78 research outputs found

    Pore Formation by Equinatoxin II, a Eukaryotic Protein Toxin, Occurs by Induction of Nonlamellar Lipid Structures

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    Pore formation in the target cell membranes is a common mechanism used by many toxins in order to kill cells. Among various described mechanisms, a toroidal pore concept was described recently in the course of action of small antimicrobial peptides. Here we provide evidence that such mechanism may be used also by larger toxins. Membrane-destabilizing effects of equinatoxin II, a sea anemone cytolysin, were studied by various biophysical techniques. 31P NMR showed an occurrence of an isotropic component when toxin was added to multilamellar vesicles and heated. This component was not observed with melittin, alpha-staphylococcal toxin, or myoglobin. It does not originate from isolated small lipid structures, since the size of the vesicles after the experiment was similar to the control without toxin. Electron microscopy shows occurrence of a honeycomb structure, previously observed only for some particular lipid mixtures. The analysis of FTIR spectra of the equinatoxin II-lipid complex showed lipid disordering that is consistent with isotropic component observed in NMR. Finally, the cation selectivity of the toxin-induced pores increased in the presence of negatively charged phosphatidic acid, indicating the presence of lipids in the conductive channel. The results are compatible with the toroidal pore concept that might be a general mechanism of pore formation for various membrane-interacting proteins or peptides

    Peptides corresponding to helices 5 and 6 of Bax can independently form large lipid pores

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    Proteins of the B-cell lymphoma protein 2 (Bcl2) family are key regulators of the apoptotic cascade, controlling the release of apoptotic factors from the mitochondrial intermembrane space. A helical hairpin found in the core of water-soluble folds of these proteins has been reported to be the pore- forming domain. Here we show that peptides including any of the two a-helix fragments of the hairpin of Bcl2 associated protein X (Bax) can independently induce release of large labelled dextrans from synthetic lipid vesicles. The permeability promoted by these peptides is influenced by intrinsic monolayer curvature and accompanied by fast transbilayer redis- tribution of lipids, supporting a toroidal pore mechanism as in the case of the full-length protein. However, compared with the pores made by com- plete Bax, the pores made by the Bax peptides are smaller and do not need the concerted action of tBid. These data indicate that the sequences of both fragments of the hairpin contain the principal physicochemical require- ments for pore formation, showing a parallel between the permeabilization mechanism of a complex regulated protein system, such as Bax, and the much simpler pore-forming antibiotic peptides

    Single-molecule FRET studies on alpha-synuclein oligomerization of Parkinson's disease genetically related mutants.

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    Oligomers of alpha-synuclein are toxic to cells and have been proposed to play a key role in the etiopathogenesis of Parkinson's disease. As certain missense mutations in the gene encoding for alpha-synuclein induce early-onset forms of the disease, it has been suggested that these variants might have an inherent tendency to produce high concentrations of oligomers during aggregation, although a direct experimental evidence for this is still missing. We used single-molecule Förster Resonance Energy Transfer to visualize directly the protein self-assembly process by wild-type alpha-synuclein and A53T, A30P and E46K mutants and to compare the structural properties of the ensemble of oligomers generated. We found that the kinetics of oligomer formation correlates with the natural tendency of each variant to acquire beta-sheet structure. Moreover, A53T and A30P showed significant differences in the averaged FRET efficiency of one of the two types of oligomers formed compared to the wild-type oligomers, indicating possible structural variety among the ensemble of species generated. Importantly, we found similar concentrations of oligomers during the lag-phase of the aggregation of wild-type and mutated alpha-synuclein, suggesting that the properties of the ensemble of oligomers generated during self-assembly might be more relevant than their absolute concentration for triggering neurodegeneration.LT has been recipient of a grant PAT Post Doc Outgoing 2009 – 7th Framework Program Marie Curie COFUND actions. NC was funded by a Royal Society Dorothy Hodgkin Research Fellowship and is currently a RamĂłn y Cajal Research Fellow (Spanish Ministry of Economy and Competitiveness). MHH thanks the Royal Society of Chemistry (Analytical Chemistry Trust Fund) for his studentship. AJD is funded by the Schiff Foundation.This is the final version of the article. It first appeared from NPG via http://dx.doi.org/10.1038/srep1669

    Distinction between Pore Assembly by Staphylococcal α-Toxin versus Leukotoxins

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    The staphylococcal bipartite leukotoxins and the homoheptameric α-toxin belong to the same family of ÎČ-barrel pore-forming toxins despite slight differences. In the α-toxin pore, the N-terminal extremity of each protomer interacts as a deployed latch with two consecutive protomers in the vicinity of the pore lumen. N-terminal extremities of leukotoxins as seen in their three-dimensional structures are heterogeneous in length and take part in the ÎČ-sandwich core of soluble monomers. Hence, the interaction of these N-terminal extremities within structures of adjacent monomers is questionable. We show here that modifications of their N-termini by two different processes, using fusion with glutathione S-transferase (GST) and bridging of the N-terminal extremity to the adjacent ÎČ-sheet via disulphide bridges, are not deleterious for biological activity. Therefore, bipartite leukotoxins do not need a large extension of their N-terminal extremities to form functional pores, thus illustrating a microheterogeneity of the structural organizations between bipartite leukotoxins and α-toxin

    Fast flow microfluidics and single-molecule fluorescence for the rapid characterization of α-synuclein oligomers.

