Structure of the membrane-bound form of the pore-forming domain of colicin A: A partial proteolysis and mass spectrometry study

Massotte, Dominique; Yamamoto, Mika; Scianimanico, Sandra; Sorokine, Odile; Dorsselaer, Alain Van; Nakatani, Yôichi; Ourisson, Guy; Pattus, F.

doi:10.1021/bi00213a006

Cited by 30 publications

(24 citation statements)

References 33 publications

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“…Indeed, the ability of such short helices to form a channel is mainly related to their effect on membrane thickness and the induction of curvature in the membrane associated with toroidal pore formation (further comments on this topic in ''Lipids and Proteins Acting Together: The Protein-Lipid Pore'' section) (Parker et al 1990). Alternatively, the ''penknife'' model proposes that the hydrophobic hairpin is only shallowly inserted while laying more or less parallel to the membrane plane (Massotte et al 1993). Another possibility is that the hydrophobic hairpin is in fact alternating between these two different conformations (Kienker et al 1997).…”

Section: Colicins/bax Familymentioning

confidence: 99%

More Than a Pore: The Interplay of Pore-Forming Proteins and Lipid Membranes

Ros

García‐Sáez

2015

J Membrane Biol

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Pore-forming proteins (PFPs) punch holes in their target cell membrane to alter their permeability. Permeabilization of lipid membranes by PFPs has received special attention to study the basic molecular mechanisms of protein insertion into membranes and the development of biotechnological tools. PFPs act through a general multi-step mechanism that involves (i) membrane partitioning, (ii) insertion into the hydrophobic core of the bilayer, (iii) oligomerization, and (iv) pore formation. Interestingly, PFPs and membranes show a dynamic interplay. As PFPs are usually produced as soluble proteins, they require a large conformational change for membrane insertion. Moreover, membrane structure is modified upon PFPs insertion. In this context, the toroidal pore model has been proposed to describe a pore architecture in which not only protein molecules but also lipids are directly involved in the structure. Here, we discuss how PFPs and lipids cooperate and remodel each other to achieve pore formation, and explore new evidences of protein-lipid pore structures.

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Section: Colicins/bax Familymentioning

confidence: 99%

More Than a Pore: The Interplay of Pore-Forming Proteins and Lipid Membranes

Ros

García‐Sáez

2015

J Membrane Biol

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“…The em max data for the contingent of single Trp mutant and WT proteins strongly suggest that the polarity of the Trp residues (at 11 of the 14 different Trp sites within the peptide) increases when the protein associates with (51); biotinylation (41,42,53); epitope mapping (43); saturation mutagenesis (55); protease accessibility (28,47); depth-dependent fluorescence quenching (29,31); cysteine-scanning mutagenesis (56); FRET (27); CD, Fourier transform infrared radiation, and differential scanning calorimetry (48,49); time-resolved spin labeling (57); and acrylamide quenching and other fluorescence data presented in this work. The initial surface-bound structure adopts at least two states with state 2 being the most populated.…”

Section: Discussionmentioning

confidence: 99%

“…A model for colicin A has been proposed wherein most helices open like an "umbrella" on the surface of the membrane (26). An alternate model, called the "penknife model," has been suggested which proposes that helices 8 and 9 only partially penetrate into the membrane bilayer (27,28).…”

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confidence: 99%

Adventures in Membrane Protein Topology

Tory

Merrill

1999

Journal of Biological Chemistry

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The molecular aggregate size of the closed state of the colicin E1 channel was determined by fluorescence resonance energy transfer experiments involving a fluorescence donor (three tryptophans, wild-type protein) and a fluorescence acceptor (5-(((acetyl)amino)ethyl)aminonaphthalene-1-sulfonic acid (AEDANS), Trp-deficient protein). There was no evidence of energy transfer between the donor and acceptor species when bound to membrane large unilamellar vesicles. These experiments led to the conclusion that the colicin E1 channel is monomeric in the membrane-bound closed channel state. Experiments were also conducted to study the membrane topology of the closed colicin channel in membrane large unilamellar vesicles using acrylamide as the membrane-impermeant, nonionic quencher of tryptophan fluorescence in a battery of single tryptophan mutant proteins. Furthermore, additional fluorescence parameters, including fluorescence emission maximum, fluorescence quantum yield, and fluorescence decay times, were used to assist in mapping the topology of the closed channel. Results suggest that the closed channel comprises most of the polypeptide of the channel domain and that the hydrophobic anchor domain does not transverse the membrane bilayer but nonetheless is deeply embedded within the hydrocarbon core of the membrane. Finally, a model is proposed which features at least two states that are in rapid equilibrium with each other and in which one state is more heavily populated than the other.The cytotoxic function of the bactericidal protein colicin E1 is found in the ability of the protein to form voltage-gated, ionconductive channels within the cytoplasmic membrane of susceptible cells. However, despite recent strides in the elucidation of the soluble structures of whole colicin (1) and various channel domain fragments (2-4), the current state of knowledge of the structure and function of membrane-associated colicins is modest at best. Colicin E1, secreted by Escherichia coli that possess the naturally occurring colE1 plasmid, consists of three functional domains: the translocation, receptor-binding, and channel-forming domains. Initially, the receptor-binding domain (5) interacts with the vitamin B 12 receptor of target cells (6). After recognition, the translocation domain interacts with the tolA gene product, which permits the translocation of colicin E1 across the outer membrane and into the periplasm (7). In the periplasm the channel domain undergoes a conformational change to an insertion-competent state and then inserts spontaneously into the cytoplasmic membrane, forming an ion channel. The channel translocates monovalent ions, resulting in the dissipation of the cationic gradients (H ϩ , K ϩ , Na ϩ ) of the cell, causing depolarization of the cytoplasmic membrane (8, 9). In an effort to compensate for the membrane depolarization effected by the colicin E1 channel, Na ϩ /K ϩ ATPase activity is increased in the target cell, resulting in the consumption of ATP reserves, without concomitant replenishment (10). The...

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“…A model for colicin A has been proposed wherein most helices open like an "umbrella" on the surface of the membrane (52). An alternate model, called the "penknife model," has been suggested which proposes that helices 8 and 9 only partially penetrate into the membrane bilayer (53,54).…”

Section: Structurementioning

confidence: 99%