Rodney K. Tweten scite author profile

Clostridium perfringens perfringolysin O (PFO or theta-toxin) is a cytolytic toxin that binds to cholesterol-containing membranes and then self-associates to spontaneously form aqueous pores of varying size in the bilayer. In this study, a membrane-spanning domain has been identified in PFO by a combination of fluorescence spectroscopic methods using the fluorescent dye N, N'-dimethyl-N-(iodoacetyl)-N'-(7-nitrobenz-2-oxa-1, 3-diazolyl)ethylenediamine (NBD) whose emission properties are sensitive to water. PFO was substituted with a single cysteine at most of the residues between amino acids K189 and N218, and then each cysteine was modified with NBD. Each purified NBD-labeled PFO was then bound to membranes, and the probe's environment was ascertained by measuring its fluorescence lifetime, emission intensity, and collisional quenching with either aqueous (iodide ions) or nonaqueous (nitroxide-labeled phospholipids) quenchers. Lifetime and intensity measurements revealed that the amino acid side chains in this region of the membrane-bound PFO polypeptide alternated between being in an aqueous or a nonaqueous environment. This pattern indicates that this portion of the membrane-bound PFO spans the membrane in an antiparallel beta-sheet conformation. The alternating exposure of these residues to the hydrophobic interior of the bilayer was demonstrated by their susceptibility to quenching by nitroxide moieties attached to phospholipid acyl chains. Residues K189-N218 therefore form a two-stranded, amphipathic beta-sheet in the membrane-bound PFO that creates a stable interface between the pore and the membrane. This same region packs as three short alpha-helices in the soluble, monomeric form of PFO, and therefore, the cholesterol-dependent conversion of PFO to a membrane-bound oligomer involves a major structural transition in which three alpha-helices unfold to form a membrane-spanning amphipathic beta-sheet.

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Structure of a Cholesterol-Binding, Thiol-Activated Cytolysin and a Model of Its Membrane Form

Rossjohn

Feil

McKinstry

et al. 1997

Cell

441

468

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The mechanisms by which proteins gain entry into membranes is a fundamental problem in biology. Here, we present the first crystal structure of a thiol-activated cytolysin, perfringolysin O, a member of a large family of toxins that kill eukaryotic cells by punching holes in their membranes. The molecule adopts an unusually elongated shape rich in beta sheet. We have used electron microscopy data to construct a detailed model of the membrane channel form of the toxin. The structures reveal a novel mechanism for membrane insertion. Surprisingly, the toxin receptor, cholesterol, appears to play multiple roles: targeting, promotion of oligomerization, triggering a membrane insertion competent form, and stabilizing the membrane pore.

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Cholesterol-Dependent Cytolysins, a Family of Versatile Pore-Forming Toxins

2005

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The cholesterol-dependent cytolysins (CDCs) are a large family of pore-forming toxins that are produced by more than 20 species from the genera Clostridium, Streptococcus, Listeria, Bacillus, and Arcanobacterium. The pore-forming mechanism of these toxins exhibits two hallmark characteristics: an absolute dependence on the presence of membrane cholesterol and the formation of an extraordinarily large pore. Each CDC is produced as a soluble monomeric protein that, with the exception of one member, is secreted by a type II secretion system. Upon encountering a eukaryotic cell, the CDCs undergo a transformation from a soluble monomeric protein to a membrane-embedded supramolecular pore complex. The conversion of the monomers to an oligomeric, membrane-inserted pore complex requires some extraordinary changes in the structure of the monomer, yet the mechanism of pore formation may be only the beginning of the CDC story.Although the CDCs are well known as beta-hemolytic proteins, it has become increasingly apparent that bacterial pathogens use these proteins in much more sophisticated ways than as simple hemolysins or general cell-lytic agents. The CDC structure also exhibits a plasticity that has allowed the evolution of unique features for some CDCs, without compromising the fundamental pore-forming mechanism. Some of these features are reflected in CDCs that activate complement, that utilize a nonsterol receptor, that exhibit a pH-sensitive, poreforming mechanism, or that can function as a protein translocation channel. As will be apparent in this review, our knowledge of how the CDCs are used by pathogens lags behind our understanding of the CDC pore-forming mechanism, although some studies have provided some provocative glimpses into how the bacterial cells use CDCs during an infection. This review will focus on the advancements in our understanding of the CDC pore-forming mechanism, the unique structural and mechanistic features that are exhibited by many of the CDCs, and how these features might contribute to pathogenesis.

