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Neutrophil products inhibit LLO secretion and activity, and <i>Listeria monocytogenes </i> intracellular growthArnett, Eusondia A. 25 September 2013 (has links)
No description available.
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Molecular mode of action of Cry6Aa1, a new insecticidal Bacillus thuringiensis toxinFortea Verdejo, Eva 08 1900 (has links)
Cry6Aa1, une nouvelle toxine produite par Bacillus thuringiensis (Bt), agit comme insecticide sur la chrysomèle du maïs (WCRW). Dans cette étude, on démontre que Cry6Aa1 est une toxine formeuse de pores (TFP) en bicouches lipidiques planes (BLP). Contrairement aux autres toxines de Bt étudiées jusqu’à présent, la formation de pores par Cry6Aa1 ne requiert pas
de prétraitement par protéases et se produit à des doses de toxine deux à trois ordres de grandeur plus faibles que celles nécessaires pour les autres toxines de Bt dans les mêmes conditions.
La formation de pores par la forme non traitée de Cry6Aa1 dépend du pH; les pores obtenus ont des conductances comprises entre 31 et 689 pS en conditions symétriques de 150 mM de KCl; ils sont cationiques avec un comportement cinétique complexe. Les propriétés biophysiques des pores ne changent pas lorsque la toxine est traitée avec le suc du mésenthéron de l’insecte (Cry6Aa1 WCR1). Par contre, un traitement à la trypsine (Cry6Aa1 TT) modifie la conductance
et la sélectivité des pores à pH 5,5 (le pH physiologique de l’intestin de WCRW). La reconstitution en BLP de fraction de membrane native du mésenthéron de WCRW affecte les propriétés des pores formés par Cy6Aa1. Les déterminants moléculaires du mode d’action de cette nouvelle toxine formeuse de pores semblent donc différer de ceux décrits précédemment pour d’autres toxines de Bt.
La structure atomique tridimensionnelle de Cry6Aa1 vient tout juste d’être élucidée. Elle montre que la toxine adopte une conformation riche en hélices α qui ressemble fortement à celle de la TFP ClyA produite par E. coli. En se fondant sur les données disponibles pour ClyA, on a étudié l’effet de divers changements dans les régions N et C terminales de Cry6Aa1 sur sa capacité de former des pores en BLP. / Cry6Aa1 is a new toxin produced by Bacillus thuringiensis (Bt), which displays insecticidal
activity against the Western corn rootworm (WCRW). The present work demonstrates that
Cry6Aa1 is a pore-forming toxin (PFT) in planar lipid bilayers (PLBs). Contrary to other Bt toxins
tested so far, pore formation by Cry6Aa1 does not require protease pretreatment and takes place
at doses that are two to three orders of magnitude lower than those required for other Bt toxins
under similar conditions.
Pore formation by Cry6Aa1 is pH-dependent; the conductances of the pores range between
31 and 689 pS under symmetrical 150 mM KCl conditions; they are cationic and display a complex
kinetic behaviour. The treatment of the toxin with midgut juice (Cry6Aa1 WCR1) does not change
the biophysical properties of the pores. However, the treatment with trypsin (Cry6Aa1 TT) affects
their conductance and selectivity at pH 5.5 (the WCRW gut physiological pH). The incorporation
in PLBs of native membrane material from WCRW midgut affects the behaviour of the Cry6Aa1
pores. The molecular determinants of the mode of action of this new PFT appear therefore to differ
from those reported before for other Bt toxins.
The three-dimensional (3-D) atomic structure of Cry6Aa1 has just been elucidated. It
shows that the toxin assumes an α-helix-rich configuration, which is quite similar to that of the
ClyA PFT produced by E. coli. Based on the data available for ClyA, we have studied how
different changes in the N- and C-terminal regions of Cry6Aa1 affect its pore formation ability in
PLBs.
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Imaging the assembly of the Staphylococcal pore-forming toxin alpha-HemolysinThompson, James Russell January 2009 (has links)
Alpha-hemolysin is a pore-forming toxin secreted by pathogenic Staphylococcus aureus. Its spontaneous oligomerization and assembly into a trans-bilayer beta-barrel pore is a model for the assembly of many other pore-forming toxins. It is studied here in vitro as a means to probe general membrane protein oligomerization and lipid bilayer insertion. This thesis details the results of experiments to develop and implement a novel in vitro lipid bilayer system, Droplet-on-Hydrogel Bilayers (DHBs) for the single-molecule imaging of alpha-hemolysin assembly. Chapter 2 describes the development of DHBs and their electrical characterization. Experiments show the detection of membrane channels in SDS-PAGE gels post-electrophoresis and DHBs use as a platform for nanopore stochastic sensing. Chapter 3 describes the engineering and characterization of fluorescently-labelled monomeric alpha-hemolysin for use in protein assembly imaging experiments described in Chapter 6. Chapter 4 describes the characterization of DHB lipid fluidity and suitability for single-molecule studies of membrane protein diffusion. In addition, a novel single-particle tracking algorithm is described. Chapter 5 describes experiments demonstrating simultaneous electrical and fluorescence measurements of alpha-hemolysin pores embedded within DHBs. The first multiple-pore stochastic sensing in a single-lipid bilayer is also described. Chapter 6 describes experiments studying the assembly of alpha-hemolysin monomers in DHBs. Results show that alpha-hemolysin assembles rapidly into its oligomeric state, with no detection of long-lived intermediate states.
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