Lipid vertical motion and related steric effects in bilayer membranes

We present a theoretical model of a lipid bilayer in its gel state which explicity couples the vertical displacements of the lipid chains to their conformational state. In this model the chains are free to move longitudinally under a potential due to the neighbouring chains. The potential is due to a restoring force with a force constant k and thus acts to keep them in the local plane as defined by their nearest neighbours. It is demonstrated that the force constant k is directly related to the internal bilayer pressure, , and that if a value =33 dynes/cm is assumed then k=17.3 dynes/cm. Steric effects are explicity included by allowing chains to twist into free volume created by the vertical displacement of neighbouring chains. The Hamiltonian is expressed in terms of the projection operators, P _ij , describing the displacement of chain i relative to a neighbour j, and G _ij describing the direction of a twist in chain i. The model is solved both analytically and via Monte Carlo simulations for a one-dimensional system. The possibility of phase-transitions in two-dimensions and the relevance to the bilayer pre-transition is discussed.This work was first presented in poster form at the Canadian Biochemical Society Conference held in Banff, Alberta, Canada, April 29–May 4, 1984Work supported in part by the Natural Sciences and Engineering Research Council of Canada, Le Fonds Formation des Chercheurs et Action a la Recherche du Quebec, and the Advisory Research Council of Queen's University     

影响类弹性蛋白多肽自组装成微球的因素及其作用机制

影响类弹性蛋白多肽(ELPs)自组装成微球的因素较多,目前尚缺乏系统研究。以类弹性蛋白多肽[KV8F]n为对象,利用动态光散射仪测定了不同条件下其自组装成微球的粒径。结果表明:随着分子量的增加ELPs形成的微球粒径也随之增大,粒径的均一度减小;当盐浓度低于0.4 mol/L时,盐浓度的增加,微球粒径相应增加,而盐浓度高于0.4 mol/L则呈减少的趋势,但粒径均大于1.1μm;而当ELPs末端融合木聚糖酶和1,3-丙二醇氧化还原酶后,其自组装形成的微球粒径急剧减小,约为游离ELPs的1/10,分别为151.0 nm和174.2 nm。导致这种现象的原因可能是酶分子和ELPs通过静电引力相互作用后,酶分子的空间位阻妨碍了ELPs分子的聚集。     

Steric Engineering of Alkylthiolation Side Chains to Finely Tune Miscibility in Nonfullerene Polymer Solar Cells

Morphology and miscibility control are still a great challenge in polymer solar cells. Despite physical tools being applied, chemical strategies are still limited and complex. To finely tune blend miscibility to obtain optimized morphology, chemical steric engineering is proposed to systemically investigate its effects on optical and electronic properties, especially on a balance between crystallinity and miscibility. By changing the alkylthiol side chain orientation different steric effects are realized in three different polymers. Surprisingly, the photovoltaic device of the polymer PTBB‐m with middle steric structure affords a better power conversion efficiency, over 12%, compared to those of the polymers PTBB‐o and PTBB‐p with large or small steric structures, which could be attributed to a more balanced blend miscibility without sacrificing charge‐carrier transport. Space charge‐limited current, atomic force microscopy, grazing incidence wide angle X‐ray scattering, and resonant soft X‐ray scattering measurements show that the steric engineering of alkylthiol side chains can have significant impacts on polymer aggregation properties, blend miscibility, and photovoltaic performances. More important, the control of miscibility via the simple chemical approach has preliminarily proved its great potential and will pave a new avenue for optimizing the blend morphology.     

