Protein-lipid interactions in raft-exhibiting membranes probed by combined AFM and FCS

Chiantia, Salvatore

22 May 2008

The cellular membrane is a complex biological entity, far from being an inert assembly of protein and lipids which separates cells from the surrounding environment. A multitude of biological processes, ranging from active transport of ions into and out of the cell, to the immune response, are regulated at the level of the plasma membrane. The understanding of their molecular basis is among the central goals of modern biological research. In order to dissect the complexity of actual cell membranes, which involves a very complex network of intermolecular interactions, a “divide and conquer” strategy proves very useful. To this end, researchers try to isolate molecules from complex biological contexts to understand their function in simple model systems under controlled conditions. A variety of model membranes have thus been developed in order to gain insight into membrane processes. This approach has resulted in a deeper knowledge on how lipids and proteins interact and how these interactions govern the function of cellular membranes. In the recent past in fact, a connection has been established between the lateral structure of the plasma membrane and its biological function. Furthermore, a large range of biophysical techniques have been used to characterize protein-lipid microdomains. For example, atomic force microscopy (AFM) is a powerful technique which allows a highly detailed topographical characterization of lipid domains in physiological conditions. While AFM imaging offers an extremely high spatial resolution, up to the nanometer scale, the limited image acquisition speed (minutes) can pose a severe drawback in adequately studying fast dynamic processes. On the other hand, fluorescence based imaging techniques are much faster (10-3-100 s), but certainly lack the high spatial resolution that AFM offers. FCS in particular can also provide information about dynamic processes, like diffusion of fluorescent membrane components. For these reasons, implementing a combination of the above mentioned techniques on the same sample (e.g. cell membrane models) would prove extremely beneficial in the complete dynamic and structural characterization of molecular interactions. . The work described in this thesis can be summarized in two main points: i) the development of a novel combined approach of atomic force microscopy (AFM), laser scanning imaging (LSM), and fluorescence correlation spectroscopy (FCS) and ii) the study of the effects of ceramide in the lateral organization of model plasma membranes. We described one of the first simultaneous applications of AFM and FCS on biologically relevant systems. More specifically, model membranes showing complex phase separation were investigated with a combined approach of AFM, confocal fluorescence imaging, force measurements and FCS, based on commercially available instruments. AFM conveys information about the structural and mechanical properties of the different lipid phases. Different membrane domains can be distinguished based on height difference, elastic properties and line tension as measured by the AFM tip. Simultaneous optical measurements offer the correlation of these data in real time with the partition behavior and diffusion of fluorescent lipids and proteins. We established a clear link between the local membrane viscosity, probed by FCS, and the lipid-lipid interactions involved in line tension, probed by AFM force measurements. An example of a significant drawback circumvented by the AFM-FCS approach involves the use of AFM micromanipulation to eliminate unwanted interactions between lipid particles — similar to intra-cellular vesicles found in vivo experiments — and the membrane, which usually result in distorted FCS autocorrelation curves. Finally, the combined application of AFM and FCS on membrane-anchored proteins reconstituted in lipid bilayers has been instrumental in clarifying inconsistencies that arose in work that focused solely on either AFM or fluorescence techniques. We have shown that, in the case of proteins diffusing in the plane of the membrane, AFM can unambiguously detect only a small immobile fraction. Furthermore, since AFM detection of proteins might be facilitated by high local membrane viscosity (e.g. in ordered lipid phases), the measurement of protein partition between disordered and ordered membrane domains might be biased toward the latter. In this case, the use of FCS as a complementary technique allows a more thorough investigation and deeper understanding of the system of interest. The second part of this thesis dealt with the study of complex lipid mixtures which are used to model the putative lipid/proteins domains in cells, called “rafts”. Firstly, we proved how the combined fluorescence imaging/AFM