Modelling glycocluster effects using artificial lipid rafts

Noble, Gavin Thomas

January 2012

The interaction of carbohydrates with carbohydrate-binding proteins is key to a multitude of important biological events, such as cell-cell interactions and signal transduction. Carbohydrates are also essential for energy storage and transfer. Binding to the three-dimensional display of carbohydrates at the cell surface (the glycocalyx) is known to play a role in many disease states, such as carbohydrate binding by viruses. Furthermore, changes in the distribution and type of oligosaccharides is known to occur at tumour cell surfaces. The importance of these natural events at the cell membrane surface provided the motivation for their study in a biomimetic environment. Inspired by previous work in the field of carbohydrate-lectin binding and work in the Webb group into mimicry of cellular processes using supramolecular chemistry, vesicular structures of synthetic glycolipids in natural phospholipids were created. Several synthetic glycolipids were synthesised and found to be capable of lateral phase separation in ordered-phase phospholipid bilayers, forming artificial lipid rafts in the bilayer. The glycolipid vesicle systems were used to study the effects of the lateral clustering of glycolipids on two different biochemical events at the membrane surface: Binding of mannosyl-lipids by concanavalin A (ConA) and the enzymatic galactosylation of N-acetylglucosamine (GlcNAc)-lipids by bovine β-(1,4)-galactosyltransferase (β4GalT1). Fluorescence quenching titrations revealed that clustering of mannosyl-lipids had little effect on the strength of ConA binding. However, HPLC measurements showed that lateral clustering of GlcNAc-lipids could enhance their enzymatic galactosylation by β4GalT1. The work presented in this thesis represents the formulation of these vesicle systems and their study with ConA and β4GalT1. Further investigation with other phase-separating glycolipid-lectin/enzyme pairs is necessary to establish whether the effects of clustering observed herein are exclusive to ConA and β4GalT1, or are general phenomena observed at the membrane surface.

572.56

Glycocluster ; Lipid raft

Membrane Dynamics During Cytokinesis

Gudejko, Heather F.M.

January 2013

Thesis advisor: David R. Burgess / Cytokinesis is the final step in cell division, culminating in the formation of two daughter cells from a single mother cell. Previous studies from our lab have shown that lipid rafts are dynamic during cytokinesis in sea urchin embryos, migrating into the ingressing cleavage furrow then moving back outwards towards the poles prior to abscission. Here, I quantitated the mobility of GM1, a ganglioside enriched in lipid rafts, using cholera toxin subunit B (CTB). Despite previous observations of raft movement during cell division, I have found lipid rafts to be immobile throughout the cell cycle. Lipid raft stability is dependent on the activity of myosin light chain kinase (MLCK), most likely due to the dramatic reorganization of actin filaments upon MLCK inhibition. While further investigating the immobility of lipid rafts during cytokinesis using confocal microscopy, I have found that new membrane is added to the cell poles during anaphase, causing the plasma membrane to expand coincident with the constriction of the contractile ring. This membrane addition is dependent on actin and astral microtubules and occurs significantly earlier during mitosis than membrane addition at the furrow. The membrane that is added at the polar regions is compositionally distinct from the original cell membrane in that it is devoid of GM1, a component of lipid rafts. I also found that Rab11 vesicles are trafficked to the polar plasma membrane during the time of this new membrane event, suggesting that the growth of the plasma membrane at the cell poles during cell division is not due to stretching as previously thought, but due to the addition of new membrane through exocytosis. / Thesis (PhD) — Boston College, 2013. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

cytokinesis

lipid raft

membrane addition

membrane trafficking

Intracellular trafficking and plasma membrane microdomain distribution of the NSP4 enterotoxin during rotavirus infection in epithelial cells

