Nanodomain Formation in Planar Supported Lipid Bilayers Composed of Fluid and Polymerized Dienoyl Lipids.

Polymerization of synthetic phospholipid monomers has been widely used to enhance the stability of lipid membranes in applications such as membrane-based biosensing, where the inherent instability of fluid-phase lipid bilayers can be problematic. However, lipid polymerization typically decreases membrane fluidity, which may be required to maintain the activity of reconstituted integral proteins and peptides. Prior work has shown that a bilayer composed of binary mixtures of poly(lipid) and fluid lipid exhibits enhanced stability and supports the function of incorporated biomolecules. This work examines the structural basis of these findings using planar supported lipid bilayers (PSLBs) composed of binary mixtures of a polymerizable lipid, 1,2-bis[10-(2',4'-hexadienoloxy)decanoyl]-sn-glycero-3-phosphocholine (bis-SorbPC), and a nonpolymerizable lipid, 1,2-diphytanoyl-sn-glycero-3-phosphocholine (DPhPC). Fluorescence recovery after photobleaching (FRAP) measurements showed that long-range lateral diffusion was minimally affected when the poly(lipid) mole ratio was ≤0.7. Atomic force microscopy, used to examine phase segregation in these PSLBs, showed that DPhPC forms a continuous lipid matrix that is 0.2-0.4 nm thicker than the island-like poly(bis-SorbPC) domains, with lateral dimensions of ≤200 nm. The nanoscale phase segregation allows for long-range lateral diffusion of lipid probes in the DPhPC matrix. The combination of fluidity and stability in these materials should make them useful in membrane-based biosensing applications.

Photopolymerization of Dienoyl Lipids Creates Planar Supported Poly(lipid) Membranes with Retained Fluidity.

Polymerization of substrate-supported bilayers composed of dienoylphosphatidylcholine (PC) lipids is known to greatly enhance their chemical and mechanical stability; however, the effects of polymerization on membrane fluidity have not been investigated. Here planar supported lipid bilayers (PSLBs) composed of dienoyl PCs on glass substrates were examined to assess the degree to which UV-initiated polymerization affects lateral lipid mobility. Fluorescence recovery after photobleaching (FRAP) was used to measure the diffusion coefficients (D) and mobile fractions of rhodamine-DOPE in unpolymerized and polymerized PSLBs composed of bis-sorbyl phosphatidylcholine (bis-SorbPC), mono-sorbyl-phosphatidylcholine (mono-SorbPC), bis-dienoyl-phosphatidylcholine (bis-DenPC), and mono-dienoyl phosphatidylcholine (mono-DenPC). Polymerization was performed in both the Lα and Lß phase for each lipid. In all cases, polymerization reduced membrane fluidity; however, measurable lateral diffusion was retained which is attributed to a low degree of polymerization. The D values for sorbyl lipids were less than those of the denoyl lipids; this may be a consequence of the distal location of polymerizable group in the sorbyl lipids which may facilitate interleaflet bonding. The D values measured after polymerization were 0.1-0.8 of those measured before polymerization, a range that corresponds to fluidity intermediate between that of a Lα phase and a Lß phase. This D range is comparable to ratios of D values reported for liquid-disordered (Ld) and liquid-ordered (Lo) lipid phases and indicates that the effect of UV polymerization on lateral diffusion in a dienoyl PSLB is similar to the transition from a Ld phase to a Lo phase. The partial retention of fluidity in UV-polymerized PSLBs, their enhanced stability, and the activity of incorporated transmembrane proteins and peptides is discussed.

Computational investigation of the competition between the concerted Diels-Alder reaction and formation of diradicals in reactions of acrylonitrile with nonpolar dienes.

