Interaction of polymeric particles with surfactant interfaces

Farnoud, Amir Mohammad

01 May 2013

Films of phospholipids and biologically relevant surfactants at the air-water interface provide a well-defined medium to study molecular alignment, phase behavior and interactions of biomembranes and lung surfactant with exogenous materials. Interactions between lung surfactant interfaces and solid particles are of particular interest due to the increased use of nanomaterials in industrial applications and the promise of polymeric particles in pulmonary drug delivery. Understanding such interactions is necessary to avoid potential adverse effects on surfactant function after exposure to particles. In this thesis, the mechanisms of surfactant inhibition after exposure to submicron particles via different routes were investigated. The effects of carboxyl-modified polystyrene particles (200 nm) on films of dipalmitoyl phosphatidylcholine (DPPC) and Infasurf (calf lung surfactant extract) were studied. Surfactants were exposed to different concentrations of particles in a Langmuir trough with symmetric surface compression and expansion. Surface tension, potential, microstructure and topology were examined to monitor particle effects on surfactant function. Several methods of surfactant exposure to particles were studied: particle injection into the subphase after spreading surfactant monolayers (subphase injection), mixing the particles with the subphase and spreading the surfactant on top (monolayer addition) and particle aerosolization onto surfactant films. Studies with DPPC monolayers revealed that particle-surfactant interactions are dependent on the particle introduction method. In the subphase injection method, particles did not penetrate the monolayer and no inhibitory effects on surfactant function were observed. However, in the monolayer addition method, particles caused a premature monolayer collapse and hindered surfactant respreading likely by penetrating into the DPPC monolayer. Finally, particle aerosolization on surfactant was performed to mimic the physiologically relevant route of surfactant exposure to particles. Particle aerosolization on DPPC monolayers significantly inhibited surfactant function in the lung-relevant surface tension range. When aerosolized on Infasurf, particles caused inhibitory effects as a function of time suggesting adsorption of surfactant components on particle surfaces as the main mechanism of interaction. This research will enhance understanding of the mechanisms of particle-induced surfactant dysfunction, thereby providing information for the safe design of polymeric particles for drug delivery and for developing guidelines for particles used in occupational settings.

Air-Water Interface

Langmuir Monolayer

Lipid Domain

Particle

Surface Tension

Surfactant

Chemical Engineering

Modulatory effect of lipid compositions on phospholipase A2 activity

Chiou, Yi-ling

17 July 2012

The goal of the present study is to elucidate the modulatory effect of lipid compositions on phospholipase A2 (PLA2) activity. Sphingomyelin (SM) incorporation inhibited catalytic activity and membrane-damaging activity of native and mutated PLA2 toward egg yolk phosphatidylcholine (EYPC) vesicles. The inhibitory effects were through the reduction of membrane fluidity and modulation of the mode of membrane binding of PLA2 at water/lipid interface. The modulated effect of SM depended on inherent structural elements of PLA2. Moreover, cholesterol (Chol) incorporation into EYPC/egg yolk sphingomyelin (EYSM) vesicles relieved the inhibitory effect of sphingomyelin on PLA2 activity via lipid domain formation by SM and Chol. The effects on the interactive mode of PLA2 with phospholipids induced by the physical state changes of membrane bilayers abolished the inhibition of SM on catalytic activity and membrane-damaging activity of PLA2. Additionally, quercetin incorporation increased PLA2 activity and membrane-damaging activity toward EYPC/SM vesicles via its raft-making effect. Quercetin incorporation reduced PLA2 activity and membrane-damaging activity toward EYPC/SM/Chol vesicles via its raft-breaking effect. Membrane-inserted quercetin affected on membrane structure and membrane-bound mode of PLA2 to modulate PLA2 interfacial activity and membrane-damaging activity. Finally, studies on the effects of phosphatidylserine (PS) content on the sensitivity of lipid vesicles mimicking inner and outer plasma membrane toward PLA2 activity revealed that the membrane-binding mode adopted by PLA2 depended on the lipid composition. The effects of PS content on the extent of lipid domain formation and the conformation of PLA2 adopted at water-lipid interface modulate PLA2 catalytic activity. Collectively, these results indicate that lipid composition modulates PLA2 activity via its effects on membrane structure and membrane-bound mode of PLA2