Storey, Stephen Michael

15 May 2009

Rotavirus (RV) nonstructural protein 4 (NSP4) is a multifunctional glycoprotein that induces secretory diarrhea in mouse pups in the absence of other viral proteins. The intracellular transport route(s) and functional mechanism(s) of NSP4 are poorly understood; however, the recent association of the enterotoxin with cellular caveolin-1 may provide a link between NSP4 transport and function. To determine if NSP4 traffics to a specific subset of lipid rafts at the plasma membrane (PM), we isolated caveolae from a PM-enriched fraction with a new method that yielded endoplasmic reticulum (ER)-free caveolae membranes with a unique membrane structure and composition. Comparison of these caveolae with other detergent- and non-detergent-extracted membranes revealed that each caveolae/raft fraction contained caveolae markers; however, only our PM caveolae fraction mimicked the membrane structure and sterol exchange dynamics of intact PM without ER or non-raft PM contaminants. When these PM caveolae were isolated from RV-infected cells, full-length, high-mannose glycosylated NSP4 was present. Confocal imaging showed association of NSP4 with caveolin-1 moving from perinuclear and cytoplasmic sites toward the PM as the infection progressed. Fluorescent imaging also indicated exposure of the NSP4 Cterminus at the exofacial PM surface without transport of the enterotoxin through the Golgi apparatus. Surface-specific biotinylation was used to confirm NSP4 exposure at the surface of infected MDCK cells and to determine that the exposed protein was fulllength and high-mannose glycosylated. This study presents an ER contaminant-free PM caveolae isolation methodology, identifies the presence of full-length, high-mannose glycosylated NSP4 in both PM caveolae and exposed at the cell surface, and confirms the Golgi-bypassing nature of NSP4 ER to PM transport in RV-infected MDCK cells.

caveolae isolation

NSP4

rotavirus

lipid raft

Investigations in Immunology: TACI Localization in B Cells

Sanborn, Keri

January 2006

Thesis advisor: Thomas C. Chiles / For ten weeks during the summer of 2005, I was a Summer Undergraduate Research Fellow in an immunology laboratory at the Mayo Clinic. My research focused on the BLyS/APRIL system and the receptor TACI on the surface of B cells. Going into my summer research, I had very little experience in immunology. Throughout the process of writing this thesis, I have sought to improve upon my knowledge of immunology, building a cohesive story that begins with basic biology and ends with the results of the summer's experiments. The first part of this thesis covers topics in general immunology, and narrow down in focus to cover the function and development of lymphocytes and B cell maturation and activation. In the second part of the thesis, the background for my research is described in more detail, and topics such as autoimmunity and cancer, lipid rafts, cell polarization, the BLyS/APRIL system for B cell survival, and TACI are covered extensively. The final portion of this thesis discusses the experimental logic, a background on materials and methods, and the results of the experiments I conducted over the summer. By reading this thesis, anyone with a background in biology should become familiar with basic subjects in immunology, advanced concepts in the study of lymphocytes, the ligands BLyS and APRIL, and the receptor TACI in B cells. / Thesis (BS) — Boston College, 2006. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: College Honors Program.

Health Sciences, Immunology

Immunology

B Cell

TACI

TNF

Lipid Raft

Pattern Formation in Membranes with Quenched Disorder

Sadeghi, Sina

17 November 2014

No description available.

530

Physik (PPN621336750)

