Reduction of membrane potential, an immediate effect of colicin K.

Weiss, Michael J.; Luria, Salvador E.

doi:10.1073/pnas.75.5.2483

Cited by 53 publications

(23 citation statements)

References 27 publications

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“…Among the bacterial poreforming proteins, perhaps most noteworthy are the colicins secreted by bacteria. Colicins El, Ia, and K depolarize E. coil (38)(39)(40), and colicin K is known to create voltage-dependent channels in the planar bilayer membrane (23). This change in ion permeability induced by colicins is compatible with a single-hit killing mechanism for target bacteria (23,33).…”

Section: Pore-forming Protein From E Tlistolyticamentioning

confidence: 99%

Characterization of a membrane pore-forming protein from Entamoeba histolytica.

Young¹,

Young²,

Lu³

et al. 1982

The Journal of Experimental Medicine

146

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We describe the partial purification and characterization of a pore-forming material (PEM) from Entamoeba histolytica. The formation of ion channels by PFM was examined in three systems. (a) PFM depolarizes J774 macrophages and mouse spleen lymphocytes as measured by [3H]TPP+ uptake. (b) PFM induces rapid monovalent cation flux across the membrane of phosphatidylcholine-cholesterol vesicles. (c) PFM confers a voltage-dependent conductance to artificial planar bilayers, which is resolved as a summation of opening of individually conducting steps of 67 pS in 0.1 M KCl. Monomers of PFM are functional; however, a preferential aggregation occurs in the planar bilayer. Activity is pronase, trypsin, and heat sensitive and is stable between pH 5-8. PFM is not secreted by unstimulated amoebae but after exposure to the calcium ionophore A23187, concanavalin A, and E. coli lipopolysaccharide, 5-10% of the total cell content of PFM is released into the medium within 5-10 min. High-performance gel filtration results in an approximately 1,000-fold purification of PFM and gives an Mr of 30,000. This protein may play a role in the cytotoxicity mediated by E. histolytica.

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Section: Pore-forming Protein From E Tlistolyticamentioning

confidence: 99%

Characterization of a membrane pore-forming protein from Entamoeba histolytica.

Young¹,

Young²,

Lu³

et al. 1982

The Journal of Experimental Medicine

146

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“…Colicin El is a 522-residue bactericidal protein, known to exert its lethal effect through an ability to depolarize the cytoplasmic membrane of sensitive Escherichia coli (1)(2)(3). Studies of colicin El action using artificial membranes have shown that the deenergization results from an ion channel formed by the colicin molecule, which dissipates the cellular membrane potential (ref.…”

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confidence: 99%

Acidic pH requirement for insertion of colicin E1 into artificial membrane vesicles: relevance to the mechanism of action of colicins and certain toxins.