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    α-Synuclein oligomers can be toxic to cells and may be responsible for cell death in Parkinson's disease. Their typically low abundance and highly heterogeneous nature, however, make such species challenging to study using traditional biochemical techniques. By combining fast-flow microfluidics with single-molecule fluorescence, we are able to rapidly follow the process by which oligomers of αS are formed and to characterize the species themselves. We have used the technique to show that populations of oligomers with different FRET efficiencies have varying stabilities when diluted into low ionic strength solutions. Interestingly, we have found that oligomers formed early in the aggregation pathway have electrostatic repulsions that are shielded in the high ionic strength buffer and therefore dissociate when diluted into lower ionic strength solutions. This property can be used to isolate different structural groups of αS oligomers and can help to rationalize some aspects of αS amyloid fibril formation.M.H.H. thanks the Royal Society of Chemistry (Analytical Chemistry Trust Fund) for his studentship. L.T. has been the recipient of a grant PAT Post Doc Outgoing 2009 – 7th Framework Program Marie Curie COFUND actions. A.J.D. is funded by the Schiff Foundation.This is the author accepted manuscript. The final version is available from ACS via http://dx.doi.org/10.1021/acs.analchem.5b0181

    Integrating artificial with natural cells to translate chemical messages that direct E. coli behaviour

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    Previous efforts to control cellular behaviour have largely relied upon various forms of genetic engineering. Once the genetic content of a living cell is modified, the behaviour of that cell typically changes as well. However, other methods of cellular control are possible. All cells sense and respond to their environment. Therefore, artificial, non-living cellular mimics could be engineered to activate or repress already existing natural sensory pathways of living cells through chemical communication. Here we describe the construction of such a system. The artificial cells expand the senses of Escherichia coli by translating a chemical message that E. coli cannot sense on its own to a molecule that activates a natural cellular response. This methodology could open new opportunities in engineering cellular behaviour without exploiting genetically modified organisms

    La renovaciĂłn de la palabra en el bicentenario de la Argentina : los colores de la mirada lingĂŒĂ­stica

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    El libro reĂșne trabajos en los que se exponen resultados de investigaciones presentadas por investigadores de Argentina, Chile, Brasil, España, Italia y Alemania en el XII Congreso de la Sociedad Argentina de LingĂŒĂ­stica (SAL), Bicentenario: la renovaciĂłn de la palabra, realizado en Mendoza, Argentina, entre el 6 y el 9 de abril de 2010. Las temĂĄticas abordadas en los 167 capĂ­tulos muestran las grandes lĂ­neas de investigaciĂłn que se desarrollan fundamentalmente en nuestro paĂ­s, pero tambiĂ©n en los otros paĂ­ses mencionados arriba, y señalan ademĂĄs las ĂĄreas que reciĂ©n se inician, con poca tradiciĂłn en nuestro paĂ­s y que deberĂ­an fomentarse. Los trabajos aquĂ­ publicados se enmarcan dentro de las siguientes disciplinas y/o campos de investigaciĂłn: FonologĂ­a, Sintaxis, SemĂĄntica y PragmĂĄtica, LingĂŒĂ­stica Cognitiva, AnĂĄlisis del Discurso, PsicolingĂŒĂ­stica, AdquisiciĂłn de la Lengua, SociolingĂŒĂ­stica y DialectologĂ­a, DidĂĄctica de la lengua, LingĂŒĂ­stica Aplicada, LingĂŒĂ­stica Computacional, Historia de la Lengua y la LingĂŒĂ­stica, Lenguas AborĂ­genes, FilosofĂ­a del Lenguaje, LexicologĂ­a y TerminologĂ­a

    The equinatoxin N‐terminus is transferred across planar lipid membranes and helps to stabilize the transmembrane pore

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    Equinatoxin II is a cytolytic protein isolated from the sea anemone Actinia equina. It is a member of the actinoporins, a family of eukaryotic pore‐forming toxins with a unique mechanism of pore formation. Equinatoxin II is a 20 kDa cysteineless protein, with sphingomyelin‐dependent activity. Recent studies showed that the N‐terminal region of the molecule requires conformational flexibility during pore formation. An understanding of the N‐terminal position in the final pore and its role in membrane insertion and pore stability is essential to define the precise molecular mechanism of pore formation. The formation of pores and their electrophysiologic characteristics were studied with planar lipid membranes. We show that amino acids at positions 1 and 3 of equinatoxin II are exposed to the lumen of the pore. Moreover, sulfhydryl reagents and a hexa‐histidine tag attached to the N‐terminus revealed that the N‐terminus of the toxin extends through the pore to the other (trans) side of the membrane and that negatively charged residues inside the pore are crucial to define the electrophysiologic characteristics of the channel. Finally, we detected a new, less stable, state with a lower conductance by using a deletion mutant in which the first five N‐terminal amino acids were removed. We propose that the first five amino acids help to anchor the amphipathic helix on the trans side of the membrane and consequently stabilize the final transmembrane pore
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