A methodology was implemented for purifying peptides in one chromatographic run via solid-phase extraction (SPE), reverse phase mode (RP), and gradient elution, obtaining high-purity products with good yields. Crude peptides were analyzed by reverse phase high performance liquid chromatography and a new mathematical model based on its retention time was developed in order to predict the percentage of organic modifier in which the peptide will elute in RP-SPE. This information was used for designing the elution program of each molecule. It was possible to purify peptides with different physicochemical properties, showing that this method is versatile and requires low solvent consumption, making it the least polluting one. Reverse phase-SPE can easily be routinely implemented. It is an alternative to enrich and purified synthetic or natural molecules.
Chimeric peptides containing short sequences derived from bovine Lactoferricin (LfcinB) and Buforin II (BFII) were synthetized using solid‐phase peptide synthesis (SPPS) and characterized via reversed‐phase liquid chromatography and mass spectrometry. The chimeras were obtained with high purity, demonstrating their synthetic viability. The chimeras’ antibacterial activity against Gram‐positive and Gram‐negative strains was evaluated. Our results showed that all the chimeras exhibited greater antibacterial activity against the evaluated strains than the individual sequences, suggesting that chemical binding of short sequences derived from AMPs significantly increased the antibacterial activity. For each strain, the chimera with the best antibacterial activity exerted a bacteriostatic and/or bactericidal effect, which was dependent on the concentration. It was found that: (i) the antibacterial activity of a chimera is mainly influenced by the linked sequences, the palindromic motif RLLRRLLR being the most relevant one; (ii) the inclusion of a spacer between the short sequences did not significantly affect the chimera's synthesis process; however, it enhanced its antibacterial activity against Gram‐negative and Gram‐positive strains; on the other hand, (iii) the replacement of Arg with Lys in the LfcinB or BFII sequences improved the chimeras’ synthesis process without significantly affecting their antibacterial activity. These results illustrate the great importance of the synthesis of chimeric peptides for the generation of promising antibacterial peptides.
Scheme 1. Copper-catalyzed azide-alkyne cycloaddition of Pra-RRWQWR (1) with Lys(N 3 )-RLLR (2) for obtaining the chimeric peptide (3)
Click chemistry is currently one of the most used tools for the generation of complex organic molecules. The advantages of using click chemistry in organic synthesis are remarkable; in many cases, the reactions occur under mild conditions and are free of solvents, with high yields and short reaction times. This makes it an extraordinarily effective and viable alternative for obtaining complex/conjugated molecules. In this review, the use of click chemistry CuAAC is especially emphasized for polyhydroxylated platforms such as resorcinarenes or calixarenes, focusing mainly on aspects of synthesis, specifically conditions, reagents, and methodologies.
Antimicrobial peptides (AMPs) are considered to be a valuable source for the identification and/or design of promising candidates for the development of antifungal treatments, since they have advantages such as lower tendency to induce resistance, ease of production, and high purity and safety. Bovine lactoferricin (LfcinB) and buforin II (BFII) are AMPs to which great antimicrobial potential has been attributed. The minimum motives with antimicrobial activity derived from LfcinB and BFII are RRWQWR and RLLR, respectively. Nine chimeras containing the minimum motives of both peptides were synthesized and their antifungal activity against fluconazole (FLC)-sensitive and resistant C. albicans, C. glabrata, and C. auris strains was evaluated. The results showed that peptides C9: (RRWQWR)2K-Ahx-RLLRRRLLR and C6: KKWQWK-Ahx-RLLRRLLR exhibited the greatest antifungal activity against two strains of C. albicans, a FLC-sensitive reference strain and a FLC-resistant clinical isolate; no medically significant results were observed with the other chimeras evaluated (MIC ~200 µg/mL). The chimera C6 was also active against sensitive and resistant strains of C. glabrata and C. auris. The combination of branched polyvalent chimeras together with FLC showed a synergistic effect against C. albicans. In addition to exhibiting antifungal activity against reference strains and clinical isolates of Candida spp., they also showed antibacterial activity against both Gram-positive and Gram-negative bacteria, suggesting that these chimeras exhibit a broad antimicrobial spectrum and can be considered to be promising molecules for therapeutic applications.
Short peptides derived from buforin and lactoferricin B were conjugated with other antimicrobial molecules of different chemical natures.
: Over the last few years, short peptides have become a powerful tool in basic and applied research, with different uses like diagnostic, antimicrobial peptides, human health promoters or bioactive peptides, therapeutic treatments, templates for peptidomimetic design, and peptide-based vaccines. In this endeavor, different approaches and technologies have been explored, such as bioinformatics, large-scale peptide synthesis, omics sciences, structure-activity relationship studies, and a biophysical approach, among others, seeking to obtain the shortest sequence with the best activity. The advantage of short peptides lies in their stability, ease of production, safety, and low cost. There are many strategies for designing short peptides with biomedical and industrial applications (targeting the structure, length, charge, or polarity) or as a starting point for improving their properties (sequence data base, de novo sequences, templates, or organic scaffolds). In peptide design, it is necessary to keep in mind factors such as the application (peptidomimetic, immunogen, antimicrobial, bioactive, or proteinprotein interaction inhibitor), the expected target (membrane cell, nucleus, receptor proteins, or immune system), and particular characteristics (shorter, conformationally constrained, cycled, charged, flexible, polymerized, or pseudopeptides). This review summarizes the different synthetic approaches and strategies used to design new peptide analogs, highlighting the achievements, constraints, and advantages of each.
A reversed-phase high-performance liquid chromatography (RP-HPLC) method was developed to study the conformer formation generated during the reaction for obtaining C-tetramethylcalix [4]resorcinarene. The chromatographic method was used to design a strategy for purifying the reaction products, using solid-phase extraction columns (RP-SPE) and gradient elution. The chromatographic profiles of the cyclocondensation reaction between resorcinol and acetaldehyde show the presence of three products under the different reaction and precipitation conditions studied. Using RP-SPE, it was possible to enrich the products, which were later characterized by means of RP-HPLC and 1 H nuclear magnetic resonance (NMR). This investigation explored and established a new method for RP-HPLC analysis and RP-SPE separation of conformational isomers obtained in the formation reaction of C-tetramethylcalix [4]resorcinarene.
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