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The Mechanism of Membrane Insertion for a Cholesterol-Dependent Cytolysin

Shatursky

Heuck

Shepard

et al. 1999

Cell

345

382

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Perfringolysin O (PFO), a water-soluble monomeric cytolysin secreted by pathogenic Clostridium perfringens, oligomerizes and forms large pores upon encountering cholesterol-containing membranes. Whereas all pore-forming bacterial toxins examined previously have been shown to penetrate the membrane using a single amphipathic beta hairpin per polypeptide, cysteine-scanning mutagenesis and multiple independent fluorescence techniques here reveal that each PFO monomer contains a second domain involved in pore formation, and that each of the two amphipathic beta hairpins completely spans the membrane. In the soluble monomer, these transmembrane segments are folded into six alpha helices. The insertion of two transmembrane hairpins per toxin monomer and the major change in secondary structure are striking and define a novel paradigm for the mechanism of membrane insertion by a cytolytic toxin.

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Only two amino acids are essential for cytolytic toxin recognition of cholesterol at the membrane surface

Farrand

LaChapelle

Hotze

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

192

279

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The recognition and binding of cholesterol is an important feature of many eukaryotic, viral, and prokaryotic proteins, but the molecular details of such interactions are understood only for a few proteins. The pore-forming cholesterol-dependent cytolysins (CDCs) contribute to the pathogenic mechanisms of a large number of Grampositive bacteria. Cholesterol dependence of the CDC mechanism is a hallmark of these toxins, yet the identity of the CDC cholesterol recognition motif has remained elusive. A detailed analysis of membrane interactive structures at the tip of perfringolysin O (PFO) domain 4 reveals that a threonine-leucine pair mediates CDC recognition of and binding to membrane cholesterol. This motif is conserved in all known CDCs and conservative changes in its sequence or order are not well tolerated. Thus, the Thr-Leu pair constitutes a common structural basis for mediating CDC-cholesterol recognition and binding, and defines a unique paradigm for membrane cholesterol recognition by surface-binding proteins.M embrane cholesterol is important to a variety of pathogenic processes that include virus fusion and budding (1) and the mechanisms of eukaryotic (2, 3) and prokaryotic toxins (4-7). Whether cholesterol is bound directly by these proteins as a receptor or it indirectly influences the binding or activity of the protein at the membrane surface remains unknown. The cholesterol-dependent cytolysins (CDCs) use cholesterol as their receptor at the membrane surface (7) and contribute to the pathogenesis of a large number of Gram-positive bacterial pathogens (8). The CDC-sterol interaction initiates a cascade of secondary and tertiary structural changes that lead to the formation of a large oligomeric complex, and ultimately a pore in the membrane of eukaryotic cells (9-13). Although significant progress has been made in understanding the assembly of the CDC pore complex, the structural basis for recognition and binding to cholesterol-rich membranes remains elusive.Early studies with the Clostridium perfringens perfringolysin O (PFO) suggested that the highly conserved tryptophan-rich undecapeptide sequence at the base of domain 4 (14, 15) (Fig. S1) mediated the PFO-cholesterol interaction. However, recent studies by Soltani et al. (16) uncoupled cholesterol binding from the undecapeptide and showed that the membrane insertion of loops L1-L3 at the base of domain 4 was cholesterol dependent (Fig. S1). These observations are also consistent with a lack of conservation of the 3D structures of the undecapeptide in the closely related CDCs PFO (17) and Bacillus anthracis anthrolysin O (ALO) (18) (Fig. S1). These studies suggest the residues that comprise the cholesterol recognition motif are located within L1-L3 because these loops and the undecapeptide are the only structures at the tip of domain 4 exposed to the nonpolar bilayer core; the rest of the domain 4 surface is surrounded by water (19).Cholesterol was thought to function as the sole CDC receptor until the discovery of intermedilysin (ILY), a CDC fr...

