Preparation and Characterization of Novel Lipid and Proteolipid Membranes from Polymerizable Lipids

Subramaniam, Varuni

January 2006

The work described here has focused on two types of supramolecular assemblies, supported lipid bilayers (SLBs) and giant vesicles (GVs) from polymerizable lipids. SLBs are explored extensively as structural models in biophysical studies of cell membranes and biosensor coatings. With regard to implementation as biocompatible scaffoldings for receptor-based molecular devices, fluid SLBs lack chemical, thermal and mechanical stability as lipids are self-organized by weak, noncovalent forces. One possible solution is to use synthetic lipid monomers that can be polymerized to form robust bilayers. A key question is how polymerization affects transmembrane protein structure and activity. Specifically it is unclear if lipid cross-linking can be achieved without adversely affecting the activity of incorporated proteins. In this work the effect of lipid polymerization on transmembrane protein activity was studied with rhodopsin. The protein was reconstituted into SLBs composed of polymerizable lipids, bis-SorbPC, bis-SorbPC:mono-SorbPC, bis-DenPC and bis-SorbPC:mono-SorbPE. Rhodopsin photoactivity was monitored using plasmon waveguide spectroscopy. The results show that reconstitution of rhodopsin into SLBs composed of phosphatidylcholine with the polymerizable moiety in the acyl chain terminus, followed by photoinduced cross-linking of the lipids, does not significantly perturb protein function. A possible explanation is that a bilayer with relatively low Xn retains sufficient elasticity to accommodate the membrane deformation that accompanies the conformational change associated with rhodopsin photoactivation when polymerized in the acyl chain terminus. GVs have diameters ranging from several to few hundred micrometers and thus can be observed by optical microscopic methods. This allows manipulation of individual vesicles and observation of their transformations in real time. GVs have attracted attention as microcontainers for enzymes and drugs, and as biosensors. With the aim of increasing stability for these types of applications, GVs were prepared from synthetic dienoyl lipids that can be polymerized to form robust vesicles. The stability of these vesicles after polymerization was investigated by surfactant treatment, drying and rehydration, and temperature variations. The structure of poly(GVs) was largely retained under these conditions which destroy unpolymerized vesicles. Permeability studies on poly(GVs) suggests that they could be potentially used in a variety of technological applications, including sensors, macromolecular carriers, and microreactors.

Polymerizable lipids

Supported lipid membranes

Rhodopsin

Giant Vesicles

Fotossensibilização de vesículas lipídicas gigantes / Giant Lipid Vesicles Photosensibilization

Sudbrack, Tatiane de Paula

20 December 2011

A Terapia Fotodinâmica é um tratamento promissor no cura de várias doenças oftalmológicas e dermatológicas, assim como tumores. Este tratamento utiliza a combinação de luz e um composto fotossensível na presença de oxigênio. Neste trabalho objetivamos entender mecanismos de fotossensibilização em membranas. Para isso, estudamos os efeitos de irradiação em Vesículas Unilamelares Gigantes (GUVs) compostas de POPC e Cardiolipina (CL) e POPC e Colesterol (Col), contendo uma molécula fotoativa (diC12-porf) ancorada à superfície dessas membranas. GUVs compostas por POPC e POPC:Col na presença da molécula fotoativa reagem ao estímulo da luz exibindo um aumento de área seguido de flutuações. O mesmo foi observado para membranas de POPC contendo menos que 50mol% de CL. Já para composições contendo 50mol% de CL, a membrana passa a formar domínios lipídicos podendo ou não ser destruída durante a irradiação. Estes domínios podem ser suprimidos com a adição de EDTA (agente quelante de íons divalentes) na solução. Ao adicionarmos CaCl2 ao meio externo das GUVs contendo EDTA, percebemos que o efeito dos domínios e destruição da membrana reaparece. Tal fato evidencia que íons Ca++ presentes em solução devem complexar com as cargas da CL, levando à formação de domínios lipídicos. Ao quantificar o aumento de área sofrido pelas membranas percebemos que a presença de CL na membrana de POPC inibe o aumento de área para concentrações acima de 40mol% de CL. Já a presença de Col na membrana parece não contribuir significativamente para o aumento de área, embora o mesmo sofra oxidação. Além disso, evidenciou-se que na presença de CL/Col o tempo de fotoclareamento de diC12-porf é muito maior do que na ausência destes. Estes resultados evidenciam que a inclusão de CL na membrana oferece um número maior de sítios de reação para o oxigênio singlete reduzindo a foto-degradação da molécula fotoativa. Já a inclusão de Col aumenta o tempo de vida da molécula fotoativa provavelmente devido ao fato da dupla ligação do Col estar mais próxima ao centro produtor de oxigênio singlete do que a dupla ligação do POPC. / Photodynamic Therapy is a promising treatment for the cure of many diseases, like tumors. This treatment uses a combination of light and a photosensitive molecule in the presence of oxygen. In this way, our objective is to understand photosensibilization mechanisms on membranes. For this purpose, we studied the effects of irradiation in Giant Unilamelar Vesicles (GUVs) composed of POPC and Cardiolipin (CL) and POPC and Cholesterol (Chol) in the presence of a photosensitive molecule (diC12-porf). When the GUVs composed of POPC or POPC and Cholesterol (Chol) in the presence of the photosensitive molecule were irradiated, increase in surface area followed by fluctuations was observed. For GUVs composed of low concentrations of CL, the membrane photo-response was similar to that observed for pure POPC. For GUVs composed of 50 mol% CL different responses to light irradiation were observed. Some lipid domains appear for GUVs in water under irradiation and the GUV might be destroyed. When the irradiation was done in the presence of EDTA (chelant agent), the formation of the domains was prevented. Further addition of CaCl2 to this solution induced the formation of domains again leading eventually to membrane disruption. These results suggest that divalent cations have effect on the binding to CL negative polar heads, favoring lipid domain formation. We quantified the area increase obtained for the GUVs. For GUVs composed of CL we observed that until 40mol% of CL, the maximum expansion reached by the membrane area was similar to that obtained for pure POPC. For 50mol% of CL the increase of area is smaller than that found for GUVs composed only by POPC. For GUVs composed of Chol the behavior of the area is similar to that found for POPC. This means that the increase of area is mainly related to POPC peroxidation, although Chol hydroperoxide must be concomitantly formed too. Further, we observed that the diC12-porf photobleaching characteristic time for GUVs composed of CL/Chol is greater than that noted for GUVs composed of POPC. This means that when we introduce CL we are increasing the possibilities of reaction of the singlet oxygen and the photosensitive molecule is protected. The insertion of Chol in the membrane also protects the photosensitive molecule.

