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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.

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Showing 1 to 4 of 4 (0.021 seconds)

Spelling suggestions: "subject:"[een] PHOSPHOLIPID MONOLAYER"" "subject:"[enn] PHOSPHOLIPID MONOLAYER""

1

Phospholipid monolayer interactions at the air-water interface

Standish, M. M. January 1965 (has links)
No description available.
547.7
Phospholipid monolayer study
2

Solubilisation des oléosines de graines d'Arabidopsis thaliana, études structurales pour la valorisation / Solubilization and structural characterization of Arabidopsis thaliana seed oleosins

Vindigni, Jean-David 12 December 2011 (has links)
Les corps lipidiques (CLs) sont des organites de stockage de lipides neutres rencontrés dans des organismes très variés, depuis les procaryotes jusqu’aux organismes complexes (animaux, végétaux). La surface des CLs est constituée d’une monocouche de phospholipides (PLs) entourant un coeur hydrophobe dans lequel sont stockés les lipides neutres. La monocouche de PLs est associée plus ou moins étroitement avec des protéines structurales, capables de stabiliser les CLs et d’accompagner certaines de leurs modifications morphologiques. Dans les graines de plantes oléagineuses, les CLs sont stabilisés par les oléosines. Ces protéines contiennent le plus long domaine hydrophobe connu (70 résidus) situé entre deux extrémités N et C-terminales hydrophiles. Leur mode d’association avec les CLs n’est pas connu et la littérature fait état de résultats contradictoires concernant leur structure secondaire. Nous avons montré que les oléosines de graines d’Arabidopsis thaliana sont maintenues en solution par différentes catégories de surfactants, comme les détergents anioniques ou des polymères amphiphiles appelés amphipols (Apols). La détermination de la structure secondaire des oléosines maintenues en solution dans ces différents surfactants, par dichroïsme circulaire utilisant le rayonnement synchrotron, a mis en évidence des profils contrastés. Les détergents chargés augmentent le contenu en hélices α des oléosines alors que des proportions plus importantes de feuillets β sont observées avec le détergent zwitterionique (Foscholine-12) ou les Apols. Afin d’obtenir un profil structural modèle dans un système proche du naturel, nous avons réalisé une expression hétérologue d’une isoforme d’oléosine pour la cibler dans les CLs de Saccharomyces cerevisiae. Les CLs purifiés de levures restent intacts et contiennent une forte majorité de cette isoforme d’oléosine à leur surface. Nous avons été les premiers à montrer que les oléosines étaient repliées dans un tel environnement, avec un profil structural majoritairement β. Celui-ci se rapproche du profil observé en Foscholine-12. Ce détergent est par conséquent un outil de choix pour envisager des études structurales plus résolutives (structures tridimensionnelles). / Lipid Bodies (LBs) are neutral lipid storage organelles found in various organisms from procaryotic cells to complex organisms. These neutral lipids are packed into the core of the particle which is surrounded by a phospholipid monolayer. The surface of LBs is more or less tightly associated with structural proteins involved in their stabilization and able to assist modifications of their shape or size. In oleaginous seeds, LBs are stabilized by oleosins. These proteins contain the longest known hydrophobic domain (70 residues) flanked by hydrophilic N and C-termini. The way of association of these proteins with LBs is poorly known and secondary structure descriptions in the literature are contradictory. We have shown that Arabidopsis thaliana seed oleosins could be solubilized by various surfactants such as detergents or amphiphatic polymers called amphipols (Apols). Secondary structure determination of solubilized oleosins using synchrotron radiation circular dichroism gave contrasted profiles. Negatively charged detergents increase the α-helix content of oleosins whereas the zwitterionic detergent (Foscholine-12) or Apols allow higher proportions of β-sheets. In order to get closer to the natural environment of olesins, we have opted for the heterologous expression of one oleosin isoform in the yeast Saccharomyces cerevisiae. This approach allows the biological targeting and insertion of oleosins into cytosolic LBs. Purified yeast LBs remain intact and contain a large majority of oleosins at their surface. In this natural like environment, oleosins are folded and contain a majority of β-sheets. This secondary structure profile is close to that of oleosins solubilized by Foscholin-12, making it a suitable detergent for more resolutive structural studies (three-dimensional structures).
Oléosines
Corps lipidiques
Monocouche de phospholipides
Structure secondaire
Oleosins
Lipid bodies
Phospholipid monolayer
Secondary structure
572.2
3

Mobilisierung von Speicherlipiden in <i>Cucumis sativus</i>- und <i>Arabodopsis thaliana</i>-Keimlingen / Mobilisation of storage lipids in <i>Cucumis sativus</i> and <i>Arabidopsis thaliana</i> seedlings

