Antifungal and antitumor models of bioactive protective peptides

Rodrigues, Elaine G.; Dobroff, Andrey S.; Taborda, Carlos Pelleschi; Travassos, Luiz R.

doi:10.1590/s0001-37652009000300015

Cited by 35 publications

(34 citation statements)

References 127 publications

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“…This entrance might lead to the disruption of the cell membrane accompanied by pore formation and/or changes on the cell membrane charge (Janek et al, 2013) and finally the interference with necrotic (Maher and McClean, 2008; Huang et al, 2011; Ausbacher et al, 2012; Wang et al, 2013a) and apoptotic pathways (Ausbacher et al, 2012). Pore formation is a mechanism associated to some AMPs and has been reported for ACPs as well (Rodrigues et al, 2009). The insertion of bulky hydrophobic amino acids on the cell membrane hydrophobic core with the acquisition of a stable structure can be the driving events for pore formation (Hilchie et al, 2011).…”

Section: Anticancer Peptides For Solid and Hematological Tumorsmentioning

confidence: 79%

“…In a structural point of view, most ACPs have either α-helical or β-sheet conformation but some extended structures have already been reported (Hoskin and Ramamoorthy, 2008; Rodrigues et al, 2009; Wang et al, 2009a; Hammami and Fliss, 2010). Concerning cell targets, they can be classified into two major groups.…”

Section: Anticancer Peptides—classification Selectivity and Modes Omentioning

confidence: 99%

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From antimicrobial to anticancer peptides. A review

Gaspar¹,

Veiga²,

Castanho³

2013

Front. Microbiol.

575

528

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Antimicrobial peptides (AMPs) are part of the innate immune defense mechanism of many organisms. Although AMPs have been essentially studied and developed as potential alternatives for fighting infectious diseases, their use as anticancer peptides (ACPs) in cancer therapy either alone or in combination with other conventional drugs has been regarded as a therapeutic strategy to explore. As human cancer remains a cause of high morbidity and mortality worldwide, an urgent need of new, selective, and more efficient drugs is evident. Even though ACPs are expected to be selective toward tumor cells without impairing the normal body physiological functions, the development of a selective ACP has been a challenge. It is not yet possible to predict antitumor activity based on ACPs structures. ACPs are unique molecules when compared to the actual chemotherapeutic arsenal available for cancer treatment and display a variety of modes of action which in some types of cancer seem to co-exist. Regardless the debate surrounding the definition of structure-activity relationships for ACPs, great effort has been invested in ACP design and the challenge of improving effective killing of tumor cells remains. As detailed studies on ACPs mechanisms of action are crucial for optimizing drug development, in this review we provide an overview of the literature concerning peptides' structure, modes of action, selectivity, and efficacy and also summarize some of the many ACPs studied and/or developed for targeting different solid and hematologic malignancies with special emphasis on the first group. Strategies described for drug development and for increasing peptide selectivity toward specific cells while reducing toxicity are also discussed.

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Section: Anticancer Peptides For Solid and Hematological Tumorsmentioning

confidence: 79%

Section: Anticancer Peptides—classification Selectivity and Modes Omentioning

confidence: 99%

From antimicrobial to anticancer peptides. A review

Gaspar¹,

Veiga²,

Castanho³

2013

Front. Microbiol.

575

528

View full text Add to dashboard Cite

show abstract

“…The 3D non‐acetylated anticancer peptide model presented cationic (Lys 3 ) and aromatic (Trp 2 ) residues forming a single amphipathic α‐helice that showed 55% of hydrophobic residues. This structural fold is commonly found in peptides with multiple activities such as antimicrobial, antifungal, and antitumoral [Rodrigues et al, 2009]. Helene and Maurizot [Helene and Maurizot, 1981] have observed that short oligopeptides containing basic and aromatic residues provided simple systems where it was possible to differentiate between single‐stranded and double‐stranded structures by inserting their aromatic residue between successive bases.…”

Section: Resultsmentioning

confidence: 99%

Identification and characterization of a bactericidal and proapoptotic peptide from cycas revoluta seeds with DNA binding properties

Mandal

Migliolo²,

Das

et al. 2011

J of Cellular Biochemistry

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Nowadays, novel pharmacies have been screened from plants. Among them are the peptides, which show multiple biotechnological activities. In this report, a small peptide (Ala-Trp-Lys-Leu-Phe-Asp-Asp-Gly-Val) with a molecular mass of 1,050 Da was purified from Cycas revoluta seeds by using reversed-phase liquid chromatography. This peptide shows clear deleterious effects against human epidermoid cancer (Hep2) and colon carcinoma cells (HCT15). It caused inhibition of cancer cell proliferation and further disruption of nucleosome structures, inducing apoptosis by direct DNA binding. A remarkable antibacterial activity was also observed in this same peptide. Nevertheless, no significant lysis of normal RBC cells was observed in the presence of peptide. Additionally, an acetylation at the N-termini portion is able to reduce both activities. Bioinformatics tools were also utilized for construction of a three-dimensional model showing a single amphipathic helix. Since in vitro binding studies show that the target of this peptide seems to be DNA, theoretical docking studies were also performed to better understand the interaction between peptide and nucleic acids and also to shed some light on the acetyl group role. Firstly, binding studies showed that affinity contacts basically occur due to electrostatic attraction. The complex peptide-ssDNA was clearly oriented by residues Ala(1), Lys(3), and Asp(6), which form several hydrogen bonds that are able to stabilize the complex. When acetyl was added, hydrogen bonds are broken, reducing the peptide affinity. In summary, it seems that information here provided could be used to design a novel derivative of this peptide which a clear therapeutic potential.

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“…The primary function of defense peptides is to serve as naturally occurring antibiotics of the innate immune system, targeting a wide variety of microbes ranging from bacteria and viruses to parasites and fungi . However, over the last decade, it has become increasingly clear that many of these peptides also possess a potent ability to inactivate a wide range of cancer cells . A number of articles and databases have listed these anticancer peptides (ACPs), and inspection of these sources shows that the vast majority of ACPs are cationic and adopt molecular architecture that is either β‐sheet (β‐ACPs) or α‐helical (α‐ACPs), although several extended ACPs (E‐ACPs) have been described (Tables and ) .…”

Section: Defense Peptidesmentioning

confidence: 99%

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

Harris

Dennison

Singh³

et al. 2011

Medicinal Research Reviews

148

143

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Here, we review potential determinants of the anticancer efficacy of innate immune peptides (ACPs) for cancer cells. These determinants include membrane-based factors, such as receptors, phosphatidylserine, sialic acid residues, and sulfated glycans, and peptide-based factors, such as residue composition, sequence length, net charge, hydrophobic arc size, hydrophobicity, and amphiphilicity. Each of these factors may contribute to the anticancer action of ACPs, but no single factor(s) makes an overriding contribution to their overall selectivity and toxicity. Differences between the anticancer actions of ACPs seem to relate to different levels of interplay between these peptide and membrane-based factors.

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Antifungal and antitumor models of bioactive protective peptides

Cited by 35 publications

References 127 publications

From antimicrobial to anticancer peptides. A review

From antimicrobial to anticancer peptides. A review

Identification and characterization of a bactericidal and proapoptotic peptide from cycas revoluta seeds with DNA binding properties

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

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