bAntimicrobial peptides with amphipathic -hairpin-like structures have potent antimicrobial properties and low cytotoxicity. The effect of VR or RV motifs on -hairpin-like antimicrobial peptides has not been investigated. In this study, a series of -hairpin-like peptides, Ac-C(VR) n D PG (RV) n C-NH 2 (n ؍ 1, 2, 3, 4, or 5), were synthesized, and the effect of chain length on antimicrobial activity was evaluated. The antimicrobial activity of the peptides initially increased and then decreased with chain length. Longer peptides stimulated the toxicity to mammalian cells. VR3, a 16-mer peptide with seven amino acids in the strand, displayed the highest therapeutic index and represents the optimal chain length. VR3 reduced bacterial counts in the mouse peritoneum and increased the survival rate of mice at 7 days after Salmonella enterica serovar Typhimurium infection in vivo. The circular dichroism (CD) spectra demonstrated that the secondary structure of the peptides was a -hairpin or -sheet in the presence of an aqueous and membrane-mimicking environment. VR3 had the same degree of penetration into the outer and inner membranes as melittin. Experiments simulating the membrane environment showed that Trp-containing VRW3 (a VR3 analog) tends to interact preferentially with negatively charged vesicles in comparison to zwitterionic vesicles, which supports the biological activity data. Additionally, VR3 resulted in greater membrane damage than melittin as determined using a flow cytometry-based membrane integrity assay. Collectively, the data for synthetic lipid vesicles and whole bacteria demonstrated that the VR3 peptide killed bacteria via targeting the cell membrane. This assay could be an effective pathway to screen novel candidates for antibiotic development.
Protease-Activatable Organometal−Peptide Bioconjugates with Enhanced Cytotoxicity on Cancer Cells
Over the past years, numerous promising new metalorganic lead structures have been developed exhibiting highly active cytostatic properties. However, the efficiency of such chemotherapeutics in the treatment of tumors is often limited by their low therapeutic index due to their short half-life, lack of tumor selectivity, and associated side effects. Furthermore, the membrane barrier often restricts their cellular uptake by passive diffusion. In this contribution, we describe the synthesis, cellular uptake, and biologic activity of a series of cymantrene-peptide conjugates. Cymantrene CpMn(CO)(3) is a robust organometallic group, which is stable in air and water and easy to functionalize. In this work, some new cymantrene derivatives with different linkers between the half-sandwich complex and the carboxylate group were attached to the cell-penetrating peptide sC18 that should act as a transporter for the metal moiety. All conjugates were characterized for their cytotoxic activity on human breast adenocarcinoma cells (MCF-7) and human colon carcinoma cells (HT-29). We found that bioconjugates bearing two cymantrene groups were more active than the monofunctionalized ones. By the introduction of a cathepsin B cleavage site next to the organometallic group, the biologic activity could be in increased even further. Fluorescence microscopy studies and apoptosis assays gave preliminary hints on the mode of action of these systems.
By combining organometallic groups and peptides, a large number of conjugates with interesting new biological properties can be prepared. Especially, attachment to cell-penetrating peptides (CPP) that act as efficient cell delivery vehicles has come to the fore. However, the presence of the metal moiety in such systems can interfere with standard conjugate synthesis procedures which therefore need to be optimized for every new compound. In this work, we report on the preparation of six new cymantrene-sC18 peptide bioconjugates that were prepared by solid phase peptide synthesis (SPPS) techniques. The cymantrene complexes were chosen for their different linker to the peptide, to study the influence of the linker group on cellular uptake and cell viability of the conjugates. Interestingly, the attachment of the metal complex leads to a non-standard cleavage of the Rink amide linker used in the SPPS protocol under trifluoroacetic acid (TFA) treatment, resulting in peptide amides that are N-alkylated at the C-terminus. Furthermore, we found that depending on the type of cymantrene moiety attached, the formation of reactive carbocations which result from decomposition of the resin linker is facilitated and can alkylate the metal complex moiety. Both effects were analyzed by MS/MS studies and cleavage mixtures for efficient elimination of this byproduct formation were identified. Moreover, initial biological testing of the cytotoxicity of one of the bioconjugates gave promising results. Concentration-dependent cell viability studies of Cym1-sC18 on human MCF-7 breast adenocarcinoma cells gave an IC(50) value of 59.8 (+/- 6.7) microM and demonstrate their potential in anticancer chemotherapy.
