Fernanda Dias da Silva scite author profile

Antimicrobial peptides (AMPs) constitute promising alternatives to classical antibiotics for the treatment of drug-resistant infections, which are a rapidly emerging global health challenge. However, our understanding of the structure-function relationships of AMPs is limited, and we are just beginning to rationally engineer peptides in order to develop them as therapeutics. Here, we leverage a physicochemical-guided peptide design strategy to identify specific functional hotspots in the wasp-derived AMP polybia-CP and turn this toxic peptide into a viable antimicrobial. Helical fraction, hydrophobicity, and hydrophobic moment are identified as key structural and physicochemical determinants of antimicrobial activity, utilized in combination with rational engineering to generate synthetic AMPs with therapeutic activity in a mouse model. We demonstrate that, by tuning these physicochemical parameters, it is possible to design nontoxic synthetic peptides with enhanced sub-micromolar antimicrobial potency in vitro and anti-infective activity in vivo. We present a physicochemical-guided rational design strategy to generate peptide antibiotics.

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Structure and Mode of Action of Microplusin, a Copper II-chelating Antimicrobial Peptide from the Cattle Tick Rhipicephalus (Boophilus) microplus

Silva

Rezende

Rossi

et al. 2009

Journal of Biological Chemistry

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Microplusin, a Rhipicephalus (Boophilus) microplus antimicrobial peptide (AMP) is the first fully characterized member of a new family of cysteine-rich AMPs with histidine-rich regions at the N and C termini. In the tick, microplusin belongs to the arsenal of innate defense molecules active against bacteria and fungi. Here we describe the NMR solution structure of microplusin and demonstrate that the protein binds copper II and iron II. Structured as a single ␣-helical globular domain, microplusin consists of five ␣-helices: ␣1 (residues Gly-9 to Arg-21), ␣2 (residues Glu-27 to Asn-40), ␣3 (residues Arg-44 to Thr-54), ␣4 (residues Leu-57 to Tyr-64), and ␣5 (residues Asn-67 to Cys-80). The N and C termini are disordered. This structure is unlike any other AMP structures described to date. We also used NMR spectroscopy to map the copper binding region on microplusin. Finally, using the Gram-positive bacteria Micrococcus luteus as a model, we studied of mode of action of microplusin. Microplusin has a bacteriostatic effect and does not permeabilize the bacterial membrane. Because microplusin binds metals, we tested whether this was related to its antimicrobial activity. We found that the bacteriostatic effect of microplusin was fully reversed by supplementation of culture media with copper II but not iron II. We also demonstrated that microplusin affects M. luteus respiration, a copper-dependent process. Thus, we conclude that the antibacterial effect of microplusin is due to its ability to bind and sequester copper II.

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Decoralin Analogs with Increased Resistance to Degradation and Lower Hemolytic Activity

et al. 2017

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Decoralin is an antimicrobial peptide with activity against microorganisms and pronounced hemolytic activity. Decoralin analogs have been proposed, and the results indicated that when isoleucine at position 6 was substituted by phenylalanine residue, the peptides exhibited increased resistance towards enzymes action. Besides that, lower hemolytic activity was obtained for [Pro] 4 -Decoralin-NH 2 and [Phe] 6 -Des[Thr] 11 -Decoralin-NH 2 ; this effect is probably due to their poor helical tendency.[Arg] 1 -Decoralin-NH 2 exhibited + 4 net charge and lower hemolytic activity (25.0 mmol L À1 ) and even showed helical propensity; as a consequence, it presented the higher therapeutic indexes (values from 16.0 to 32.0). The helical conformational tendency is believed to be determinant of the antimicrobial activity of this decoralin family and has been shown to be as important as the increased positive net charge. This points to a new direction for the design of potential chemotherapeutic agents.[a] M.

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Antimicrobial activity in the tick Rhipicephalus (Boophilus) microplus eggs: Cellular localization and temporal expression of microplusin during oogenesis and embryogenesis

Esteves

Fogaça

Maldonado

et al. 2009

Developmental & Comparative Immunology

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Arthropods display different mechanisms to protect themselves against infections, among which antimicrobial peptides (AMPs) play an important role, acting directly against invader pathogens. We have detected several factors with inhibitory activity against Candida albicans and Micrococcus luteus on the surface and in homogenate of eggs of the tick Rhipicephalus (Boophilus) microplus. One of the anti-M. luteus factors of the egg homogenate was isolated to homogeneity. Analysis by electrospray mass spectrometry (ESI-MS) revealed that it corresponds to microplusin, an AMP previously isolated from the cell-free hemolymph of R. (B.) microplus. Reverse transcription (RT) quantitative polymerase chain reactions (qPCR) showed that the levels of microplusin mRNA gradually increase along ovary development, reaching an impressive highest value three days after the adult females have dropped from the calf and start oviposition. Interestingly, the level of microplusin mRNA is very low in recently laid eggs. An enhance of microplusin gene expression in eggs is observed only nine days after the onset of oviposition, achieving the highest level just before the larva hatching, when the level of expression decreases once again. Fluorescence microscopy analysis using an anti-microplusin serum revealed that microplusin is present among yolk granules of oocytes as well as in the connecting tube of ovaries. These results, together to our previous data, suggest that microplusin may be involved not only in protection of adult female hemocele, but also in protection of the female reproductive tract and embryos, what points this AMP as a considerable target for development of new methods to control R. (B.) microplus as well as the vector-borne pathogens.

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The Micelle-Bound Structure of an Antimicrobial Peptide Derived from the α-Chain of Bovine Hemoglobin Isolated from the TickBoophilus microplus

et al. 2005

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Hemoglobin is known to be a source of peptides involved in several functions. The peptide FLSFPTTKTYFPHFDLSHGSAQVKGHGAK (Hb33-61) is a proteolytic product of the bovine hemoglobin alpha-chain found in the gut content of the cattle tick, Boophilus microplus, and it possesses antimicrobial activity. Since in the past we showed that the amidated form of Hb33-61, Hb33-61a, is active against a few Gram-positive bacteria and fungi strains at micromolar concentration [Fogaca et al. (1999) J. Biol. Chem. 274, 25330-25334], we have been prompted to shed more light on its functional and structural features. Here we show that the peptide is able to disrupt the bacterial membrane ofMicrococcus luteus A270. As for its structure, it has a random conformation in water, and it does not interact with zwitterionic micelles. On the other hand, it binds to negatively charged micelles acquiring a finite structural organization. The 3D structure of Hb33-61a bound to SDS micelles exhibits a nonconventional conformation for an antimicrobial peptide. The backbone is characterized by the presence of a beta-turn in the N-terminus and by a beta-turn followed by a alpha-helical stretch in the C-terminus. A hinge, whose spatial organization is stabilized by side-chain-side-chain interactions, joins these two regions. Interestingly, it preserves structural features present in the corresponding segment of the bovine hemoglobin alpha-chain. Hb33-61a does not possess a well-defined amphipathic nature, and H/D exchange experiments show that while the C-terminal region is embedded in the SDS micelle, one face of the N-terminal half is partly exposed to the solvent.

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