bilayer membrane

lipid raft

membrane curvature

Modulation of glucocorticoid action in vivo : role of lipid rafts and clocks

Caratti, Giorgio

January 2017

Glucocorticoids (Gcs) are a commonly used drug to target the glucocorticoid receptor (GR). The GR has a myriad of cellular and physiological effects, however, Gcs are clinically used for the treatment of inflammatory conditions due to the potent anti-inflammatory actions of GR. The anti-inflammatory effects come with serious side effects e.g. metabolic disease. I examine the role of lipid rafts in modulating the anti-inflammatory actions of Gcs, and the role of circadian rhythms in the control of Gc side effects. I tested the role of caveolin-1 (Cav1), a constituent of membrane lipid rafts, and its role in Gc suppression of inflammation. Gene expression analysis of mouse lung tissue showed that genetic depletion of Cav1 (CAV1KO) results in increased transactivation of Gc target genes. The increased Gc action, however, does not result in an increased effect on suppression of inflammation in a model of innate immunity: aerosolised lipopolysaccharide (LPS) induced lung inflammation or in a model of adaptive immunity: Ovalbumin. CAV1KO mice were protected from LPS induced inflammation, despite increased cytokine production. This suggests a differential response to LPS in lung parenchyma and alveolar macrophages dependent on Cav1. CAV1KO results in a pro-inflammatory phenotype in macrophages, and the opposite in parenchymal tissue. These data suggest that while Cav1 is an upstream regulator of Gc response, it does not have a strong enough effect to alter the ability of GR to repress inflammation in vivo. Gc treatment results in a strong metabolic phenotype, with aberrant energy metabolism, insulin resistance and hepatosteaotosis, I investigated how this side effect interacts with circadian rhythms, another key determinant of energy metabolism. Using transcriptomics of whole lung and liver taken during the day or the night, I demonstrate that the metabolic actions of Gc in the liver can be temporally separated, whilst maintaining consistent anti-inflammatory actions in both liver and lung. This temporal gene regulation by Gc is controlled by REV-ERB, a rhythmically expressed, orphan nuclear receptor, part of the core clock machinery, via a direct interaction with GR at key regulatory DNA loci. Genetic deletion of REV-ERB protects mice from the hepatosteotosis associated with Gc treatment. Taken together, these data suggest that Gcs are regulated upstream of the receptor by the core consitutent of membrane lipid rafts; Cav1, which modulates the Gc response in vivo. Also, that the GR action can be controlled by dosing at different times of day, separating the detrimental metabolic effects of Gcs from the beneficial anti-inflammatory effects. This is enabled through a direct interaction between GR and REV-ERB at key gene regulatory sites.

612.4

Super-Resolution Microscopy of Sphingolipids and Protein Nanodomains / Hochaufgelöste Mikroskopie von Sphingolipiden und Protein Nanodomänen

