pH-Selective Cytotoxicity of pHLIP-Antimicrobial Peptide Conjugates

Burns, Kelly E.; McCleerey, Tanner P.; Thévenin, Damien

doi:10.1038/srep28465

Cited by 57 publications

(69 citation statements)

References 38 publications

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“…However, one of the biggest therapeutic and biotechnical developments of these antimicrobial molecules has been to provide guidance to the design of novel compounds with pH dependent activity against: bacteria [303,304], fungi [46,305,306] and cancer cells [307,308] as well as applications involving drug [309,310] and gene delivery [311,312]. As a specific example, most AMPs designed to target the low pH of tumor tissue are cationic and cytotoxicity to healthy tissue at physiological pH has often been an issue for these peptides [98,279,280]. To address this issue, a peptide based on magainin 2 from X. laevis was designed to possess a negative charge at neutral pH that switched to a strong positive charge at low pH for cancer targeting.…”

Section: Discussionmentioning

confidence: 99%

“…As major examples, lactoferrin and its derivatives have been extensively investigated as potential drugs for the treatment of common viral infections including the common cold, influenza, viral gastroenteritis and herpes [275] whilst the inhibitory effects of these proteins and peptides against the proliferation of multiple cancers, has suggested a potential role in cancer prevention [276]. It is well established that many AMPs and antimicrobial proteins have anticancer activity that generally appears to involve mechanisms of membranolysis that are similar to those used by these molecules in their action against microbes [277,278], which in some cases shows pH dependence [98], as recently described [279,280]. Advanced clinical trials have shown that the administration of lactoferrin has no significant side effects and that the protein has efficacy in treating iron deficiency anemia in pregnant women [281], sepsis in premature neonates, which is a common and severe complication in new-born infants [282] and infections due to Helicobacter pylori , which is causally associated with gastritis and peptic ulcer diseases [283].…”

Section: Potential Applications Of Ph Dependent Antimicrobial Peptmentioning

confidence: 99%

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pH Dependent Antimicrobial Peptides and Proteins, Their Mechanisms of Action and Potential as Therapeutic Agents

et al. 2016

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Antimicrobial peptides (AMPs) are potent antibiotics of the innate immune system that have been extensively investigated as a potential solution to the global problem of infectious diseases caused by pathogenic microbes. A group of AMPs that are increasingly being reported are those that utilise pH dependent antimicrobial mechanisms, and here we review research into this area. This review shows that these antimicrobial molecules are produced by a diverse spectrum of creatures, including vertebrates and invertebrates, and are primarily cationic, although a number of anionic examples are known. Some of these molecules exhibit high pH optima for their antimicrobial activity but in most cases, these AMPs show activity against microbes that present low pH optima, which reflects the acidic pH generally found at their sites of action, particularly the skin. The modes of action used by these molecules are based on a number of major structure/function relationships, which include metal ion binding, changes to net charge and conformational plasticity, and primarily involve the protonation of histidine, aspartic acid and glutamic acid residues at low pH. The pH dependent activity of pore forming antimicrobial proteins involves mechanisms that generally differ fundamentally to those used by pH dependent AMPs, which can be described by the carpet, toroidal pore and barrel-stave pore models of membrane interaction. A number of pH dependent AMPs and antimicrobial proteins have been developed for medical purposes and have successfully completed clinical trials, including kappacins, LL-37, histatins and lactoferrin, along with a number of their derivatives. Major examples of the therapeutic application of these antimicrobial molecules include wound healing as well as the treatment of multiple cancers and infections due to viruses, bacteria and fungi. In general, these applications involve topical administration, such as the use of mouth washes, cream formulations and hydrogel delivery systems. Nonetheless, many pH dependent AMPs and antimicrobial proteins have yet to be fully characterized and these molecules, as a whole, represent an untapped source of novel biologically active agents that could aid fulfillment of the urgent need for alternatives to conventional antibiotics, helping to avert a return to the pre-antibiotic era.