approach is useful in general for studying supported lipid membranes and the role of lipid domains in biological contexts. We investigated the effect of environmental stress on biological membranes and the protective effects of several substances. Our experimental approach was shown to be a new valuable method to visualize the dehydration damage and its effects on the lateral organization of lipid domains. Our results demonstrated that disaccharides like trehalose or sucrose are effective in protecting lipid membranes, not only on a macroscopic scale — preserving the overall integrity of the bilayer — but also on a microscopic scale, preventing the clustering of microdomains. These phenomena are interesting in the context of biological damage to living cells which need to be stored for long time, like organs to be transplanted or blood platelets. Finally, a large section of this thesis focused on the effects of a specific lipid called “ceramide” on the lateral organization of proteins and lipids in the plasma membrane. Ceramide is produced by cells in several situations, like bacterial infections or apoptosis. As consequence of ceramide production in vivo, the local concentration and the dynamic behavior of lipids and membrane receptors are supposed to exhibit strong variations. In order to understand the molecular mechanisms responsible for these effects, we applied a combination of AFM, FCS and fluorescence imaging on simple model membranes containing ceramide. We could show for the first time that, in presence of raft-like Lo/Ld phase separation, physiological quantities of ceramide induced the formation of a highly ordered gel phase, constituted of ceramide and sphingomyelin. The enzymatic production of ceramide was monitored both in supported and in free-standing bilayers. In the second case, ceramide production was connected to selective vesicle budding from the raft-like phase. Since short-chain analogues are often used in both medical applications and biochemical research to mimic the effect of long-chain ceramides, we investigated the effect of chain-length on ceramide-induced membrane reorganization. We could show that only long-chain ceramides (C18 and C16) form highly ordered domains. Interestingly, FCS measurements indicated that the physical properties of the Lo raft-like domains are hardly affected by the presence of ceramide domains. Furthermore, the increased thickness of the Ld phase — as measured by AFM — and its higher viscosity — as measured by FCS — strongly support the hypothesis of ceramide-induced cholesterol displacement from rafts. On the other hand, short-chain ceramides showed completely different biophysical properties that lead to a destabilization of the raft domains, possibly acting as surfactants between the different lipid phases. Our findings contribute to the explanation of in vivo experiments where short-chain ceramides inhibit cell signaling by disrupting the lipid order in the plasma membrane. We have so far demonstrated that ceramide plays a fundamental role in lipid-lipid interactions. In a physiological context, it is also known to produce dramatic effects in living cells. Since a majority of the processes in vivo are thought to be governed by the activity of proteins, it is highly likely that ceramide not only affects lipid organization but also modifies protein-protein and protein-lipid interactions to produce its effects. To test this hypothesis, we reconstituted several membrane proteins in lipid bilayers containing Ld, Lo, and ceramide-rich domains. We were able to show that some membrane proteins are sorted into ceramide-rich domains. More specifically, the raft-associated proteins we tested were enriched in the highly ordered ceramide-rich domains, while the Ld-associated components were excluded from them. Furthermore, the inclusion of any membrane component in ceramide-rich domains is directly connected to a dramatic reduction of its in-plane diffusion. In an in vivo context, such a reorganization of membrane receptors might be used by the cell to alter the signaling process, for example, by i) separating raft receptors from inhibitors with lower raft affinity, ii) bringing both raft-associated receptors and raft-associated signaling molecules into contact, or iii) stabilizing the interactions between a receptor and its ligand by decreasing their diffusion coefficients. In conclusion, this thesis describes a novel combination of AFM, LSM, and FCS for the investigation of the lateral organization of biological membranes. Our results show that this approach applied on model membranes of increasing complexity is an effective tool for understanding the molecular mechanisms behind the organization of biological membranes. This report opens up new possibilities for further investigation in living cell membranes using the same methodology we have described.

