlies the association of the presynaptic protein α-synuclein (αS) with curved vesicle membranes to fold Asp2-Ala89 into a continuous helix. To clarify this transition, we examined αS folding cooperativity, helix nucleation and propagation in relation to membrane stabilization and leakage on diverse small unilamellar vesicles. The sequences centering on Phe4 and Tyr39 initiate lipid interactions and the Phe4 region nucleates the helix irrespective of the order of Ser9-Ala89. However, helix propagation is not the sum of individual αS-membrane interactions; it requires non-uniform but balanced sequence distributions of lipid affinities and helix flexibility. The attained helix propagation, like folding cooperativity, depends distinctly on membrane lipid composition and correlates to the degree of αS-conferred membrane stabilization. Contrary to classical coil-helix folding thermodynamics, helix propagation proceeds with a small gain in free energy relative to helix nucleation indicating that its binding enthalpy is expended to compensate a high entropic cost of reducing lipid-packing defects in the curved membrane. Non-saturating lipid conditions or rigidification of the αS helix triggers an increase in small unilamellar vesicle membrane leakage. Thus, αS folding parameters appear highly optimized and closely matched to stabilize and protect its target membrane. Aging-associated changes in lipid and αS concentrations may therefore alter synaptic plasticity and contribute to αS misfolding that culminates in fatal neurodegeneration.

Insight into α-synuclein plasticity and misfolding from differential micelle binding.

Misfolded species of the 140-residue protein α-synuclein (αS) are implicated in the demise of dopaminergic neurons, resulting in fatal neurodegeneration. The intrinsically unstructured protein binds curved synaptic vesicle membranes in helical conformations but misfolds into amyloid fibrils via ß-sheet interactions. Breaks in helical αS conformation may offer a pathway to transition from helical to sheet conformation. Here, we explore the evolution of broken αS helix conformations formed in complex with SDS and SLAS micelles by molecular dynamics simulations. The population distribution of experimentally observed αS conformations is related to the spatial concentration of intrinsic micelle shape perturbations. For the success of micelle-induced αS folding, we posit the length of the first helical segment formed, which controls micelle ellipticity, to be a key determinant. The degree of micelle curvature relates to the arrangement and segmental motions of helical secondary structure elements. A criterion for assessing the reproduction of such intermediate time scale protein dynamics is introduced by comparing the sampling of experimental and simulated spin label distributions. Finally, at the sites of breaks in the elongated, marginally stable αS helix, vulnerability to forming a transient, intramolecular ß-sheet is identified. Upon subsequent intermolecular ß-sheet pairing, pathological αS amyloid formation from initial helical conformation is thus achievable.

Construction of covalent membrane protein complexes and high-throughput selection of membrane mimics.

The association of transmembrane (TM) helices underlies membrane protein structure and folding. Structural studies of TM complexes are limited by complex stability and the often time-consuming selection of suitable membrane mimics. Here, methodology for the efficient, preparative scale construction of covalent TM complexes and the concomitant high-throughput selection of membrane mimics is introduced. For the employed integrin αIIbß3 model system, the methodology identified phospholipid bicelles, including their specific composition, as the best membrane mimic. The method facilitates structure determination by NMR spectroscopy as exemplified by the measurement of previously inaccessible residual dipolar couplings and (15)N relaxation parameters.

The clustering and spatial arrangement of beta-sheet sequence, but not order, govern alpha-synuclein fibrillogenesis.

The intrinsically unstructured protein alpha-synuclein (aS) is prone to misfold into cytotoxic beta-sheet-rich oligomers and amyloid fibrils that underlie the pathogenesis of Lewy body diseases such as Parkinson's disease. An important, recognized fibrillogenesis parameter is amino acid content, whereas the influence of amino acid sequence distribution is not as well understood. The fibril core of aS encompasses five regions of high beta-sheet propensity, termed beta1-beta5. Using four aS variants with identical amino acid compositions but rearranged pseudorepeat motifs, we show that beta2-beta5 sequence clustering, but not order, is important for efficient fibrillogenesis. For molecular species progressing toward the fibrillar state, order invariably increases; i.e., the spatial arrangement of sequence elements becomes restricted. By introducing disulfide bonds in a fibril structure-based manner, we demonstrated that a successful protofibril-to-fibril conversion is dependent upon the spatial arrangement of sequence elements of high beta-sheet propensity. Moreover, a disulfide-linked aS dimer is shown to fibrillize rapidly. We propose that a conformational search underlies the emergence of a fibrillar aS nucleus that is directed by gaps in sequence between beta-sheet regions and the accessible range of spatial beta-sheet arrangements in soluble, prefibrillar oligomers. On the basis of the universal cross-beta-sheet structure of amyloid fibrils, these principles are expected to apply to a wide range of amyloidogenic proteins.

Antiviral compounds discovered by virtual screening of small-molecule libraries against dengue virus E protein.

Infection by the mosquito-borne dengue virus causes dengue fever and the sometimes fatal dengue hemorrhagic fever. The increasing number of dengue infections per year suggests that the virus is becoming more virulent and its transmission is expanding. Nevertheless, no effective treatment for dengue infection currently exists. In a search for antiviral agents effective against dengue virus, we investigated the potential of targeting a structural protein site rather than an enzymatic one. Using this approach, we now report the discovery of a small molecule ligand that inhibits viral growth. Our results also provide the first evidence that the binding site, a pocket located at the hinge between domains 1 and 2 of the envelope protein (E protein) on the virus surface, is a valid target for antiviral therapy. Ligand candidates were identified from libraries of approximately 142,000 compounds using a computational high-throughput screening protocol targeting this pocket of the E protein. Cell-based assays were conducted on 23 top-ranked compounds. Among four with good antiviral activity profiles, the compound P02 was found to inhibit viral reproduction at micromolar concentrations. Using saturation transfer difference NMR spectroscopy, we also show that the compound binds virus and competes for binding E protein with the known ligand N-octyl-beta-D-glucoside. Together, the results are consistent with an inhibition mechanism against maturation or host-cell entry mediated by ligand binding to the E-protein pocket. P02 is a promising lead compound for future development of an effective treatment against dengue virus and related flaviviruses.

Solution conformation of alphaA-conotoxin EIVA, a potent neuromuscular nicotinic acetylcholine receptor antagonist from Conus ermineus.

We report the solution three-dimensional structure of an alphaA-conotoxin EIVA determined by nuclear magnetic resonance spectroscopy and restrained molecular dynamics. The alphaA-conotoxin EIVA consists of 30 amino acids representing the largest peptide among the alpha/alphaA-family conotoxins discovered so far and targets the neuromuscular nicotinic acetylcholine receptor with high affinity. alphaA-Conotoxin EIVA consists of three distinct structural domains. The first domain is mainly composed of the Cys3-Cys11-disulfide loop and is structurally ill-defined with a large backbone root mean square deviation of 1.91 A. The second domain formed by residues His12-Hyp21 is extremely well defined with a backbone root mean square deviation of 0.52 A, thus forming a sturdy stem for the entire molecule. The third C-terminal domain formed by residues Hyp22-Gly29 shows an intermediate structural order having a backbone root mean square deviation of 1.04 A. A structurally ill-defined N-terminal first loop domain connected to a rigid central molecular stem seems to be the general structural feature of the alphaA-conotoxin subfamily. A detailed structural comparison between alphaA-conotoxin EIVA and alphaA-conotoxin PIVA suggests that the higher receptor affinity of alphaA-conotoxin EIVA than alphaA-conotoxin PIVA might originate from different steric disposition and charge distribution in the second loop "handle" motif.