Electron microscopic evaluation of a two-step theory of pore formation by streptolysin O

Sekiya, Keizo; Danbara, Hirofumi; Yase, K; Futaesaku, Yutaka

doi:10.1128/jb.178.23.6998-7002.1996

Cited by 25 publications

(26 citation statements)

References 16 publications

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“…The membrane machinery of the TAT pathway for export of partially folded, coenzyme-liganded periplasmic proteins appears to have a central chamber about 6 nm in diameter (21), but it is highly specific for proteins carrying the TAT signal and is carefully gated. The only membrane channels of comparable size are the 30-nm-diameter cytocidal ␤-sheet channels formed in mammalian membranes by the streptolysin-O class of thiol-activated cytotoxins (1,22); however, these toxins are soluble exoproteins that undergo a complex tertiary and quaternary rearrangement once bound to the membrane.…”

Section: Discussionmentioning

confidence: 99%

Sizing the Holin Lesion with an Endolysin-β-Galactosidase Fusion

2003

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Double-stranded DNA phages require two proteins for efficient host lysis: the endolysin, a muralytic enzyme, and the holin, a small membrane protein. In an event that defines the end of the vegetative cycle, the holin S acts suddenly to permeabilize the membrane. This permeabilization enables the R endolysin to attack the cell wall, after which cell lysis occurs within seconds. A C-terminal fusion of the R endolysin with full-length ␤-galactosidase (␤-Gal) was tested for lytic competence in the context of the late-gene expression system of an induced lysogen. Under these conditions, the hybrid R-␤-Gal product, an active tetrameric ␤-Gal greater than 480 kDa in mass, was fully functional in lysis mediated by the S holin. Western blot analysis demonstrated that the lytic competence was not due to the proteolytic release of the endolysin domain of the R-␤-Gal fusion protein. The ability of this massive complex to be released by the S holin suggests that S causes a generalized membrane disruption rather than a regular oligomeric membrane pore. Similar results were obtained with an early lysis variant of the S holin and also in parallel experiments with the T4 holin, T, in an identical lambda context. However, premature holin lesions triggered by depolarization of the membrane were nonpermissive for the hybrid endolysin, indicating that these premature lesions constituted less-profound damage to the membrane. Finally, a truncated T holin functional in lysis with the endolysin is completely incompetent for lysis with the hybrid endolysin. A model for the formation of the membrane lesion within homo-oligomeric rafts of holin proteins is discussed.

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Section: Discussionmentioning

confidence: 99%

Sizing the Holin Lesion with an Endolysin-β-Galactosidase Fusion

2003

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“…Some electron microscopic techniques and/or analyses of crystal structures have provided insight into construction of the physiological pores made of aerolysin (16 -18), cholesterol-dependent cytolysins (19,20), and staphylococcal ␣-toxin (21) and so on (22, 23). In contrast, there is no report regarding microscopic observations of the CPE complex on the plasma membrane and molecular structure of the full-length CPE.…”

mentioning

confidence: 99%

Crystal Structure of Clostridium perfringens Enterotoxin Displays Features of β-Pore-forming Toxins