info:eu-repo/classification/ddc/530

ddc:530

AFM, FCS, membrane, lipid, rafts

AFM, FCS, Membranen, lipid, rafts

Estudo teórico de porfirinas, ftalocianinas e clorinas com ênfase para aplicação em terapia fotodinâmica

Bettanin, Fernanda

January 2015

Orientadora: Profa Dra Paula Homem de Melo / Tese (doutorado) - Universidade Federal do ABC. Programa de Pós-Graduação em Ciência e Tecnologia/Química, 2015. / In this work, it is shown the study of sensitizing molecules of phthalocyanines, porphyrins and chlorins families, with different ligands and ions complexed (Zn+2, Al+3 and Si+4), in order to assess, by computational methods, relevant properties for photodynamic therapy (PDT) application. In the first part of the work, was established an appropriate methodology to study all proposed molecules quickly and accurately. So it was chosen the Density Functional Theory and the best funcional-basis set combination found was B3LYP/LANL2DZ for optimization anf OLYP/6-31g(d) for excited states. The solvent effects were added by the solvation model IEFPCM, in order to represent the outside and inside of a lipid bilayer, respectively. In the second part of this work were obtained properties such as area, volume, dipole, frontier orbitals energy and electronic transitions of all molucules studied in order to compare them and define which complexed ions and ligands are able to modify these properties with focus on PDT. The third part studied dimers formation of some of these molecules, since this formation may affect the eletronic transitions, invalidating PDT. This study was performed with the DCACP¿s corrections applied to BLYP functional to simulate dispersion forces, responsible for the dimers formation. In the fourth part of this work, was simulated by molecular dynamics one phthalocyanine inserted into a lipid bilayer and, associated with quantum mechanics, it was possible to acess the electronic states of the molecule. These electronic states were compared with a second method for theating electronic states along a lipid bilayer with consists of a dielectric gradient that represents a membrane, in order to choose a more rapid and efficient method. The last part of this study used the same dielectric gradient to study the phosphorescence, along the lipid bilayer, showing that this method can be employed for this kind of property.

TERAPIA FOTODINÂMICA

DINÂMICA MOLECULAR

MEMBRANA DE BICAMADA LIPÍDICA

PHOTODYNAMIC THERAPY

MOLECULAR DYNAMICS

MEMBRANE LIPID BILAYER

γ-Tocotrienol Induces Apoptosis in Pancreatic Cancer Cells by Upregulation of Ceramide Synthesis and Modulation of Sphingolipid Transport

Palau, Victoria E., Chakraborty, Kanishka, Wann, Daniel, Lightner, Janet, Hilton, Keely, Brannon, Marianne, Stone, William, Krishnan, Koyamangalath

16 May 2018

Background: Ceramide synthesis and metabolism is a promising target in cancer drug development. γ-tocotrienol (GT3), a member of the vitamin E family, orchestrates multiple effects that ensure the induction of apoptosis in both, wild-type and RAS-mutated pancreatic cancer cells. Here, we investigated whether these effects involve changes in ceramide synthesis and transport. Methods: The effects of GT3 on the synthesis of ceramide via the de novo pathway, and the hydrolysis of sphingomyelin were analyzed by the expression levels of the enzymes serine palmitoyl transferase, ceramide synthase-6, and dihydroceramide desaturase, and acid sphingomyelinase in wild-type RAS BxPC3, and RAS-mutated MIA PaCa-2 and Panc 1 pancreatic cancer cells. Quantitative changes in ceramides, dihydroceramides, and sphingomyelin at the cell membrane were detected by LCMS. Modulation of ceramide transport by GT3 was studied by immunochemistry of CERT and ARV-1, and the subsequent effects at the cell membrane was analyzed via immunofluorescence of ceramide, caveolin, and DR5. Results: GT3 favors the upregulation of ceramide by stimulating synthesis at the ER and the plasma membrane. Additionally, the conversion of newly synthesized ceramide to sphingomyelin and glucosylceramide at the Golgi is prevented by the inhibition of CERT. Modulation ARV1 and previously observed inhibition of the HMG-CoA pathway, contribute to changes in membrane structure and signaling functions, allows the clustering of DR5, effectively initiating apoptosis. Conclusions: Our results suggest that GT3 targets ceramide synthesis and transport, and that the upregulation of ceramide and modulation of transporters CERT and ARV1 are important contributors to the apoptotic properties demonstrated by GT3 in pancreatic cancer cells.

