A novel leaflet-selective fluorescence labeling technique reveals differences between inner and outer leaflets at high bilayer curvature

AbstractUnderstanding the differences in the physical properties of the inner and outer leaflet of membranes and how the leaflets are coupled to each other requires methods that can selectively label both the outer and inner leaflets. In this report we introduce a combined chromatography/cyclodextrin method for selective labeling of the inner leaflet. Combining this method with selective labeling of the outer leaflet, we are able to show that there is a distinct difference in polar headgroup physical properties of the inner and outer leaflet headgroups in small unilamellar vesicles composed of a wide variety of phosphatidylcholines and a phosphaticylcholine/sphingomyelin mixture. It appears that the inner leaflet headgroups are more tightly packed than those of the outer leaflet. This differential packing disappears when vesicle size increases, showing that it is a consequence of membrane curvature. Differential packing is also reduced as acyl chain length is decreased. In the future, selective leaflet labeling is likely to be a powerful tool for investigating the properties of asymmetric lipid vesicles

The Phenyltetraene Lysophospholipid Analog PTE-ET-18-OMe as a Fluorescent Anisotropy Probe of Liquid Ordered Membrane Domains (Lipid Rafts) and Ceramide-Rich Membrane Domains

Author manuscript. Published in final edited form as: Biochim Biophys Acta. 2007 September; 1768(9): 2213–2221.The conjugated phenyltetraene PTE-ET-18-OMe (all-(E)-1-O-(15’-Phenylpentadeca-8’,10’,12’,14’-tetraenyl)-2-O-methyl-rac-glycero-3-phosphocholine), is a recently developed fluorescent lysophospholipid analog of edelfosine, (Quesada et al. (2004) J. Med. Chem. 47, 5333–5335). We investigated the use of this analog as a probe of membrane structure. PTE-ET-18-OMe was found to have several properties that are favorable for fluorescence anisotropy (polarization) experiments in membranes, including low fluorescence in water and moderately strong association with lipid bilayers. PTE-ET-18-OMe has absorbance and fluorescence properties similar to those of diphenylhexatriene (DPH) probes, with about as large a difference between its fluorescence anisotropy in liquid disordered (Ld) and ordered states (gel and Lo) as observed for DPH. Also like DPH, PTE-ET-18-OMe has a moderate affinity for both gel state ordered domains and Lo state ordered domains (rafts). However, unlike fluorescent sterols or DPH (Megha and London (2004) J. Biol. Chem. 279, 9997–10004), PTE-ET-18-OMe is not displaced from ordered domains by ceramide. Also unlike DPH, PTE-ET-18-OMe shows only slow exchange between the inner and outer leaflets of membrane bilayers, and can thus be used to examine anisotropy of an individual leaflet of a lipid bilayer. Since PTE-ET-18-OMe is a zwitterionic molecule, it should not be as influenced by electrostatic interactions as are other probes that do not cross the lipid bilayer but have a net charge. We conclude that PTE-ET-18-OMe has some unique properties that should make it a useful fluorescence probe of membrane structure.This work was supported by NIH grant GM 48596 to EL and a Spanish MEC grant BQU2003/04413 to AUA.Peer reviewe

\u3csup\u3e1\u3c/sup\u3eH NMR Shows Slow Phospholipid Flip-Flop in Gel and Fluid Bilayers

We measured the transbilayer diffusion of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) in large unilamellar vesicles, in both the gel (Lβ′) and fluid (Lα) phases. The choline resonance of headgroup-protiated DPPC exchanged into the outer leaflet of headgroup-deuterated DPPC-d13 vesicles was monitored using 1H NMR spectroscopy, coupled with the addition of a paramagnetic shift reagent. This allowed us to distinguish between the inner and outer bilayer leaflet of DPPC, to determine the flip-flop rate as a function of temperature. Flip-flop of fluid-phase DPPC exhibited Arrhenius kinetics, from which we determined an activation energy of 122 kJ mol-1. In gel-phase DPPC vesicles, flip-flop was not observed over the course of 250 h. Our findings are in contrast to previous studies of solid-supported bilayers, where the reported DPPC translocation rates are at least several orders of magnitude faster than those in vesicles at corresponding temperatures. We reconcile these differences by proposing a defect-mediated acceleration of lipid translocation in supported bilayers, where long-lived, submicron-sized holes resulting from incomplete surface coverage are the sites of rapid transbilayer movement