Rudolph, Maike 23 January 2008 (has links)
No description available.
500 Naturwissenschaften allgemein
Mathematics and Computer Science
Speicherlipidabbau
Lipoxygenase
Patatin-ähnliche Phospholipase
Lipidkörpermembran
storage lipid degradation
lipoxygenase
patatin-like phospholipase
phospholipid monolayer
35.78
WVE200
WVG400
4

[en] MOLECULAR DYNAMICS OF PREDNISOLONE ADSORPTION ON A LUNG SURFACTANT MODEL / [pt] DINÂMICA MOLECULAR DA ADSORÇÃO DE PREDNISOLONA EM UM MODELO DE SURFACTANTE PULMONAR

EVELINA DUNESKA ESTRADA LOPEZ 28 May 2018 (has links)
[pt] A simulação da adsorção da prednisolona em um modelo de surfactante pulmonar foi realizada com sucesso usando dinâmica molecular coarse grained a uma temperatura de 310 K. O modelo coarse grained da prednisolona foi parametrizado usando o modelo do colesterol e validado utilizando cálculos de coeficientes de partição octanol-água e coeficientes de difusão lateral. O coeficiente de partição octanol-água calculado para prednisolona a 298 K é 3,9 mais ou menos 1,6 que possui um acordo razoável com o valor experimental. O coeficiente de difusão lateral da prednisolona na monocamada mista de DPPC/POPC é estimado ser (6 mais ou menos 4) x10(-7) cm(2) s(-1) a 20 mN m(-1), o que está de acordo com o encontrado para o colesterol. A monocamada mista de DPPC/POPC foi utilizada como modelo de surfactante pulmonar onde moléculas de prednisolona foram adsorvidas formando nanoagregados. Os nanoagregados de prednisolona foram transferidos dentro da monocamada mista DPPC/POPC sendo espalhados na tensão superficial de 20 mN m(-1). A 0 e 10 mN m(-1) os nanoagregados de prednisolona induzem o colapso da monocamada mista DPPC/POPC formando bicamadas. A implicação deste trabalho é que a prednisolona pode apenas ser administrada com surfactante pulmonar utilizando baixas frações em massa de prednisolona por lipídio (menor que 10 por cento). Com frações elevadas, o colapso inativa as propriedades do surfactante pulmonar pela formação de uma bicamada. Os resultados desta pesquisa podem ser utilizados para o desenvolvimento de novos tratamentos clínicos de doenças como a síndrome da angústia respiratória do recém-nascido, asma e doença pulmonar obstrutiva crônica. / [en] The simulation of prednisolone adsorption on a lung surfactant model was successfully performed using coarse grained molecular dynamics at 310 K (dynamics first performed). The coarse grained model for prednisolone was parameterized using a well-established cholesterol model and validated by using calculations of octanol–water partition coefficients and lateral diffusion coefficients. The calculated octanol–water partition coefficient of prednisolone at 298 K is 3.9 more or less 1.6, which is in reasonable agreement with experiment. The lateral diffusion coefficient of prednisolone in the DPPC/POPC mixed monolayer is estimated to be (6 more or less 4) x10(-7) cm(2) s(-1) at 20 mN m(-1), which is in agreement with that found for cholesterol. The DPPC/POPC mixed monolayer was used as lung surfactant model where prednisolone molecules were adsorbed forming nanoaggregates. The nanoaggregates of prednisolone were transferred into the DPPC/POPC mixed monolayer being spread at the surface tension of 20 mN m(-1). At 0 and 10 mN m(-1) , the prednisolone nanoaggregates induce the collapse of the DPPC/POPC mixed monolayer forming a bilayer. The implications of this work are that prednisolone may only be administered with lung surfactant by using low mass fractions of prednisolone per lipid (less than 10 percent). And, with high fractions, the collapse inactivates the properties of the lung surfactant by forming a bilayer. The results of this research can be used to develop new clinical treatments for diseases such as respiratory distress syndrome of the newborn, asthma and chronic obstructive pulmonary disease.
[pt] ESPALHAMENTO
[en] SCATTERING
[pt] COLAPSO
[en] COLLAPSE
[pt] PREDNISOLONA
[en] PREDNISOLONE
[pt] DINAMICA MOLECULAR
[en] MOLECULAR DYNAMICS
[pt] SURFACTANTE PULMONAR
[en] LUNG SURFACTANT
[pt] MONOCAMADA FOSFOLIPIDICA
[en] PHOSPHOLIPID MONOLAYER
[pt] MODELO COARSE GRAINED
[en] COARSE GRAINED MODEL

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