ARV-1

ceramide distribution

ceramide synthesis

ceramide transport

CERT

free radicals

lipid transport

membrane lipid

pancreatic cancer

vitamin E

γ-Tocotrienol

Internal Medicine

Pediatrics

Pharmaceutical Sciences

Role of the regulation of cell lipid composition and membrane structure in the antitumor effect of 2-hydroxyoleic acid

Laura Martin, Maria

26 October 2011

El ácido 2-hidroxioleico (2OHOA) es un fármaco antitumoral diseñado para regular la estructura y composición de los lípidos de membrana y la función de importantes proteínas de membrana. El objetivo principal de este trabajo fue estudiar cómo el 2OHOA modula la composición lipídica y la estructura de membrana en las células tumorales. Se observó que el 2OHOA indujo profundas alteraciones en el contenido de fosfolípidos, aumentando el contenido de esfingomielina y disminuyendo el contenido de fosfatidiletanolamina y fosfatidilcolina. Este efecto fue específico contra las células cancerosas, ya que el tratamiento no afectó la composición lipídica de las células no tumorales MRC-5 de fibroblastos humanos. El aumento de SM se debió a una activación rápida y específica de las SM sintasas. Como consecuencia de la activación sostenida de la SMS, todo el metabolismo de los esfingolípidos se vio afectado. Finalmente, se evaluó el impacto de todos estos cambios sobre las propiedades biofísicas de membrana mediante espectroscopia de fluorescencia / 2-Hydroxyoleic acid (2OHOA) is a potent antitumor drug that was designed to regulate membrane lipid composition and structure and the function of important membrane proteins. The main goal of this work was to study how 2OHOA modulates the membrane lipid composition and structure of tumor cells. 2OHOA induced dramatic alterations in phospholipid content, increasing sphingomyelin mass, and decreasing phosphatidyl-ethanolamine and phosphatidylcholine. This effect was specific against cancer cells as it did not affect non-tumor MRC-5 cells. The increased SM mass was due to a rapid and highly specific activation of SM synthases. As a consequence of the sustained activation of SMS, the whole sphingolipid metabolism was affected. Then, the impact of all these changes on membrane biophysical properties was evaluated by fluorescence spectroscopy

Biologia celular, Oncologia molecular

57

576

The Two Faces of Janus: Unfolded Protein Response - Autophagy in Cell Death and Survival

Marcilla Etxenike, Amaia

30 November 2012

En esta tesis se estudian los efectos farmacológicos de derivados lipídicos frente el glioma y el Alzheimer. Los beneficios de este tipo de fármacos, basados en la terapia lipídica de membrana, están asociados con la modulación de la composición y las propiedades fisicoquímicas de membrana. En concreto, el ácido 2-hidroxioleico (2OHOA) es un potente fármaco antitumoral que fue diseñado para regular la composición y la estructura de la membrana lipídica así como la función de importantes proteínas de membrana. Por otro lado, el ácido 2-hidroxiaraquidónico (2OHARA), el ácido 2-hidroxieicosapentaenóico (2OHEPA), y el ácido 2-hidroxidocosahexanóico (2OHDHA) son derivados lipídicos hidroxilados que fueron diseñados en nuestro grupo de investigación para el tratamiento del Alzheimer. Este trabajo se ha basado en el estudio del funcionamiento de estos derivados de ácidos grasos hidroxilados en la modulación de las vías de señalización de la UPR (respuesta a las proteínas mal plegadas) y de la autofagia en células de glioma y células neuronales. / In this thesis, the pharmacological effects of lipid derivatives against glioma and Alzheimer's Disease are studied. The benefits of this type of drugs, which are based on the lipid membrane therapy, are associated with the modulation of the composition and physicochemical properties of membranes. 2-Hydroxyoleic acid (2OHOA) is a potent antitumor drug designed to regulate membrane lipid composition and structure and the function of important membrane proteins. In addition, 2- hydroxyarachidonic acid (2OHARA; LP204A1), 2-hydroxyeicosapentaenoic acid (2OHEPA; LP205A1), and 2-hydroxydocosahexanoic acid (2OHDHA; LP226A1) are new hydroxy derivated lipids designed in our group for the treatment of Alzheimer’s Disease. The main goal of this work was to study how these synthetic hydroxy derivates modulate the unfolded protein response and the autophagy pathways in glioma cells and neuron-like cells for Alzheimer’s Disease.

576