The energetics of the Diels-Alder cycloaddition reactions of several 1,3-dienes with acrylonitrile, and the energetics of formation of diradicals, were investigated with density functional theory (B3LYP and M06-2X) and compared to experimental data (Hall et al., J. Org. Chem.1993, 58, 7049-7058). For the reaction of 2,3-dimethyl-1,3-butadiene with acrylonitrile, the concerted reaction is favored over the diradical pathway by 2.5 kcal/mol using B3LYP/6-31G(d); experimentally, this reaction gives both cycloadduct and copolymer. The concerted cycloaddition of cyclopentadiene with acrylonitrile is preferred computationally over the stepwise pathway by 5.9 kcal/mol; experimentally, only the Diels-Alder adduct is formed. For the reactions of (E)-1,3-pentadiene and acrylonitrile, both cycloaddition and copolymerization were observed experimentally; these trends were mimicked by the computational results, which showed only a 1.2 kcal/mol preference for the concerted pathway. For the reactions of (Z)-1,3-pentadiene and acrylonitrile, the stepwise pathway is preferred by 3.9 kcal/mol, in agreement with previous experimental findings that only polymerization occurs. M06-2X is known to give more accurate activation and reaction energetics (Pieniazek, et al., Angew. Chem. Int.2008, 47, 7746-7749), but the energies of diradicals are too high.

Synthesis of a Diverse Library of N,N-Dimethylamino Containing Monomers Appropriate as Lipid Head Groups.

We report on the synthesis of a diverse library of N,N-dimethylamino containing monomers. Subjecting these monomers to Chabrier reaction conditions would yield lipids with polymerizable head groups. This library of lipid head groups is equipped with a variety of arm lengths containing reduction-oxidation polymerizable groups at the terminus.

Thermodynamic control of the polymerizability of five-, six-, and seven-membered lactones.

The thermodynamics of polymerization of epsilon-caprolactone and 1,4-dioxan-2-one has been investigated theoretically and compared with that recently reported for delta-valerolactone and gamma-butyrolactone. Specifically, the ability of these monomers to polymerize has been related to the strain of the rings, the Gibbs free energy of simple models for ring-opening reactions of the cyclic lactones, and the conformational preferences of linear model compounds of the corresponding homopolyesters. The results are fully consistent with the lack of polymerizability of gamma-butyrolactone, while the ring openings of epsilon-caprolactone and delta-valerolactone have been found to be exergonic processes. Polymerizability of 1,4-dioxan-2-one has been found to be favored, even though less than that of epsilon-caprolactone and delta-valerolactone. Two factors explain these features: (i) the strain of the ester group in the lactones increases with the exergonic character of the ring-opening process, and (ii) the stability of coiled conformations in model compounds follows this order: poly-4-hydroxybutyrate > poly(1,4-dioxan-2-one) > poly-6-hydroxycaproate approximately poly-5-hydroxyvalerate. Finally, the influence of the environment on the polymerizability of the three cyclic lactones is discussed in detail.

Why delta-valerolactone polymerizes and gamma-butyrolactone does not.

gamma-Butyrolactone, unlike delta-valerolactone, does not polymerize despite a strain energy of approximately 8 kcal mol-1 which could be relieved by opening the s-cis lactone ester bond to an s-trans ester bond in the polymer. To explain this anomaly, we have applied quantum mechanical methods to study the thermochemistry involved in the ring-opening reactions of gamma-butyrolactone and delta-valerolactone, the conformational preferences of model molecules that mimic their corresponding homopolyesters, and the variation of enthalpy associated to the polymerizability of such two cyclic lactones. The overall results indicate that the lack of polymerizability of gamma-butyrolactone should be attributed to the low strain of the ring, which shows much less geometric distortion in the ester group than delta-valerolactone, and the notable stability of the coiled conformations found in model compounds of poly-4-hydroxybutyrate.

A social cognitive approach to burnout in elite athletes.

The purpose of this study was to investigate athlete burnout from a social-cognitive perspective by examining the relationship between social cognitive motivational variables at the start of a season and signs of burnout in elite athletes at the end of the season. Participants were 141 (F=60, M=81) elite winter sport athletes competing in Alpine skiing, Biathlon, Nordic Combined, Nordic skiing, and Speed skating. Participants completed a comprehensive motivation assessment package at the start of the season and a further burnout inventory at season's end. Results indicated that motivational dispositions, measures of the achievement climate, perceived ability and dimensions of perfectionism were associated with burnout in a conceptually consistent manner. Furthermore, the elite athletes could be grouped into two motivational profiles based on variables measured at the start of the season, one being adaptive and the other maladaptive. At season's end, the two different motivational profiles yielded distinctively different responses on an inventory assessing signs of burnout. The current findings strengthen the claim that burnout in elite athletes may not simply be "motivation gone awry" as Gould has suggested, but an inevitable consequence of exhibiting a maladaptive motivational profile.