Schlegel, Jan

January 2021

The development of cellular life on earth is coupled to the formation of lipid-based biological membranes. Although many tools to analyze their biophysical properties already exist, their variety and number is still relatively small compared to the field of protein studies. One reason for this, is their small size and complex assembly into an asymmetric tightly packed lipid bilayer showing characteristics of a two-dimensional heterogenous fluid. Since membranes are capable to form dynamic, nanoscopic domains, enriched in sphingolipids and cholesterol, their detailed investigation is limited to techniques which access information below the diffraction limit of light. In this work, I aimed to extend, optimize and compare three different labeling approaches for sphingolipids and their subsequent analysis by the single-molecule localization microscopy (SMLM) technique direct stochastic optical reconstruction microscopy (dSTORM). First, I applied classical immunofluorescence by immunoglobulin G (IgG) antibody labeling to detect and quantify sphingolipid nanodomains in the plasma membrane of eukaryotic cells. I was able to identify and characterize ceramide-rich platforms (CRPs) with a size of ~ 75nm on the basal and apical membrane of different cell lines. Next, I used click-chemistry to characterize sphingolipid analogs in living and fixed cells. By using a combination of fluorescence microscopy and anisotropy experiments, I analyzed their accessibility and configuration in the plasma membrane, respectively. Azide-modified, short fatty acid side chains, were accessible to membrane impermeable dyes and localized outside the hydrophobic membrane core. In contrast, azide moieties at the end of longer fatty acid side chains were less accessible and conjugated dyes localized deeper within the plasma membrane. By introducing photo-crosslinkable diazirine groups or chemically addressable amine groups, I developed methods to improve their immobilization required for dSTORM. Finally, I harnessed the specific binding characteristics of non-toxic shiga toxin B subunits (STxBs) and cholera toxin B subunits (CTxBs) to label and quantify glycosphingolipid nanodomains in the context of Neisseria meningitidis infection. Under pyhsiological conditions, these glycosphingolipids were distributed homogenously in the plasma membrane but upon bacterial infection CTxB detectable gangliosides accumulated around invasive Neisseria meningitidis. I was able to highlight the importance of cell cycle dependent glycosphingolipid expression for the invasion process. Blocking membrane accessible sugar headgroups by pretreatment with CTxB significantly reduced the number of invasive bacteria which confirmed the importance of gangliosides for bacterial uptake into cells. Based on my results, it can be concluded that labeling of sphingolipids should be carefully optimized depending on the research question and applied microscopy technique. In particular, I was able to develop new tools and protocols which enable the characterization of sphingolipid nanodomains by dSTORM for all three labeling approaches. / Die Entwicklung von zellulären Lebensformen auf der Erde basiert auf der Entstehung biologischer Lipid-Membranen. Obwohl viele Techniken zur Verfügung stehen, welche es erlauben deren biophysikalische Eigenschaften zu untersuchen, sind die Möglichkeiten, verglichen mit der Analyse von Proteinen, eher eingeschränkt. Ein Grund hierfür, ist die geringe Größe von Lipiden und deren komplexe Zusammenlagerung in eine asymmetrische dicht gepackte Lipiddoppelschicht, welche sich wie eine heterogene zweidimensionale Flüssigkeit verhält. Durch die lokale Anreicherung von Sphingolipiden und Cholesterol sind Membranen in der Lage dynamische, nanoskopische Domänen auszubilden, welche lediglich mit Techniken, welche die optische Auflösungsgrenze umgehen, detailliert untersucht werden können. Ein wesentliches Ziel meiner Arbeit war es, drei Färbeverfahren für Sphingolipide zu vergleichen, erweitern und optimieren, um eine anschliessende Untersuchung mit Hilfe der einzelmolekülsensitiven Technik dSTORM (direct stochastic optical reconstruction microscopy) zu ermöglichen. Zunächst verwendete ich das klassische Färbeverfahren der Immunfluoreszenz, um Sphingolipid-Nanodomänen auf eukaryotischen Zellen mit Hilfe von Farbstoff-gekoppelten Antikörpern zu detektieren und quantifizieren. Dieses Vorgehen ermöglichte es mir, Ceramid-angereicherte Plattformen mit einer Größe von ~ 75nm auf der basalen und apikalen Membran verschiedener Zell-Linien zu identifizieren und charakterisieren. Als nächstes Verfahren verwendete ich die Klick-Chemie, um Sphingolipid-Analoge in lebenden und fixierten Zellen zu untersuchen. Eine Kombination aus Fluoreszenz-Mikroskopie und Anisotropie-Messungen erlaubte es mir Rückschlüsse über deren Zugänglichkeit und Konfiguration innerhalb der Plasmamembran zu ziehen. Hierbei lokalisierten Azid-Gruppen am Ende kurzkettiger Fettsäurereste außerhalb des hydrophoben Membrankerns, wodurch sie mittels membran-undurchlässige Farbstoffe angeklickt werden konnten. Im Gegensatz dazu, waren Azide an längeren Fettsäureresten weniger zugänglich und konjugierte Farbstoffe tauchten tiefer in die Plasmamembran ein. Durch die Einführung photoreaktiver Diazirin-Gruppen oder chemisch modifzierbarer Amin-Gruppen wurden Wege geschaffen, welche eine Immobilisierung und anschließende Analyse mit Hilfe von dSTORM ermöglichen. Schließlich nutzte ich das spezifische Bindeverhalten der nicht toxischen B Untereinheiten von Shiga- (STxB) und Cholera-Toxin (CTxB) aus, um Glycosphingolipid Nanodomänen im Kontext einer Neisseria meningitidis Infektion zu untersuchen. Unter physiologischen Bedingungen waren diese homogen in der Plasmamembran verteilt, jedoch reicherten sich CTxB-detektierbare Ganglioside um eindringende Bakterien an. Darüber hinaus konnte ich einen Zusammenhang zwischen der zellzyklusabhängigen Expression von Glycosphingolipiden und dem Eindringen der Bakterien herstellen. Eine Absättigung der Zucker an der äußeren Membran durch CTxB-Vorbehandlung reduzierte die Anzahl von invasiven Bakterien signifikant und bestätigte die Schlüsselrolle von Gangliosiden bei der Aufnahme von Bakterien. Meine Ergebnisse legen Nahe, dass das Färbeverfahren für Sphingolipide an die jeweilige Fragestellung und Mikroskopietechnik angepasst werden sollte. Im Rahmen dieser Arbeit konnten neue Werkzeuge und Protokolle geschaffen werden, die die Charakterisierung von Sphingolipid-Nanodomänen mittels dSTORM für alle drei Färbeverfahren ermöglichen.