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Membrane-dependent conformational changes initiate cholesterol-dependent cytolysin oligomerization and intersubunit β-strand alignment

Ramachandran

Tweten

Johnson

2004

Nat Struct Mol Biol

169

267

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Cholesterol-dependent cytolysins are bacterial protein toxins that bind to cholesterol-containing membranes, form oligomeric complexes and insert into the bilayer to create large aqueous pores. Membrane-dependent structural rearrangements required to initiate the oligomerization of perfringolysin O monomers have been identified, as have the monomer-monomer interaction surfaces, using site-specific mutagenesis, disulfide trapping and multiple fluorescence techniques. Upon binding to the membrane, a structural element in perfringolysin O moves to expose the edge of a previously hidden beta-strand that forms the monomer-monomer interface and is required for oligomer assembly. The beta-strands that form the interface each contain a single aromatic residue, and these aromatics appear to stack, thereby aligning the transmembrane beta-hairpins of adjacent monomers in the proper register for insertion. Collectively, these data reveal a novel membrane binding-dependent mechanism for regulating cytolysin monomer-monomer association and pore formation.

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Human CD59 is a receptor for the cholesterol-dependent cytolysin intermedilysin

Giddings

Zhao

Sims

et al. 2004

Nat Struct Mol Biol

208

251

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Cholesterol is believed to serve as the common receptor for the cholesterol-dependent cytolysins (CDCs). One member of this toxin family, Streptococcus intermedius intermedilysin (ILY), exhibits a narrow spectrum of cellular specificity that is seemingly inconsistent with this premise. We show here that ILY, via its domain 4 structure, binds to the glycosyl-phosphatidylinositol-linked membrane protein human CD59 (huCD59). CD59 is an inhibitor of the membrane attack complex of human complement. ILY specifically binds to huCD59 via residues that are the binding site for the C8alpha and C9 complement proteins. These studies provide a new model for the mechanism of cellular recognition by a CDC.

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Vertical collapse of a cytolysin prepore moves its transmembrane β-hairpins to the membrane

Czajkowsky

Hotze

Shao

et al. 2004

EMBO J

225

233

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Perfringolysin O (PFO) is a prototype of the large family of pore-forming cholesterol-dependent cytolysins (CDCs). A central enigma of the cytolytic mechanism of the CDCs is that their membrane-spanning b-hairpins (the transmembrane amphipathic b-hairpins (TMHs)) appear to be B40 Å too far above the membrane surface to cross the bilayer and form the pore. We now present evidence, using atomic force microscopy (AFM), of a significant difference in the height by which the prepore and pore protrude from the membrane surface: 11375 Å for the prepore but only 7375 Å for the pore. Time-lapse AFM micrographs show this change in height in real time. Moreover, the monomers in both complexes exhibit nearly identical surface features and these results in combination with those of spectrofluorimetric analyses indicate that the monomers remain in a perpendicular orientation to the bilayer plane during this transition. Therefore, the PFO undergoes a vertical collapse that brings its TMHs to the membrane surface so that they can extend across the bilayer to form the b-barrel pore.

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Rodney K. Tweten

Identification of a Membrane-Spanning Domain of the Thiol-Activated Pore-Forming Toxin Clostridium perfringens Perfringolysin O: An α-Helical to β-Sheet Transition Identified by Fluorescence Spectroscopy

Structure of a Cholesterol-Binding, Thiol-Activated Cytolysin and a Model of Its Membrane Form

Cholesterol-Dependent Cytolysins, a Family of Versatile Pore-Forming Toxins

The Mechanism of Membrane Insertion for a Cholesterol-Dependent Cytolysin

Only two amino acids are essential for cytolytic toxin recognition of cholesterol at the membrane surface

Membrane-dependent conformational changes initiate cholesterol-dependent cytolysin oligomerization and intersubunit β-strand alignment

Human CD59 is a receptor for the cholesterol-dependent cytolysin intermedilysin

Vertical collapse of a cytolysin prepore moves its transmembrane β-hairpins to the membrane

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