Kitadokoro

Nishimura

Kamitani

et al. 2011

Journal of Biological Chemistry

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Clostridium perfringens enterotoxin (CPE) is a cause of food poisoning and is considered a pore-forming toxin, which damages target cells by disrupting the selective permeability of the plasma membrane. However, the pore-forming mechanism and the structural characteristics of the pores are not well documented. Here, we present the structure of CPE determined by x-ray crystallography at 2.0 Å . The overall structure of CPE displays an elongated shape, composed of three distinct domains, I, II, and III. Domain I corresponds to the region that was formerly referred to as C-CPE, which is responsible for binding to the specific receptor claudin. Domains II and III comprise a characteristic module, which resembles those of ␤-pore-forming toxins such as aerolysin, C. perfringens ⑀-toxin, and Laetiporus sulfureus hemolytic pore-forming lectin. The module is mainly made up of ␤-strands, two of which span its entire length. Domain II and domain III have three short ␤-strands each, by which they are distinguished. In addition, domain II has an ␣-helix lying on the ␤-strands. The sequence of amino acids composing the ␣-helix and preceding ␤-strand demonstrates an alternating pattern of hydrophobic residues that is characteristic of transmembrane domains forming ␤-barrel-made pores. These structural features imply that CPE is a ␤-pore-forming toxin. We also hypothesize that the transmembrane domain is inserted into the membrane upon the buckling of the two long ␤-strands spanning the module, a mechanism analogous to that of the cholesterol-dependent cytolysins. Clostridium perfringens enterotoxin (CPE),2 which damages intestinal epithelia, is a causative agent of food poisoning. The toxin consists of a single chain polypeptide of 319 amino acids. The C-terminal domain of CPE (C-CPE, residues 184 -319) recognizes and binds to certain members of the claudin family, components of tight junctions, as a receptor on target cells (1-4), and the N-terminal region is believed to be involved in forming physiological pores to disrupt the selective permeability of the plasma membrane, resulting in cell death (5-7). It was also reported that the physiological pores are composed of a large complex comprising CPE and cellular components such as claudins (2,8).The binding between C-CPE and claudins has been well characterized. The 16 -17 C-terminal amino acids of C-CPE were reportedly important for the interaction (9, 10), especially, Tyr 306 , Tyr 310 , Tyr 312, and Leu 315 (11-13). According to the crystal structure of C-CPE (14), these residues organize a cleft space that is considered to interact directly with claudins. Claudins are tetratransmembrane proteins. The region of claudins responsible for binding to CPE was located on the C-terminal side of the second extracellular loop and recently designated CPE-SR for CPE sensitivity-related region (15). The bottom of the cleft space of CPE is negatively charged, whereas the CPESRs of CPE-sensitive claudins are positively charged. Therefore, it was proposed that electrostatic attraction at...

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“…Useful information may be found in the reviews or articles of THELESTAM and MOLLBY (1979); ALOUF (1980);ALOUF et al (1984ALOUF et al ( , 1989; BHAKADI andTRANUM-JENSEN (1988, 1991); HARSHMAN et al (1989);MENESTRINA et al (1990);SEKIYA et al (1993SEKIYA et al ( , 1996; MORGAN et al (1994); WALKER and BAYLEY (1995);DOBEREINER et al (1996);PALMER et al (1996);VALEVA et al (1997);VANDANA et al (1997);STAALI et al (1998);SHEPARD et al (1998); GILBERT et al (1998);ROSSJOHN et al (1998ROSSJOHN et al ( , 1999; MENESTRINA and VEcSEy-SEMJEN (1999);JACOBS et al (1999); ALOUF and PALMER (1999); MENEs-TRINA (2000); BILLINGTON et al (2000). It concerned the mechanism of action of these proteins on various eukaryotic cells or cell lines, isolated cell membranes (ghosts) and artificial model-membrane systems, such as phospholipid films and liposomes, investigated by a variety of biochemical, physical and electron microscopic techniques.…”

Section: Historical Backgroundmentioning

confidence: 99%

“…In contrast, the transmembrane pores formed by the cholesterol-binding toxins streptolysin 0, pneumolysin and perfringolysin ° create holes up to 25-30nm (SEKIYA et al 1993(SEKIYA et al , 1996MORGAN et al 1994;BALFANZ et al 1996;BAYLEY 1997;GILBERT et al 1999;SHATURSK Y ct al. 1999).…”

Section: Sizes Of the Toxin-induced Poresmentioning

confidence: 99%

Pore-Forming Bacterial Protein Toxins: An Overview

Alouf

2001

Current Topics in Microbiology and Immunology

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Electron microscopic evaluation of a two-step theory of pore formation by streptolysin O

Cited by 25 publications

References 16 publications

Sizing the Holin Lesion with an Endolysin-β-Galactosidase Fusion

Sizing the Holin Lesion with an Endolysin-β-Galactosidase Fusion

Crystal Structure of Clostridium perfringens Enterotoxin Displays Features of β-Pore-forming Toxins

Pore-Forming Bacterial Protein Toxins: An Overview

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