Lipid Exchange between Borrelia burgdorferi and Host Cells

Borrelia burgdorferi, the agent of Lyme disease, has cholesterol and cholesterol-glycolipids that are essential for bacterial fitness, are antigenic, and could be important in mediating interactions with cells of the eukaryotic host. We show that the spirochetes can acquire cholesterol from plasma membranes of epithelial cells. In addition, through fluorescent and confocal microscopy combined with biochemical approaches, we demonstrated that B. burgdorferi labeled with the fluorescent cholesterol analog BODIPY-cholesterol or 3H-labeled cholesterol transfer both cholesterol and cholesterol-glycolipids to HeLa cells. The transfer occurs through two different mechanisms, by direct contact between the bacteria and eukaryotic cell and/or through release of outer membrane vesicles. Thus, two-way lipid exchange between spirochetes and host cells can occur. This lipid exchange could be an important process that contributes to the pathogenesis of Lyme disease

Scanning the membrane-bound conformation of helix 1 in the colicin E1 channel domain by site-directed fluorescence labeling

Helix 1 of the membrane-associated closed state of the colicin E1 channel domain was studied by site-directed fluorescence labeling where bimane was covalently attached to a single cysteine residue in each mutant protein. A number of fluorescence properties of the tethered bimane fluorophore were measured in the membranebound state of the channel domain, including fluorescence emission maximum, fluorescence quantum yield, fluorescence anisotropy, membrane bilayer penetration depth, surface accessibility, and apparent polarity. The data show that helix 1 is an amphipathic ␣-helix that is situated parallel to the membrane surface. A least squares fit of the various data sets to a harmonic function indicated that the periodicity and angular frequency for helix 1 are typical for an amphipathic ␣-helix (3.7 ؎ 0.1 residues per turn and 97 ؎ 3.0°, respectively) that is partially bathing into the membrane bilayer. Dual fluorescence quencher analysis also revealed that helix 1 is peripherally membrane-associated, with one face of the helix dipping into the lipid bilayer and the other face projecting toward the solvent. Finally, our data suggest that the helical boundaries of helix 1, at least at the C-terminal region, remain unaffected upon binding to the surface of the membrane in support of a toroidal pore model for this colicin. The colicins are a family of antimicrobial proteins that are secreted by Escherichia coli strains under environmental stress, because of nutrient depletion or overcrowding, and these proteins often target sensitive bacterial strains (1). The lethal actions of colicins against their target cells are manifested in a number of different modes that include the following: (i) formation of depolarizing ion channels in the cytoplasmic membrane, (ii) inhibition of protein and peptidoglycan synthesis, and (iii) degradation of cellular nucleic acids (1-7). In this context, the bacterial machinery responsible for colicin biological activity feature important mechanisms that are fundamental to various biological processes. These mechanisms include protein receptor binding, membrane translocation, membrane binding and protein unfolding, membrane insertion, voltage-gated ion channel formation, catalysis, and inhibition of enzymes. Colicin E1 is a member of the channel-forming subfamily of colicins and is secreted by E. coli that harbors the naturally occurring colE1 plasmid; the whole colicin consists of three functional segments, the translocation, receptor-binding domains, and channel-forming domains. Initially, the receptor-binding domain (8) interacts with the vitamin B 12 receptor of target cells (9). Following receptor recognition, the translocation domain associates with the tolA gene product, which permits the translocation of colicin E1 across the outer membrane and into the periplasm (10). In the periplasm, the channel domain undergoes a conformational change to an insertion-competent state and then inserts spontaneously into the cytoplasmic membrane of the host cell, forming an ion channel. The channel allows the passage of monovalent ions, resulting in the dissipation of the cationic gradients (H ϩ , K ϩ , and Na ϩ ) of the target cell, causing depolarization of the cytoplasmic membrane. In an effort to compensate for the membrane depolarization effected by the colicin E1 channel, Na ϩ /K ϩ -ATPase activity is increased in the host cell, resulting in the consumption of ATP reserves, without concomitant replenishment (11). The final outcome is host cell death. A number of techniques have been used to study the topology of the membrane-bound state of colicin E1. Studies of the surface topology of the colicin E1 channel peptide bound to liposomes have been performed using proteases, and it was found that the bound polypeptide is largely sensitized to trypsin proteolysis relative to that in aqueous solution (12). The N-terminal one-third of the 190-residue membrane-bound colicin E1 channel peptide is unbound or loosely bound with the C-terminal two-thirds showing little sensitivity to protease. The membrane-associated closed state of the channel was also studied by depth-dependent fluorescence quenching (13). This approach used Trp as the reporter spectroscopic probe and doxyl-labeled phospholipids as the quencher species. The results from this study were consistent with the presence of only two transmembrane segments in the closed channel and were in agreement with those obtained by Shin et al. (14) who conducted an ESR study of spin-labeled cysteine mutants of the channel peptide. Furthermore, the structure and dynamics of the gating mechanism of the colicin E1 channel were studied previously by hydrophobic photolabeling (15) and by site-specific biotinylation (4). Also, the membrane-bound volume of the colicin E1 channel peptide was determined using light scattering analysis and was found to be 177 nm 3 , suggesting that the peptide likely has a large hydration shell when membrane-bound (16). Tory and Merrill (17, 18) used a plethora of fluorescence methods to probe the membrane topology of the closed channel state, and they concluded that the monomeric channel features two states that are in rapid equilibrium in which one state is more heavily populated than the other. Furthermore, Zakharov et al. (19) proposed that the colicin E1 closed channel exists as a two-dimensional helical array with most of the helices appressed closely to the bilayer surface. Also, Kim et al. (20) used 15 N-labeled p190 colicin in oriented planar phospholipid bilayers and found that the data were consistent with a single transmembrane helica