Steric hindrance controls pyridine nucleotide specificity of a flavin‐dependent NADH:quinone oxidoreductase

The crystal structure of the NADH:quinone oxidoreductase PA1024 has been solved in complex with NAD⁺ to 2.2 Å resolution. The nicotinamide C4 is 3.6 Å from the FMN N5 atom, with a suitable orientation for facile hydride transfer. NAD⁺ binds in a folded conformation at the interface of the TIM‐barrel domain and the extended domain of the enzyme. Comparison of the enzyme‐NAD⁺ structure with that of the ligand‐free enzyme revealed a different conformation of a short loop (75–86) that is part of the NAD⁺‐binding pocket. P78, P82, and P84 provide internal rigidity to the loop, whereas Q80 serves as an active site latch that secures the NAD⁺ within the binding pocket. An interrupted helix consisting of two α‐helices connected by a small three‐residue loop binds the pyrophosphate moiety of NAD⁺. The adenine moiety of NAD⁺ appears to π–π stack with Y261. Steric constraints between the adenosine ribose of NAD⁺, P78, and Q80, control the strict specificity of the enzyme for NADH. Charged residues do not play a role in the specificity of PA1024 for the NADH substrate.     

Primary structure effects on peptide group hydrogen exchange

The rate of exchange of peptide group NH hydrogens with the hydrogens of aqueous solvent is sensitive to neighboring side chains. To evaluate the effects of protein side chains, all 20 naturally occurring amino acids were studied using dipeptide models. Both inductive and steric blocking effects are apparent. The additivity of nearest-neighbor blocking and inductive effects was tested in oligo-and polypeptides and, suprisingly, confirmed. Reference rates for alanine-containing peptides were determined and effects of temperature considered. These results provide the information necessary to evaluate measured protein NH to ND exchange rates by comparing them with rates to be expected for the same amino acid sequence is unstructured aligo- and polypeptides. The application of this approach to protein studies is discussed. © 1993 Wiley-Liss, Inc.     

Steric and electronic interactions controlling the cis/trans isomer equilibrium at X‐pro tertiary amide motifs in solution

A systematic understanding of the noncovalent interactions that influence the structures of the cis conformers and the equilibrium between the cis and the trans conformers, of the X‐Pro tertiary amide motifs, is presented based on analyses of ¹H‐, ¹³C‐NMR and FTIR absorption spectra of two sets of homologous peptides, X‐Pro‐Aib‐OMe and X‐Pro‐NH‐Me (where X is acetyl, propionyl, isobutyryl and pivaloyl), in solvents of varying polarities. First, this work shows that the cis conformers of any X‐Pro tertiary amide motif, including Piv‐Pro, are accessible in the new motifs X‐Pro‐Aib‐OMe, in solution. These conformers are uniquely observable by FTIR spectroscopy at ambient temperatures and by NMR spectroscopy from temperatures as high as 273 K. This is made possible by the persistent presence of n_i‐1→π_i* interactions at Aib, which also influence the disappearance of steric effects at these cis X‐Pro rotamers. Second, contrary to conventional understanding, the energy contribution of steric effects to the cis/trans equilibrium at the X‐Pro motifs is found to be nonvariant (0.54 ± 0.02 kcal/mol) with increase in steric bulk on the X group. Third, the current studies provide direct evidence for the weak intramolecular interactions namely the n_i‐1→π_i*, the N_Pro???H_i+1 (C₅a), and the C₇ hydrogen bond that operate and influence the structures, stabilities, and dynamics between different conformational states of X‐Pro tertiary amide motifs. NMR and IR spectral data suggest that the cis conformers of X‐Pro motifs are ensembles of short‐lived rotamers about the C′_X–N_Pro bond. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 66–77, 2014.     

Synergistic Mixtures of Fungitoxic Monochloro and Dichloro-8-Quinolinols against Five Fungi

Fourteen mono- and dichloro-8-quinolinols were tested against five fungi (Aspergillus niger, A. oryzae, Myrothecium verrucaria, Trichoderma viride, and Mucor circinelloides) and compared with the fungitoxicity of 8-quinolinol in Yeast Nitrogen Base containing 1% D-glucose and 0.088% L-asparagine. All of the compounds were more fungitoxic than 8-quinolinol except for the surprising activity of 8-quinolinol against A. oryzae. Mixtures of the MICs of monochloro- and dichloro-8-quinolinols in which the halogens were in different positions of the quinoline ring showed synergism. Comparable mixtures in which one position of each compound was occupied by the same halogen showed additive activity. In a different study we showed that 3,5,6-, 3,5,7-, 4,5,7-, and 5,6,7-trichloro-8-quinolinols were not toxic to M. circinelloides, whereas the combinations of the correspondingly substituted mono- and dichloro-8-quinolinols as well as 3,6-dichloro- and 5,7-dichloro-8-quinolinols were inhibitory. This indicated that a steric factor can be involved in affecting fungitoxicity.     

