Antibacterial and Antimembrane Activities of Cecropin A in
            <i>Escherichia coli</i>

Silvestro, Loraine; Weiser, Jeffrey N.; Axelsen, Paul H.

doi:10.1128/aac.44.3.602-607.2000

Cited by 119 publications

(107 citation statements)

References 26 publications

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“…On the other hand, the seeds may also act directly upon microorganisms and result in growth inhibition. Antimicrobial peptides are thought to act by disrupting the cell membrane or by inhibiting essential enzymes (Silvestro et al, 2000;Suarez et al, 2003). Sutherland et al (1990) reported that Moringa seeds could inhibit the replication of bacteriophages.…”

Section: Microbial Elimination With Moringa Seedsmentioning

confidence: 99%

Moringa oleifera: a food plant with multiple medicinal uses

Anwar

Latif

Ashraf

et al. 2006

Phytotherapy Research

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Section: Microbial Elimination With Moringa Seedsmentioning

confidence: 99%

Moringa oleifera: a food plant with multiple medicinal uses

Anwar

Latif

Ashraf

et al. 2006

Phytotherapy Research

1,533

1,048

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“…Antimicrobial peptides clearly have an affinity for membranes and exert an array of membrane-invasive activities, including folding-insertion reactions (19), channel formation (4), pore formation (21), and complete structural disruption (18). However, there are virtually no reliable data indicating that anionic lipids are present on the extracellular surface of the bacterial cell membrane, and several important structure-activity relationships are not adequately explained by this mechanism.…”

mentioning

confidence: 99%

Transcriptional Profile of theEscherichia coliResponse to the Antimicrobial Insect Peptide Cecropin A

Hong

Shchepetov

Weiser

et al. 2003

Antimicrob Agents Chemother

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Cationic antimicrobial peptides are believed to exert their primary activities on anionic bacterial cell membranes; however, this model does not adequately account for several important structure-activity relationships. These relationships are likely to be influenced by the bacterial response to peptide challenge. In order to characterize the genomic aspect of this response, transcription profiles were examined for Escherichia coli isolates treated with sublethal and lethal concentrations of the cationic antimicrobial peptide cecropin A. Transcript levels for 26 genes changed significantly following treatment with sublethal peptide concentrations, and half of the transcripts corresponded to protein products with unknown function. The pattern of response is distinct from that following treatment with lethal concentrations and is also distinct from the bacterial response to nutritional, thermal, osmotic, or oxidative stress. These results demonstrate that cecropin A induces a genomic response in E. coli apart from any lethal effects on the membrane and suggest that a complete understanding of its mechanism of action may require a detailed examination of this response.

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“…The pore-forming peptides discovered by screening the β-hairpin library in lipid vesicles thus share features in common with naturallyoccurring, pore-forming antimicrobial peptides (AMP) (27). We hypothesized that the mechanism of pore-formation in biological membranes is also similar, however, the correlation between structure and function of pore-forming peptide in vesicles and in biological membranes remains controversial (28). Therefore, we characterized the antimicrobial and cytotoxic activity of four similar peptides originating from this framework that have very different structures and pore-forming propensities in vesicles, including members of the library that do not form pores in vesicles under stringent conditions.…”

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β-Sheet Pore-Forming Peptides Selected from a Rational Combinatorial Library: Mechanism of Pore Formation in Lipid Vesicles and Activity in Biological Membranes

et al. 2007

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In a previous report we described the selection of potent, β-sheet pore-forming peptides from a combinatorial library designed to mimic membrane-spanning β-hairpins (Rausch JM, Marks JR and Wimley WC, (2005) PNAS, 102:10511-5). Here, we characterize their mechanism of action and compare the structure-function relationships in lipid vesicles to their activity in biological membranes. The pore-forming peptides bind to membrane interfaces and self-assemble into β-sheets that cause a transient burst of graded leakage across the bilayers. Despite the continued presence of the structured peptides in the bilayer, at most peptide concentrations leakage is incomplete and ceases quickly after peptide addition with a deactivation half-time of several minutes. Molecules up to 3,000 Da escape from the transient pores, but much larger molecules do not. Fluorescence spectroscopy and quenching showed that the peptides reside mainly on the bilayer surface and are partially exposed to water, rather than in a membrane-spanning state. The "carpet" or "sinking raft" model of peptide pore formation offers a viable explanation for our observations and suggests that the selected pore formers function with a mechanism that is similar to the natural pore-forming antimicrobial peptides. We therefore also characterized the antimicrobial and cytotoxic activity of these peptides. All peptides studied, including non pore-formers, had sterilizing antimicrobial activity against at least some microbes, and most have low activity against mammalian cell membranes. Thus, the structurefunction relationships that were apparent in the vesicle systems are similar to, but do not correlate completely with the activity of the same peptides in biological membranes. However, of the peptides tested, only the pore-formers selected in the high throughput screen have potent, broad-spectrum sterilizing activity against Gram-positive and Gram-negative bacteria as well as against fungi, while having only small lytic effects on human cells.A wide variety of pore-forming proteins and peptides take advantage of the discontinuous hydrophobicity of membrane-spanning β-sheets, which makes them well suited for undergoing transitions between hydrophilic and hydrophobic environments. For example, the β-barrel protein toxins including perfringolysin-O (1), α-hemolysin (2), and the anthrax protective antigen(3) pre-assemble a protein scaffold on membrane surfaces and then undergo a spontaneous transition in which loop sequences change conformation and are inserted into the membrane to form β-barrel pores. Similarly, there are many pore-forming, antimicrobial peptides (AMPs) 1 that are soluble in water and which self assemble into β-sheet-rich pores in membranes(4-6). To explore the structural determinants of folding and self-assembly of β- † Supported by the National Institutes of Health grant GM060000 *Corresponding author: Phone: 504-988-7076; Fax:504-988-2739, Email: wwimley@tulane.edu. NIH Public Access Author ManuscriptBiochemistry. Author manuscript; available ...

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Antibacterial and Antimembrane Activities of Cecropin A in Escherichia coli

Cited by 119 publications

References 26 publications

Moringa oleifera: a food plant with multiple medicinal uses

Moringa oleifera: a food plant with multiple medicinal uses

Transcriptional Profile of theEscherichia coliResponse to the Antimicrobial Insect Peptide Cecropin A

β-Sheet Pore-Forming Peptides Selected from a Rational Combinatorial Library: Mechanism of Pore Formation in Lipid Vesicles and Activity in Biological Membranes

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