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Section: Discussionmentioning

confidence: 99%

Section: Potential Applications Of Ph Dependent Antimicrobial Peptmentioning

confidence: 99%

pH Dependent Antimicrobial Peptides and Proteins, Their Mechanisms of Action and Potential as Therapeutic Agents

et al. 2016

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“…7–14 We recently showed that pHLIP provides localized delivery of monomethyl auristatin E (MMAE) to cancer cells. 12 This previous study shows that pHLIP-mediated translocation of MMAE inhibits the proliferation of cancer cells in a pH-selective and concentration-dependent fashion and that it offers clear advantages over treatment with free MMAE.…”

Section: Introductionmentioning

confidence: 99%

Therapeutic Efficacy of a Family of pHLIP–MMAF Conjugates in Cancer Cells and Mouse Models

et al. 2017

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The targeting of therapeutics specifically to diseased tissue is crucial for the development of successful cancer treatments. The approach here is based on the pH(low) insertion peptide (pHLIP) for the delivery of a potent mitotic inhibitor monomethyl auristatin F (MMAF). We investigated six pHLIP variants conjugated to MMAF to compare their efficacy in vitro against cultured cancer cells. While all pHLIP–MMAF conjugates exhibit potent pH- and concentration-dependent killing, their cytotoxicity profiles are remarkably different. We also show that the lead conjugate exhibits significant therapeutic efficacy in mouse models without overt toxicities. This study confirms pHLIP–monomethyl auristatin conjugates as possible new therapeutic options for cancer treatment and supports their further development.

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“…Within pHLIP there are multiple D/E residues which could sense the pH change,t he particular role played by eacho ft hem in the protonation-driven insertion process is not clear.T he precise location of the TM helix within the pHLIP sequence is also unknown. [11][12][13][14][15][16][17][18][19][20] To extend the biomedical applications of pHLIP to broader systems with higher efficiency,a ppropriate tuning of its primary sequence is necessary, [21,22] and to do so requires an in-depth and detailed understanding of its pH-regulated membrane insertion process,which is currently not available.Them acroscopic, apparent pH 50 ,d efined as the pH at which 50 %o ft he pHLIP molecules are inserted (also referred to as pK or pK a of insertion by others), has been estimated to be about 6.1-6.2 by following fluorescence changes of Wresidues at positions 9and 15. Residue-specific pK a values of D31, D33, D25, and D14 were determined to be 6.5, 6.3, 6.1, and 5.8, respectively,a nd define the sequence of protonations which lead to insertion.…”

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confidence: 99%

Protonation‐Driven Membrane Insertion of a pH‐Low Insertion Peptide

et al. 2016

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The pH-low insertion peptide (pHLIP) inserts into membranes and forms a transmembrane (TM) α-helix in response to slight acidity, and has shown great potential for cancer diagnosis and treatment. As a lead, pHLIP is challenging to optimize because the mechanism of its pH-dependent membrane interactions is not completely understood. Within pHLIP there are multiple D/E residues which could sense the pH change, the particular role played by each of them in the protonation-driven insertion process is not clear. The precise location of the TM helix within the pHLIP sequence is also unknown. In this work, solid-state NMR spectroscopy is used to address these central questions. Tracing backbone conformations revealed that the TM helix spans from A10 to D33 with a break at T19 to P20. Residue-specific pKa values of D31, D33, D25, and D14 were determined to be 6.5, 6.3, 6.1, and 5.8, respectively, and define the sequence of protonations which lead to insertion. Furthermore, possible intermediate states which disrupt membranes at pH 6.4 were proposed based on tryptophan fluorescence quenching and NMR data.

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pH-Selective Cytotoxicity of pHLIP-Antimicrobial Peptide Conjugates

Cited by 57 publications

References 38 publications

pH Dependent Antimicrobial Peptides and Proteins, Their Mechanisms of Action and Potential as Therapeutic Agents

pH Dependent Antimicrobial Peptides and Proteins, Their Mechanisms of Action and Potential as Therapeutic Agents

Therapeutic Efficacy of a Family of pHLIP–MMAF Conjugates in Cancer Cells and Mouse Models

Protonation‐Driven Membrane Insertion of a pH‐Low Insertion Peptide

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