Reconstitution of rhodopsin into polymerizable planar supported lipid bilayers: influence of dienoyl monomer structure on photoactivation.

G-protein-coupled receptors (GPCRs) play key roles in cellular signal transduction and many are pharmacologically important targets for drug discovery. GPCRs can be reconstituted in planar supported lipid bilayers (PSLBs) with retention of activity, which has led to development of GPCR-based biosensors and biochips. However, PSLBs composed of natural lipids lack the high stability desired for many technological applications. One strategy is to use synthetic lipid monomers that can be polymerized to form robust bilayers. A key question is how lipid polymerization affects GPCR structure and activity. Here we have investigated the photochemical activity of bovine rhodopsin (Rho), a model GPCR, reconstituted into PSLBs composed of lipids having one or two polymerizable dienoyl moieties located in different regions of the acyl chains. Plasmon waveguide resonance spectroscopy was used to compare the degree of Rho photoactivation in fluid and poly(lipid) PSLBs. The position of the dienoyl moiety was found to have a significant effect: polymerization near the glycerol backbone significantly attenuates Rho activity whereas polymerization near the acyl chain termini does not. Differences in cross-link density near the acyl chain termini also do not affect Rho activity. In unpolymerized PSLBs, an equimolar mixture of phosphatidylethanolamine and phosphatidylcholine (PC) lipids enhances activity relative to pure PC; however after polymerization, the enhancement is eliminated which is attributed to stabilization of the membrane lamellar phase. These results should provide guidance for the design of robust lipid bilayers functionalized with transmembrane proteins for use in membrane-based biochips and biosensors.

Systematic evaluation of the conformational properties of aliphatic omega-hydroxy acids.

A systematic conformational study of omega-hydroxy acids, HO-(CH(2))(n)()-COOH with n ranging from 2 to 5, has been performed using quantum mechanical calculations at the MP2 level. To distinguish between intrinsic and environmentally induced conformational preferences, calculations have been carried out in both gas phase and chloroform solution, a polarizable continuum solvation model being used to represent the latter. Results indicate a consistent conformational behavior, as reflects the feature that the lowest energy minimum for n = 2, 3, 4, and 5 corresponds to the g+g-t, g+g+g-t, g-g+g+g-t, and g+g-g+g+g-t conformations, respectively. Furthermore, the stability of the extended and semi-extended conformations increases systematically with the size of the central aliphatic segment. The relationship between the size of the aliphatic segment and the stability of folded conformations is analyzed and discussed.

Systematic evaluation of the conformational properties of aliphatic omega-methoxy methyl esters.

[structure: see text] A systematic conformational study of omega-methoxy methyl esters, CH(3)O-(CH2)n-COO-CH3 with n = 3 and 4, has been performed using quantum mechanical calculations at the MP2 level. Calculations have been carried out in both gas phase and chloroform solution, a polarizable continuum solvation model being used to represent the latter. Results have been compared with those recently obtained for the analogues omega-hydroxy acids, HO-(CH2)n-COOH with n = 3 and 4. The compounds with n = 3 clearly favor coiled conformations, the population expected for extended and semiextended conformations being very low. However, for compounds with n = 4 the minimum energy extended and semiextended structures become considerably more stable. The overall results indicate that the conformational preferences of the central aliphatic segment of omega-methoxy methyl esters and omega-hydroxy acids are not influenced by the formation of intramolecular O-H...O hydrogen bonds.

Effect of Salmonella typhimurium ferric uptake regulator (fur) mutations on iron- and pH-regulated protein synthesis.