phospholipase A2

lipid domain/lipid raft formation

N-terminal region

lipid composition

interfacial activation

quercetin

Giant vesicles

Stöckl, Martin Thomas

14 January 2009

In der vorliegenden Arbeit wird ein neuer Ansatz vorgestellt, um Lipiddomänen, die Bindungsorte peripherer und integraler Membranproteine darstellen können, zu charakterisieren. Insbesondere wurde die Analyse der Fluoreszenzlebenszeiten von NBD-markierten Lipidanaloga benutzt, um Lipiddomänen in Giant unilamellar vesicles (GUV) und darauf aufbauend, in der Plasmamembran von Säugerzellen zu untersuchen. Das typische Zeitfenster von Fluoreszenzlebenszeiten im Bereich von Nanosekunden ermöglicht es, auch sehr kurzlebige Lipiddomänen nachzuweisen. Mit Hilfe des Fluorescence lifetime imaging (FLIM) wurden für die liquid disordered (ld) und liquid ordered (lo) Domänen in GUV jeweils spezifische Werte für das Abklingen der Fluoreszenz gemessen. Sogar die Existenz von submikroskopischen Domänen in GUV konnte nachgewiesen werden. Die Fluoreszenzlebenszeit des Lipidanalogs C6-NBD-PC zeigte in der Plasmamembran von Säugerzellen eine breite Verteilung. Dies legt in Übereinstimmung mit FLIM-Experimenten an aus der Plasmamembran von HeLa-Zellen gewonnenen Giant vesicles nahe, dass in der Plasmamembran von Zellen eine Vielzahl verschiedener submikroskopischer Lipiddomänen existiert. Darauf aufbauend wurde die Fluoreszenzmikroskopie an GUV angewendet, um die Bindung von fluoreszenzmarkiertem alpha-Synuclein an mittels FLIM charakterisierte Lipiddomänen zu untersuchen. Die Experimente zeigten, dass das Protein mit hoher Affinität an negativ geladene Phospholipide unter der Vorraussetzung bindet, dass diese sich in ld Domänen befinden. Im Gegensatz dazu erfolgt keine Bindung wenn diese Lipide in lo Domänen lokalisiert sind. Im Vergleich zum wildtypischen alpha-Synuclein zeigte die Variante A30P eine geringere Affinität zur Membran, während die E46K-Variante eine stärkere Bindung zeigte. Dies deutet darauf hin, dass bei den erblichen Formen des Morbus Parkinson eine veränderte Assoziation des alpha-Synucleins mit der Membran eine Rolle spielen kann. / In the present study a novel approach to characterize lipid domains, which may provide binding sites for peripheral or integral membrane proteins, is demonstrated. In particular, analysis of fluorescence lifetimes of NBD-labeled lipid analogues was used to study lipid domains in Giant unilamellar vesicles (GUV) and – based on the GUV results – in the plasma membrane of mammalian cells. As fluorescence decays in a few nanoseconds it is possible to to detect also very short-lived lipid domains. Fluorescence Lifetime Imaging (FLIM) revealed that the fluorescence decay of NBD-lipid analogues showed domain dependent decay times in the liquid disordered (ld) and the liquid ordered (lo) phase of GUV. Even the existence of submicroscopic domains in lipid membranes could be detected by FLIM. A broad distribution of the fluorescence lifetime was found for C6-NBD-PC inserted in the plasma membrane of mammalian cells. In agreement with FLIM studies on lipid domain forming Giant vesicles derived from the plasma membrane of HeLa-cells this may suggest that a variety of submicroscopic lipid domains exists in the plasma membrane of intact mammalian cells. Based on that, fluorescence microscopy was used on GUV to study the binding of fluorescently labeled alpha-synuclein at lipid domains previously characterized by FLIM. The experiments suggested that alpha-synuclein binds with high affinity to negatively charged phospholipids, when they are embedded in a ld as opposed to a lo environment. When compared with wildtype alpha-synuclein, the disease-causing alpha-synuclein variant A30P bound less efficiently to anionic phospholipids, while the variant E46K showed enhanced binding. This suggests that an altered association of alpha-synuclein with membranes may play a role in the inherited forms of Parkinson’s disease.