Sphingolipide

Lipide

Einzelmolekülmikroskopie

Click-Chemie

Lipid Raft

ddc:570

Efeito dos ácidos graxos sobre a via de sinalização da interleucina-2 em linfócitos humanos. / Regulation of IL-2 signaling by fatty acids in human lymphocytes.

Gorjão, Renata

19 May 2008

Neste estudo investigamos os efeitos dos ácidos graxos sobre a função e sinalização intracelular de linfócitos humanos. Os ácidos oléico (OA) e linoléico (LA), em baixas concentrações, estimularam a proliferação celular induzida pela IL-2 através do aumento da fosforilação da proteína PKC-<font face=\"symbol\">Z que levou a um aumento da fosforilação de ERK 1/2. Já os ácidos palmítico (PA), esteárico (SA), DHA e EPA diminuíram a proliferação destas células e inibiram a fosforilação de JAK1 e 3, STAT5, ERK e Akt. Os resultados obtidos são sugestivos de que o efeito inibitório promovido por PA, SA, DHA e EPA sobre a proliferação de linfócitos ocorreu devido à diminuição da fosforilação de proteínas fundamentais para a proliferação celular. Por outro lado, OA e LA estimularam a proliferação de linfócitos aumentando a fosforilação de ERK 1/2 através da ativação de PKC-<font face=\"symbol\">Z, efeito dependente da PI3K. O efeito inibitório promovido pelo DHA está associado a uma alteração na quantidade de lipid rafts na membrana plasmática nos quais o receptor de IL-2 está localizado. / The effect of fatty acids (FA) on interleukin -2 (IL-2) signaling pathway in human lymphocytes was investigated. Docosahexaenoic (DHA), eicosapentaenoic (EPA), palmitic (PA) and stearic (SA) acids decreased lymphocyte proliferation in concentrations above 50 <font face=\"symbol\">mM. However, oleic (OA) and linoleic (LA) acids increase lymphocyte proliferation at 25 <font face=\"symbol\">mM. PA, SA, DHA and EPA decreased JAK 1, JAK 3, STAT 5 and AKT phosphorylation induced by IL-2 but OA and LA did not cause any effect. OA and LA increased ERK1/2 phosphorylation whereas the other FA caused a marked decrease. PKC-<font face=\"symbol\">Z phosphorylation was decreased by OA and LA only. In conclusion, the inhibitory effect of PA, SA, DHA and EPA on lymphocyte proliferation observed in our previous study was due to a decrease in protein phosphorylation activated by IL-2. Probably, OA and LA stimulated lymphocyte proliferation by increasing ERK 1/2 phosphorylation throught PKC-<font face=\"symbol\">Z activation. The inhibition of JAK 1, JAK3, STAT 5, ERK1/2 and Akt phosphorylation caused by DHA is associated to a decrease in membrane lipid rafts contend.

Ácidos graxos

Fatty acids

Interleucina 2

Interleukin 2

Intracellular signaling

Linfócitos

Lipid RAFT

Lipid RAFT

Lymphocytes

Proliferação

Proliferation

Sinalização intracelular

Efeito dos ácidos graxos sobre a via de sinalização da interleucina-2 em linfócitos humanos. / Regulation of IL-2 signaling by fatty acids in human lymphocytes.