Fur is an important regulatory protein known to function in the presence of iron as a repressor of iron-controlled genes. It was recently discovered that Fur is also essential to Salmonella typhimurium for mounting an adaptive acid tolerance response (J. W. Foster, J. Bacteriol 173:6896-6902, 1991). Because little is known about the effect of Fur on the physiology of this enteric pathogen, a systematic two-dimensional polyacrylamide gel electrophoresis (PAGE) analysis was conducted to identify proteins whose synthesis is linked to iron levels. Mutations in the fur locus were identified and used to classify which proteins are controlled by Fur. Thirty-six proteins were overtly affected by iron availability, most of which were clearly under the control of Fur. Although most of the Fur-dependent proteins were under negative control, a significant portion (15 of 34) appeared to be under a form of positive control. Nine of the positively controlled proteins required Fur and iron for expression. However, Fur lacking iron was also required for the induction of six gene products. Surprisingly, not all iron-regulated proteins were controlled by Fur and not all Fur-dependent proteins were obviously regulated by iron status. Because fur mutants fail to mount an effective acid tolerance response, we made a comparative two-dimensional PAGE analysis of 100 total acid- and iron-regulated gene products. Production of most of these proteins was regulated by only one of the two stresses, yet a clear subset of seven genes were influenced by both acid and iron and were also controlled by fur. These proteins were also members of the acid tolerance response modulon. Consistent with the fur effect on pH-regulated protein synthesis, fur mutants lacked the inducible pH homeostasis system associated with the acid tolerance response. The results provide further evidence that Fur has an extensive impact on gene expression and cellular physiology and suggest an explanation for the acid-sensitive nature of fur mutants.

The role of fur in the acid tolerance response of Salmonella typhimurium is physiologically and genetically separable from its role in iron acquisition.

The response of Salmonella typhimurium to low pH includes a low-pH protection system called the acid tolerance response (ATR). The iron-regulatory protein Fur has been implicated in the ATR since fur mutants are acid sensitive and cause altered expression of several acid shock proteins (J. W. Foster, J. Bacteriol. 173:6896-6902, 1991). We have determined that the acid-sensitive phenotype of fur mutations is indeed due to a defect in Fur that can be complemented by a fur(+)-containing plasmid. However, changes in cellular iron status alone did not trigger the ATR. Cells clearly required exposure to low pH in order to induce acid tolerance. The role of Fur in acid tolerance was found to extend beyond regulating iron acquisition. A mutation in fur converting histidine 90 to an arginine (H90R) eliminated Fur-mediated iron regulation of enterochelin production and deregulated an iroA-lacZ fusion but had no effect on acid tolerance. The H90R iron-blind Fur protein also mediated acid shock induction of several Fur-dependent acid shock proteins and acid control of the hyd locus. In addition, a Fur superrepressor that constitutively repressed iron-regulated genes mediated normal Fur-dependent acid tolerance and pH-controlled gene expression. The results indicate the acid-sensing and iron-sensing mechanisms of Fur are separable by mutation and reinforce the concept of Fur as a major global regulator in the cell.

Inducible pH homeostasis and the acid tolerance response of Salmonella typhimurium.

The acid tolerance response (ATR) is an adaptive system triggered at external pH (pHo) values of 5.5 to 6.0 that will protect cells from more severe acid stress (J. Foster and H. Hall, J. Bacteriol. 172:771-778, 1990). Correlations between the internal pH (pHi) of adapted versus unadapted cells at pHo of 3.3 indicate that the ATR system produces an inducible pH-homeostatic function. This function serves to maintain the pHi above 5 to 5.5. Below this range, cells rapidly lose viability. Development of this pH homeostasis mechanism was sensitive to protein synthesis inhibitors and operated only to augment the pHi at pHo values below 4. In contrast, classical constitutive pH homeostasis was insensitive to protein synthesis inhibitors and was efficient only at pHo values above 4. Physiological studies indicated an important role for the Mg(2+)-dependent proton-translocating ATPase in affording ATR-associated survival during exposure to severe acid challenges. Along with being acid intolerant, cells deficient in this ATPase did not exhibit inducible pH homeostasis. We speculate that adaptive acid tolerance is important to Salmonella species in surviving acid encounters in both the environment and the infected host.

Adaptive acidification tolerance response of Salmonella typhimurium.