biofísica

biophysics

cardiolipin

cardiolipina

cholesterol

colesterol

fotossensibilização

giant vesicles

lipid peroxidation

microscopia óptica

optical microscopy

peroxidação lipídica

photosensibilization

porfirin

porfirina

vesículas gigantes

Fotossensibilização de vesículas lipídicas gigantes / Giant Lipid Vesicles Photosensibilization

Tatiane de Paula Sudbrack

20 December 2011

A Terapia Fotodinâmica é um tratamento promissor no cura de várias doenças oftalmológicas e dermatológicas, assim como tumores. Este tratamento utiliza a combinação de luz e um composto fotossensível na presença de oxigênio. Neste trabalho objetivamos entender mecanismos de fotossensibilização em membranas. Para isso, estudamos os efeitos de irradiação em Vesículas Unilamelares Gigantes (GUVs) compostas de POPC e Cardiolipina (CL) e POPC e Colesterol (Col), contendo uma molécula fotoativa (diC12-porf) ancorada à superfície dessas membranas. GUVs compostas por POPC e POPC:Col na presença da molécula fotoativa reagem ao estímulo da luz exibindo um aumento de área seguido de flutuações. O mesmo foi observado para membranas de POPC contendo menos que 50mol% de CL. Já para composições contendo 50mol% de CL, a membrana passa a formar domínios lipídicos podendo ou não ser destruída durante a irradiação. Estes domínios podem ser suprimidos com a adição de EDTA (agente quelante de íons divalentes) na solução. Ao adicionarmos CaCl2 ao meio externo das GUVs contendo EDTA, percebemos que o efeito dos domínios e destruição da membrana reaparece. Tal fato evidencia que íons Ca++ presentes em solução devem complexar com as cargas da CL, levando à formação de domínios lipídicos. Ao quantificar o aumento de área sofrido pelas membranas percebemos que a presença de CL na membrana de POPC inibe o aumento de área para concentrações acima de 40mol% de CL. Já a presença de Col na membrana parece não contribuir significativamente para o aumento de área, embora o mesmo sofra oxidação. Além disso, evidenciou-se que na presença de CL/Col o tempo de fotoclareamento de diC12-porf é muito maior do que na ausência destes. Estes resultados evidenciam que a inclusão de CL na membrana oferece um número maior de sítios de reação para o oxigênio singlete reduzindo a foto-degradação da molécula fotoativa. Já a inclusão de Col aumenta o tempo de vida da molécula fotoativa provavelmente devido ao fato da dupla ligação do Col estar mais próxima ao centro produtor de oxigênio singlete do que a dupla ligação do POPC. / Photodynamic Therapy is a promising treatment for the cure of many diseases, like tumors. This treatment uses a combination of light and a photosensitive molecule in the presence of oxygen. In this way, our objective is to understand photosensibilization mechanisms on membranes. For this purpose, we studied the effects of irradiation in Giant Unilamelar Vesicles (GUVs) composed of POPC and Cardiolipin (CL) and POPC and Cholesterol (Chol) in the presence of a photosensitive molecule (diC12-porf). When the GUVs composed of POPC or POPC and Cholesterol (Chol) in the presence of the photosensitive molecule were irradiated, increase in surface area followed by fluctuations was observed. For GUVs composed of low concentrations of CL, the membrane photo-response was similar to that observed for pure POPC. For GUVs composed of 50 mol% CL different responses to light irradiation were observed. Some lipid domains appear for GUVs in water under irradiation and the GUV might be destroyed. When the irradiation was done in the presence of EDTA (chelant agent), the formation of the domains was prevented. Further addition of CaCl2 to this solution induced the formation of domains again leading eventually to membrane disruption. These results suggest that divalent cations have effect on the binding to CL negative polar heads, favoring lipid domain formation. We quantified the area increase obtained for the GUVs. For GUVs composed of CL we observed that until 40mol% of CL, the maximum expansion reached by the membrane area was similar to that obtained for pure POPC. For 50mol% of CL the increase of area is smaller than that found for GUVs composed only by POPC. For GUVs composed of Chol the behavior of the area is similar to that found for POPC. This means that the increase of area is mainly related to POPC peroxidation, although Chol hydroperoxide must be concomitantly formed too. Further, we observed that the diC12-porf photobleaching characteristic time for GUVs composed of CL/Chol is greater than that noted for GUVs composed of POPC. This means that when we introduce CL we are increasing the possibilities of reaction of the singlet oxygen and the photosensitive molecule is protected. The insertion of Chol in the membrane also protects the photosensitive molecule.

biofísica

cardiolipina

colesterol

fotossensibilização

microscopia óptica

peroxidação lipídica

porfirina

vesículas gigantes

biophysics

cardiolipin

cholesterol

giant vesicles

lipid peroxidation

optical microscopy

photosensibilization

porfirin