Renata Gorjão

19 May 2008

Neste estudo investigamos os efeitos dos ácidos graxos sobre a função e sinalização intracelular de linfócitos humanos. Os ácidos oléico (OA) e linoléico (LA), em baixas concentrações, estimularam a proliferação celular induzida pela IL-2 através do aumento da fosforilação da proteína PKC-<font face=\"symbol\">Z que levou a um aumento da fosforilação de ERK 1/2. Já os ácidos palmítico (PA), esteárico (SA), DHA e EPA diminuíram a proliferação destas células e inibiram a fosforilação de JAK1 e 3, STAT5, ERK e Akt. Os resultados obtidos são sugestivos de que o efeito inibitório promovido por PA, SA, DHA e EPA sobre a proliferação de linfócitos ocorreu devido à diminuição da fosforilação de proteínas fundamentais para a proliferação celular. Por outro lado, OA e LA estimularam a proliferação de linfócitos aumentando a fosforilação de ERK 1/2 através da ativação de PKC-<font face=\"symbol\">Z, efeito dependente da PI3K. O efeito inibitório promovido pelo DHA está associado a uma alteração na quantidade de lipid rafts na membrana plasmática nos quais o receptor de IL-2 está localizado. / The effect of fatty acids (FA) on interleukin -2 (IL-2) signaling pathway in human lymphocytes was investigated. Docosahexaenoic (DHA), eicosapentaenoic (EPA), palmitic (PA) and stearic (SA) acids decreased lymphocyte proliferation in concentrations above 50 <font face=\"symbol\">mM. However, oleic (OA) and linoleic (LA) acids increase lymphocyte proliferation at 25 <font face=\"symbol\">mM. PA, SA, DHA and EPA decreased JAK 1, JAK 3, STAT 5 and AKT phosphorylation induced by IL-2 but OA and LA did not cause any effect. OA and LA increased ERK1/2 phosphorylation whereas the other FA caused a marked decrease. PKC-<font face=\"symbol\">Z phosphorylation was decreased by OA and LA only. In conclusion, the inhibitory effect of PA, SA, DHA and EPA on lymphocyte proliferation observed in our previous study was due to a decrease in protein phosphorylation activated by IL-2. Probably, OA and LA stimulated lymphocyte proliferation by increasing ERK 1/2 phosphorylation throught PKC-<font face=\"symbol\">Z activation. The inhibition of JAK 1, JAK3, STAT 5, ERK1/2 and Akt phosphorylation caused by DHA is associated to a decrease in membrane lipid rafts contend.

Ácidos graxos

Interleucina 2

Linfócitos

Lipid RAFT

Proliferação

Sinalização intracelular

Fatty acids

Interleukin 2

Intracellular signaling

Lipid RAFT

Lymphocytes

Proliferation

Estudio funcional y molecular del canal Maxi-Cl activado por antiestrógenos

Bahamonde Santos, María Isabel

27 February 2004

Las membranas celulares contienen un canal de Cl- (Maxi-Cl-) que es modulado por estrógenos y antiestrógenos. El trabajo experimental de mi tesis doctoral ha consistido en el estudio de la modulación de este canal y su identidad molecular. El resultado de mi trabajo ha demostrado que la base molecular del canal Maxi-Cl- es una isoforma de la proteína mitocondrial VDAC y que la activación del canal por los antiestrógenos y su inhibición por los estrógenos implica procesos de defosforilación y fosforilación, respectivamente. / Cellular membranes contain a Maxi-Cl- channel that is modulated by oestrogen and antioestrogens. The experimental work of my PhD Thesis has focussed in the study of the molecular identity of the Maxi-Cl- channel and its regulation. My results demonstrated that an isoform of the mitochondrial protein VDAC is the molecular correlate of the Maxi-Cl- channel and that the activation of the channel by antioestrogens and its inhibition by oestrogen requires a dephosphorylation and phosphorylation process, respectively.

neuroblastos

fibroblastos

toremifeno

mitocondria

lipid raft

caveolin

Maxi-Cl- channel

fibroblast

mitochondria

caveolae

antioestrogen

neuroblastoma

toremifen

antiestrógeno

caveola

caveolina

lipid raft

VDAC

canal Maxi-Cl-

573