Measurement of the Branching Fraction for B- --> D0 K*-

We present a measurement of the branching fraction for the decay B- --> D0 K*- using a sample of approximately 86 million BBbar pairs collected by the BaBar detector from e+e- collisions near the Y(4S) resonance. The D0 is detected through its decays to K- pi+, K- pi+ pi0 and K- pi+ pi- pi+, and the K*- through its decay to K0S pi-. We measure the branching fraction to be B.F.(B- --> D0 K*-)= (6.3 +/- 0.7(stat.) +/- 0.5(syst.)) x 10^{-4}.Comment: 7 pages, 1 postscript figure, submitted to Phys. Rev. D (Rapid Communications

Multi-ethnic genome-wide association study for atrial fibrillation

Atrial fibrillation (AF) affects more than 33 million individuals worldwide and has a complex heritability. We conducted the largest meta-analysis of genome-wide association studies (GWAS) for AF to date, consisting of more than half a million individuals, including 65,446 with AF. In total, we identified 97 loci significantly associated with AF, including 67 that were novel in a combined-ancestry analysis, and 3 that were novel in a European-specific analysis. We sought to identify AF-associated genes at the GWAS loci by performing RNA-sequencing and expression quantitative trait locus analyses in 101 left atrial samples, the most relevant tissue for AF. We also performed transcriptome-wide analyses that identified 57 AF-associated genes, 42 of which overlap with GWAS loci. The identified loci implicate genes enriched within cardiac developmental, electrophysiological, contractile and structural pathways. These results extend our understanding of the biological pathways underlying AF and may facilitate the development of therapeutics for AF

Multi-ancestry GWAS of the electrocardiographic PR interval identifies 202 loci underlying cardiac conduction

The electrocardiographic PR interval reflects atrioventricular conduction, and is associated with conduction abnormalities, pacemaker implantation, atrial fibrillation (AF), and cardiovascular mortality. Here we report a multi-ancestry (N=293,051) genome-wide association meta-analysis for the PR interval, discovering 202 loci of which 141 have not previously been reported. Variants at identified loci increase the percentage of heritability explained, from 33.5% to 62.6%. We observe enrichment for cardiac muscle developmental/contractile and cytoskeletal genes, highlighting key regulation processes for atrioventricular conduction. Additionally, 8 loci not previously reported harbor genes underlying inherited arrhythmic syndromes and/or cardiomyopathies suggesting a role for these genes in cardiovascular pathology in the general population. We show that polygenic predisposition to PR interval duration is an endophenotype for cardiovascular disease, including distal conduction disease, AF, and atrioventricular pre-excitation. These findings advance our understanding of the polygenic basis of cardiac conduction, and the genetic relationship between PR interval duration and cardiovascular disease. On the electrocardiogram, the PR interval reflects conduction from the atria to ventricles and also serves as risk indicator of cardiovascular morbidity and mortality. Here, the authors perform genome-wide meta-analyses for PR interval in multiple ancestries and identify 141 previously unreported genetic loci.Peer reviewe