Mikroskopie

Membran

GUV

FLIM

Lipiddomänen

Synuclein

microscopy

Giant unilamellar vesicles

fluorescence lifetime imaging

lipid domain

membrane

synuclein

570 Biowissenschaften, Biologie

32 Biologie

WD 5400

ddc:570

Influence of ABCA1 and ABCA7 on the lipid microenvironment of the plasma membrane

Plazzo, Anna Pia

02 July 2009

Der ABC-Transporter ABCA1 ist unmittelbar in die zelluläre Lipidhomeostasie einbezogen, in dem er die Freisetzung von Cholesterol an plasmatische Rezeptoren, wie ApoA-I, vermittelt. Trotz intensiver Untersuchungen ist dieser molekulare Mechanismus nicht verstanden. Verschiedene Studien deuten daraufhin, dass durch die Aktivität von ABCA1 bedingte Veränderungen in der Lipidphase der äußeren Hälfte der Plasmamembran (PM) wichtig für die Freisetzung des Cholesterols sind. In der vorliegenden Arbeit wird die Lipidumgebung von ABCA1 in der PM lebender Säugetierzellen unter Anwendung der Fluoreszenzlebenszeitmikroskopie von fluoreszierenden Lipidsonden untersucht. Es wurde eine breite Verteilung der Fluoreszenzlebenszeiten der Sonden gefunden, die sensitiv gegenüber Veränderungen der lateralen und transversalen Organisation der Lipide ist. Im Einklang mit Studien an riesengroßen unilamellaren Vesikeln und Plasmamembranvesikeln weisen unsere Ergebnisse die Existenz einer größeren Vielfalt submikroskopischer Lipiddomänen auf. Die FLIM-Untersuchungen an ABCA1 exprimierenden HeLa-Zellen weisen eine die Lipidphase destabilisierende Funktion des Transportes aus. Dieses wurde unterstützt durch die Lipidanalyse von Fraktionen der PM. Auf der Basis unserer Untersuchungen und früheren Daten stellen wir die Hypothese auf, dass die Exponierung von Phosphatidylserin (PS) auf der Zelloberfläche ein zentrales Ereignis der ABCA1 bedingten Veränderungen ist. Allerdings zeigen vergleichende Studien an ABCA7 exprimierenden Zellen, dass dies nicht ausreicht, um die ABCA1 verursachten Veränderungen in der Lipidpackung der PM zu erklären. Unsere Ergebnisse beweisen, dass die Fähigkeit von ABCA1, den Cholesterolefflux zu vermitteln, auf durch den Transporter bedingte Veränderungen in der LP der PM zurückzuführen sind, die unabhängig von der Bindung von ApoA-1 sind und dieser vorausgehen. Diese Veränderungen sind notwendig für die Lipidierung von ApoA-1 und der Generierung von HDL-Partikeln. / The ABCA1 transporter organizes cellular lipid homeostasis by promoting the release of cholesterol to plasmatic acceptors such as ApoA-I. Despite intensive investigation, the molecular mechanism of such a process has not yet been clarified. In the present study we report on the analysis of the ABCA1 lipid microenvironment at the plasma membrane of living cells, by a novel approach based on fluorescence lifetime imaging microscopy (FLIM). In the plasma membrane of mammalian cells, a broad fluorescence lifetime distribution sensitive to treatments interfering with the membrane lateral and transbilayer organization was found. In agreement with investigations in giant unilamellar vesicles and giant plasma membrane vesicles, our results are consistent with the existence of a large variety of submicroscopic lipid domains. Based on that, FLIM in HeLa cells expressing ABCA1 revealed the destabilizing function of the transporter on the lipid arrangement at the membrane, indicating that lipid packing was a primary target of ABCA1 activity. This was corroborated by the analysis of plasma membrane fractions isolated by density fractionation. On the basis of our analysis and previous data, we speculate that the exposure of phosphatidylserine on the cell surface is a central event for ABCA1-dependent modifications. However, a comparative study of cells expressing ABCA7, the member of the ABCA subfamily with the highest homology to ABCA1, revealed that exposure of PS alone cannot account for the detected effects. Collectively, our data suggest that the ability of ABCA1 to promote cholesterol efflux is independent and precedes its actual binding to ApoA-I. Rather, ABCA1-induced plasma membrane modifications are necessary for the lipidation of ApoA-I and the generation of high density lipoprotein particles.

Cholesterol

Plasmamembran

FLIM

Lipiddomänen

ABCA1

cholesterol

plasma membrane

fluorescence lifetime imaging

lipid domain

ABCA1

570 Biowissenschaften, Biologie

32 Biologie

WE 5150

ddc:570