Structure–activity relationships in platinum–acridinylthiourea conjugates: effect of the thiourea nonleaving group on drug stability, nucleobase affinity, and in vitro cytotoxicity

The synthesis, cytotoxicity, and nucleoside binding of some platinum–acridinylthiourea conjugates derived from the prototypical compound [PtCl(en)(ACRAMTU)](NO₃)₂ {PT-ACRAMTU; en=ethane-1,2-diamine, ACRAMTU=1-[2-(acridin-9-ylamino)ethyl]-1,3-dimethylthiourea, protonated form} are reported. To establish structure–activity relationships within this class of compounds, systematic changes were made to the thiourea nonleaving group, which links the intercalator to platinum. Three new derivatives of ACRAMTU, one di-, one tri-, and one tetraalkylated, were generated, where the degree of alkylation indicates the number of alkyl groups attached to the SCN₂ framework. Subsequent reaction of the tri- and tetraalkylated derivatives with activated [PtCl₂(en)] yielded the corresponding platinum conjugates. The dialkylated thiourea gave an unstable complex, which was not included in the studies. The crystal structure of PT-ACRAMTU·MeOH has been determined. In the solid state, one axial position of the square-planar platinum coordination sphere is partially shielded by the bulky thiourea group, providing a strong rationale for the kinetic inertness of the compound. The cytotoxicity of the prototype, the two new conjugates, and cisplatin was assessed in ovarian (A2780, A2780/CP), lung (NCI-H460), and colon (RKO) cancer cell lines using clonogenic survival assays. The derivatives containing trialkylated thiourea groups showed activity similar or superior to cisplatin, with IC₅₀ values in the low micromolar concentration range. The complex modified with the tetraalkylated (bulkiest) thiourea was significantly less active, possibly due to the greatly decreased rate of binding to nucleobase nitrogen (¹H NMR spectroscopy), but was most efficient at overcoming cross resistance to cisplatin in A2780/CP. Possible consequences of the reported structural modifications for the mechanism of action of these agents are discussed.Electronic Supplementary Material Supplementary material is available in the online version of this article at Abbreviations ACRAMTU 1-[2-(acridin-9-ylamino)ethyl]-1,3-dimethylthiourea - Boc t-butyl carbamate - dGuo 2-deoxyguanosine - dien N¹-(2-aminoethyl)ethane-1,2-diamine - en ethane-1,2-diamine - HEPES 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid - PT-ACRAMTU [PtCl(en)(ACRAMTU)](NO₃)₂ - TSP 3-(trimethylsilyl)propionate, sodium salt     

An electronic effect on protein structure

The well-known preference of the peptide bond for the trans conformation has been attributed to steric effects. Here, we show that a proline residue with an N-formyl group (H(i-1)-C'(i-1)=O(i-1)), in which H(i-1) presents less steric hindrance than does O(i-1), likewise prefers a trans conformation. Thus, the preference of the peptide bond for the trans conformation cannot be explained by steric effects alone. Rather, an n --> pi* interaction between the oxygen of the peptide bond (O(i-1)), and the subsequent carbonyl carbon in the polypeptide chain (C'(i)) also contributes to this preference. The O(i-1) and C'(i) distance and O(i-1).C'(i)=O(i) angle are especially favorable for such an n --> pi* interaction in a polyproline II helix. We propose that this electronic effect provides substantial stabilization to this and other elements of protein structure.