Davidson¹,

Brunden²,

Cramer³

1985

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

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The channel-forming activity of colicin El in artificial membranes is known to increase at low pH values and to have a maximum near pH 4 in such membrane vesicles. The present work demonstrates that this pH dependence of activity can be attributed to membrane binding. Maximal binding of colicin El and a more slowly binding channelforming carboxyl-terminal tryptic peptide occurred at acidic pH values, with the effective pK values for binding equal to 4.6 and <4.0, respectively. The binding did not require imposition of a transmembrane potential. Insertion of the tryptic peptide into the membrane was shown by retention of bound [ HIleucine-labeled peptide by vesicles after digestion with protease, as well as by retention of the peptide in salt-washed vesicles. The retention after protease treatment was also used to estimate the amount of carboxyl-terminal peptide inserted into the membrane. Approximately 12 of the 21 leucines present in the carboxyl-terminal peptide were retained after Pronase treatment at pH < 4. Reversibility of the insertion at low pH values was seen after an alkaline shift of pH to 6.0, resulting in a decrease of the protease-inaccessible fraction of the bound protein. A model is presented describing a mechanism in which protonation of one or more carboxyl residues is necessary for effective binding and insertion into the membrane by the channel-forming domain of colicin El. This model may also be relevant to the mechanism of membrane insertion by certain toxins.Colicin El is a 522-residue bactericidal protein, known to exert its lethal effect through an ability to depolarize the cytoplasmic membrane of sensitive Escherichia coli (1-3). Studies of colicin El action using artificial membranes have shown that the deenergization results from an ion channel formed by the colicin molecule, which dissipates the cellular membrane potential (ref. 4, reviewed in refs. 5-7). Colicin El requires an acidic pH in vitro to form ion channels (8), and its action is dependent upon the sign and magnitude of the membrane potential (4, 8, 9). The channel-forming activity of colicin El has been shown to reside in a Mr 20,000 carboxyl-terminal tryptic peptide (10). The tryptic peptide and colicin required a low pH for in vitro activity. The effective pK values for activity, assayed by using artificial vesicles, were 4.6 and 3.8, respectively, for the colicin and the tryptic peptide (8). This requirement of an acidic pH for colicin El action resembles the pH dependence in vitro for the actions of diphtheria toxin (11)(12)(13)(14) and tetanus toxin (15), and it suggests that an explanation of this pH effect may bear on a general molecular mechanism for insertion into membranes of other colicins (2-4, 7, 16, 17), as well as the above-mentioned channel-forming toxin molecules (11)(12)(13)(14)(15).The purpose of the present work was to examine the mechanism of binding and of insertion into artificial membranes by the channel-forming domain of colicin El, and specifically its dependence on pH and protonation of o...

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“…Transmembrane potential (Em) generally reflects the functional integrity and metabolic state of the cell. Alterations in Em are often the initial response to metabolic poisons (Weiss and Luria, 1978;Okada et al, 1980) or membrane modifiers such as lipids (Boonstra et al, 1982). Cone (1970) has proposed that Em is the regulator of mitosis in both normal and neoplastic cells, with depolarization initiating proliferation and polarization causing the cessation of growth.…”

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Temperature‐dependent transmembrane potential changes in cells infected with a temperature‐sensitive moloney sarcoma virus

Lai¹,

Gallick²,

Arlinghaus³

et al. 1984

Journal Cellular Physiology

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Normal rat kidney cells (NRK) infected with the temperature-sensitive (ts) transformation mutant of Moloney murine sarcoma virus yielded a clone of cells, 6m2, that exhibited a transformed morphology at 33 degrees C and a normal morphology at 39 degrees C. Transmembrane potential (Em) was measured fluorometrically using a cyanine dye diS-C3-(5). Fluorescence was inversely correlated with Em. Cells at 33 degrees C had lower Em. Em changes were recorded within 15 minutes of temperature shift from 33 degrees C to 39 degrees C in both directions, increasing in the 33 degrees C to 39 degrees C direction and decreasing in the 39 degrees C to 33 degrees C direction. Uninfected NRK cells when shifted under the same condition exhibited small fluorescence changes in the 33 degrees C to 39 degrees C direction. Shifting from 39 degrees C to 33 degrees C resulted in Em changes similar to those in 6m2 cells. Also studied was a cell line infected with a spontaneous revertant of the ts mutant, designated 54-5A4; it was transformed at both temperatures. Shifting from 33 degrees C to 39 degrees C in both directions yielded small changes. Transmembrane potential changes in 6m2 cells precede other transformation-specific changes that occur after a temperature shift.

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Reduction of membrane potential, an immediate effect of colicin K.

Cited by 53 publications

References 27 publications

Characterization of a membrane pore-forming protein from Entamoeba histolytica.

Characterization of a membrane pore-forming protein from Entamoeba histolytica.

Acidic pH requirement for insertion of colicin E1 into artificial membrane vesicles: relevance to the mechanism of action of colicins and certain toxins.

Temperature‐dependent transmembrane potential changes in cells infected with a temperature‐sensitive moloney sarcoma virus

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