On the selectivity and efficacy of defense peptides with respect to cancer cells

Harris, Frederick; Dennison, Sarah Rachel; Singh, Jaipaul; Phoenix, David A.

doi:10.1002/med.20252

Cited by 150 publications

(151 citation statements)

References 327 publications

(828 reference statements)

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“…It is generally accepted that the interaction with the CM of target bacteria is an essential step in the antimicrobial action of AMPs [13][14][15][16][17] and interactions of this type have been investigated using a variety of model membranes [18][19][20][21][22][23] . These model membranes are usually formed from lipid mixtures with a head-group composition that reflects the molar ratio of the major lipids in the bacterial membrane, namely PE, phosphatidylglycerol (PG), Lys-PG and cardiolipin (CL).…”

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confidence: 99%

Low pH Enhances the Action of Maximin H5 against Staphylococcus aureus and Helps Mediate Lysylated Phosphatidylglycerol-Induced Resistance

et al. 2016

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Maximin H5 (MH5) is an amphibian antimicrobial peptide specifically targeting Staphylococcus aureus. At pH 6, the peptide showed an improved ability to penetrate (ΔΠ = 6.2 mN m–1) and lyse (lysis = 48%) Staphylococcus aureus membrane mimics, which incorporated physiological levels of lysylated phosphatidylglycerol (Lys-PG, 60%), compared to that at pH 7 (ΔΠ = 5.6 mN m–1 and lysis = 40% at pH 7) where levels of Lys-PG are lower (40%). The peptide therefore appears to have optimal function at pH levels known to be optimal for the organism’s growth. MH5 killed S. aureus (minimum inhibitory concentration of 90 μM) via membranolytic mechanisms that involved the stabilization of α-helical structure (approximately 45–50%) and showed similarities to the “Carpet” mechanism based on its ability to increase the rigidity (C s –1 = 109.94 mN m–1) and thermodynamic stability (ΔG mix = −3.0) of physiologically relevant S. aureus membrane mimics at pH 6. On the basis of theoretical analysis, this mechanism might involve the use of a tilted peptide structure, and efficacy was noted to vary inversely with the Lys-PG content of S. aureus membrane mimics for each pH studied (R 2 ∼ 0.97), which led to the suggestion that under biologically relevant conditions, low pH helps mediate Lys-PG-induced resistance in S. aureus to MH5 antibacterial action. The peptide showed a lack of hemolytic activity (<2% hemolysis) and merits further investigation as a potential template for development as an antistaphylococcal agent in medically and biotechnically relevant areas.

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confidence: 99%

Low pH Enhances the Action of Maximin H5 against Staphylococcus aureus and Helps Mediate Lysylated Phosphatidylglycerol-Induced Resistance

et al. 2016

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“…In this conformation, Cn-AMP2 exhibited a strongly hydrophobic region, formed by the C-terminal eight residues of the peptide, YFVFSVGM, which was flanked by a short anionic segment, TES [36,37]. This residue arrangement endows Cn-AMP2 with primary amphiphilicity [36,37], which has been reported for other anticancer peptides such as indolicidin [38,39] and is known to mediate the ability of these peptides to traverse membranes [40]. By analogy to indolicidin, it was suggested that the ability of Cn-AMP2 to traverse cancer cell membranes may be hydrophobicity driven by a mechanism involving the peptide's C-terminal region [36,37].…”

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confidence: 86%

“…A structural role has also been suggested for aspartate residues in the case of -helical HDPs such as Cr-ACP1 where they tend to occupy positions that are i ± 3 or i ± 4 relative to basic residues. It has been suggested that this structural positioning may promote helix formation via salt bridging and thereby serve as a strategy to stabilise -helical structure [38].…”

Section: Discussionmentioning

confidence: 99%

“…The sole exception to this requirement appears to be kalata B12 (net charge-2), which is another of the ADHPs found in O. affinis [84] and has an aspartate residue substituted in the otherwise conserved glutamate position [83]. As is believed for ADHPs in general [22,23,27], their counterparts within the cylotides do not appear to require protein receptors to facilitate their membrane interactions [85] although the universality of this belief is in question [38,86]. Most recently, kalata B2 and a number of other AHDPs within the cyclotides were found to show a strong preference for phosphatidyl ethanolamine (PE) in their membrane interactions, which led to the suggestion that PE may serve as a lipid receptor for these peptides [62,81,82].…”

Section: Ahdps From Cyclotidesmentioning

confidence: 98%

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Anionic Host Defence Peptides from the Plant Kingdom: Their Anticancer Activity and Mechanisms of Action

Harris¹,

Prabhu²,

Dennison³

et al. 2016

PPL

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Abstract:It is becoming increasingly clear that plants ranging across the plant kingdom produce anionic host defence peptides (AHDPs) with potent activity against a wide variety of human cancers cells. In general, this activity involves membrane partitioning by AHDPs, which leads to membranolysis and / or internalization to attack intracellular targets such as DNA. Several models have been proposed to describe these events including: the toroidal pore and Shai-Matsuzaki-Huang mechanisms but, in general, the mechanisms underpinning the membrane interactions and anticancer activity of these peptides are poorly understood. Plant AHDPs with anticancer activity can be conveniently discussed with reference to two groups: cyclotides, which possess cyclic molecules stabilized by cysteine knot motifs, and other ADHPs that adopt extended andhelical conformations. Here, we review research into the anticancer action of these two groups of peptides along with current understanding of the mechanisms underpinning this action.

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“…Reviews available in the literature provide detailed description of the many different mechanisms underlying cancer cell toxicity (Gaspar et al 2013;Harris et al 2013;Hoskin and Ramamoorthy 2008;Papo and Shai 2005;Mulder et al 2013). Studies on structureactivity relationship have shown that some ACPs share with AMPs the ability to disrupt cell membranes, causing poration or micellization, and additionally inducing necrosis and/or apoptosis (Bhutia and Maiti 2008;Papo and Shai 2005).…”

Section: Mechanisms Of Action Cellular Targets and Selectivity Of Anmentioning

confidence: 99%

Anticancer Peptides: Prospective Innovation in Cancer Therapy

Gaspar

Castanho

2016

Host Defense Peptides and Their Potential as Therapeutic Agents

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Current cancer treatments require improvements in selectivity and efficacy. Surgery, radiation, and chemotherapy approaches result in patient's suffering over time due to the development of severe side-effects that simultaneously condition adherence to therapy. Biologically active peptides, in particular antimicrobial peptides (AMPs), are versatile molecules in terms of biological activities. The cytotoxic activities of several AMPs turn this group of molecules into an amazing pool of new templates for anticancer drug development. However, several unmet challenges limit application of peptides in cancer therapy. The mechanism(s) of action of the peptides need better description and understanding, and innovative targets have to be discovered and explored, facilitating drug design and development. In this chapter, we explore the natural occurring AMPs as potential new anticancer peptides (ACPs) for cancer prevention and treatment. Their modes of action, selectivity to tumor compared to normal cells, preferential targets, and applications, but also their weaknesses, are described and discussed.

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On the selectivity and efficacy of defense peptides with respect to cancer cells

Cited by 150 publications

References 327 publications

Low pH Enhances the Action of Maximin H5 against Staphylococcus aureus and Helps Mediate Lysylated Phosphatidylglycerol-Induced Resistance

Low pH Enhances the Action of Maximin H5 against Staphylococcus aureus and Helps Mediate Lysylated Phosphatidylglycerol-Induced Resistance

Anionic Host Defence Peptides from the Plant Kingdom: Their Anticancer Activity and Mechanisms of Action

Anticancer Peptides: Prospective Innovation in Cancer Therapy

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