Salmonella typhimurium can encounter a wide variety of environments during its life cycle. One component of the environment which will fluctuate widely is pH. In nature, S. typhimurium can experience and survive dramatic acid stresses that occur in diverse ecological niches ranging from pond water to phagolysosomes. However, in vitro the organism is very sensitive to acid. To provide an explanation for how this organism survives acid in natural environments, the adaptive ability of S. typhimurium to become acid tolerant was tested. Logarithmically grown cells (pH 7.6) shifted to mild acid (pH 5.8) for one doubling as an adaptive procedure were 100 to 1,000 times more resistant to subsequent strong acid challenge (pH 3.3) than were unadapted cells shifted directly from pH 7.6 to 3.3. This acidification tolerance response required protein synthesis and appears to be a specific defense mechanism for acid. No cross protection was noted for hydrogen peroxide, SOS, or heat shock. Two-dimensional polyacrylamide gel electrophoretic analysis of acid-regulated polypeptides revealed 18 proteins with altered expression, 6 of which were repressed while 12 were induced by mild acid shifts. An avirulent phoP mutant was 1,000-fold more sensitive to acid than its virulent phoP+ parent, suggesting a correlation between acid tolerance and virulence. The Mg2(+)-dependent proton-translocating ATPase was also found to play an important role in acid tolerance. Mutants (unc) lacking this activity were unable to mount an acid tolerance response and were extremely acid sensitive. In contrast to these acid-sensitive mutants, a constitutively acid-tolerant mutant (atr) was isolated from wild-type LT2 after prolonged acid exposure. This mutant overexpressed several acidification tolerance response polypeptides. The data presented reveal an important acidification defense modulon with broad significance toward survival in biologically hostile environments.

The stationary-phase sigma factor sigma S (RpoS) is required for a sustained acid tolerance response in virulent Salmonella typhimurium.

The acid tolerance response (ATR) of log-phase Salmonella typhimurium is induced by acid exposures below pH 4.5 and will protect cells against more extreme acid. Two systems are evident: a transiently induced system dependent on the iron regulator Fur that provides a moderate degree of acid tolerance and a more effective sustained ATR that requires the alternate sigma factor sigma S encoded by rpoS. Differences between the acid responses of virulent S. typhimurium and the attenuated laboratory strain LT2 were attributed to disparate levels of RpoS caused by different translational starts. The sustained ATR includes seven newly identified acid shock proteins (ASPs) that are dependent upon sigma S for their synthesis. It is predicted that one or more of these ASPs is essential for the sustained system. The sustained ATR also provided cross-protection to a variety of other environmental stresses (heat, H2O2 and osmolarity); however, adaptation to the other stresses did not provide significant acid tolerance. Therefore, in addition to starvation, acid shock serves as an important signal for inducing general stress resistance. Consistent with this model, sigma S proved to be induced by acid shock. Our results also revealed a connection between the transient and sustained ATR systems. Mutations in the regulator atbR are known to cause the overproduction of ten proteins, of which one or more can suppress the acid tolerance defect of an rpoS mutant. One member of the AtbR regulon, designated atrB, was found to be co-regulated by sigma S and AtbR. Both regulators had a negative effect on atrB expression. The results suggest AtrB serves as a link between the sustained and transient ATR systems. When sigma S concentrations are low, a compensatory increase in AtrB is required to engage the transiently induced, RpoS-independent system of acid tolerance. Results also suggest different acid-sensitive targets occur in log-phase versus stationary-phase cells.

Regulatory circuits involved with pH-regulated gene expression in Salmonella typhimurium.

Salmonella typhimurium encounters a variety of acid conditions during both its natural and pathogenic existence. The ability of this organism to respond transcriptionally to low pH is an area of active interest but little knowledge. As part of an ongoing investigation of low-pH adaptation, 18 pH-controlled lacZ operon fusions in Salmonella typhimurium have been identified (15 in this study) and categorized into at least 11 different loci. They include iroA (at 57 min), aciA (99 min), aciB (90-93 min), aciD (ompC, 45 min), aciJ, aciK (33-36 min), aniC (93 min), anil (33-36 min), hyd (59 min), cadA (54 min) and aniG (63 min). All but two were induced by low pH. One of the exceptions, the iron-regulated iroA locus, was induced at high pH. The unusual aciA locus was induced by low pH under semiaerobic conditions but high pH under aerobic conditions. Most of the other aci genes were expressed best under anaerobic conditions. Many of these genes exhibited strict co-inducer requirements for small molecules to be expressed in minimal medium. These included iron for iroA, tyrosine for aniC, I and aciK, mannose for aniG, formate for hyd, lysine for cadA, and unknown components of complex medium for aciA, aciB and aciD. Six regulatory circuits were revealed involving at least five regulatory loci (fur, oxrG, earAB, earC and ompR). As part of the adaptive response to low pH, S. typhimurium will induce an acid protection system called the acid tolerance response (ATR). As has been shown for fur mutations, the oxrG regulatory mutation interfered with the normal induction of this system.