Organometallic analogues of chloroquine show promise as new antimalarial agents capable of overcoming resistance to the parent drug chloroquine. Here, the synthesis and characterization of three new cymantrene (CpMn(CO)(3)) and cyrhetrene (CpRe(CO)(3)) 4-aminoquinoline conjugates with either an amine or amide linker are reported. The antimalarial activity of the new organometallic conjugates N-(2-(7-chloroquinolin-4-ylamino)ethyl)-4-cymantrenylbutanamide (3), N-(2-(7-chloroquinolin-4-ylamino)ethyl)-4-cyrhetrenylbutanamide (4) and N-(7-chloroquinolin-4-yl)-N'-(cymantrenylmethyl)ethane-1,2-diamine (6) was evaluated against a chloroquine-sensitive (CQS) and a chloroquine-resistant strain (CQR) of the malaria parasite Plasmodium falciparum. The cymantrene complex with an amine linker (6) showed good activity against the CQS strain but was inactive against the CQR strain. In contrast, cymantrene and cyrhetrene compounds with an amide linker were active against both the CQS and the CQR strain. In addition, the antibacterial, anti-trypanosomal and anti-leishmanial activity of the compounds was evaluated. Compound 6 showed submicromolar activity against Trypanosoma brucei at a concentration where the toxicity to normal human cells is low. No significant effect was noticed on the exchange of manganese for rhenium in the CpM(CO)(3) moiety in any of the biological assays.
Organometallic complexes conjugated to cell-penetrating peptides (CPPs) are promising systems for diagnostic imaging and therapeutic applications in human medicine. Recently, we reported on the synthesis of cymantrene(CpMn(CO)(3))-CPP conjugates with biological activity on different cancer cell lines. However, the precise mechanism of cytotoxicity remained elusive in these studies. To investigate the role of the metal center and the linker between the CpM(CO)(3) moiety and the peptide, a number of derivatives with manganese replaced by rhenium and the keto linker originally used substituted by a methylene group were prepared and fully characterized by (1)H NMR spectroscopy, infrared spectroscopy, electrospray ionization mass spectrometry, and elemental analysis as well as X-ray structure determination. The organometal-peptide conjugates as well as carboxyfluorescein-labeled derivatives thereof were prepared by solid-phase peptide synthesis, purified by high-performance liquid chromatography, and analyzed by mass spectrometry. Fluorescence microscopy studies of MCF-7 human breast cancer cells revealed an efficient cellular uptake and pronounced nuclear localization of the bioconjugates with the methylene linker compared with systems with the keto group. In addition, the latter also showed a higher cytotoxicity. In contrast, the variation of the metal center from manganese to rhenium had a negligible effect. The structure-activity relationships determined in the present work will aid in the further tuning of the biological activity of organometal-peptide conjugates.
Antimicrobial peptides are major components of the innate self-defence system and a large number of peptides have been designed to study the mechanism of action. In the present study, a small combinatorial library was designed to study whether the biological activity of Val/Arg-rich peptides is associated with targeted cell membranes. The peptides were produced by segregating hydrophilic residues on the polar side and hydrophobic residues on the opposite side. The peptides displayed strong antimicrobial activity against Gram-negative and Gram-positive bacteria, but weak haemolysis even at a concentration of 256 µM. CD spectra showed that the peptides formed α-helical-rich structure in the presence of negatively charged membranes. The tryptophan fluorescence and quenching experiments indicated that the peptides bound preferentially to negatively charged phospholipids over zwitterionic phospholipids, which corresponds well with the biological activity data. In the in vivo experiment, the peptide G6 decreased the bacterial counts in the mouse peritoneum and increased survival after 7 days. Overall, a high binding affinity with negatively charged phospholipids correlated closely with the cell selectivity of the peptides and some peptides in this study may be likely candidates for the development of antibacterial agents.
Short antimicrobial peptides were designed and synthesized by C-terminal truncation and residue substitution of avian β-defensin-4. The biological activity of these peptides was examined to elucidate the quantitative structure-activity relationships and find a lead peptide for the development of a novel antimicrobial peptide. The results showed that the truncation of the avian β-defensin-4 eliminated the hemolysis of the peptide. The GLI13 derivative, developed by substituting the Cys of the truncated peptide with Ile, led to increased antimicrobial activity. These results suggest that the peptides with antimicrobial activity can be derived by truncating the avian β-defensin-4. We further developed the GLI13 derivative with an increased net charge by residue substitution. The results showed that the GLI13-5 with 5 net charges had the highest cell selectivty. An increase in the net charge from 6 to 8 did not result in the improvement of antimicrobial potency. Membrane-simulating experiments showed that the peptides preferentially bound to negatively charged phospholipids over zwitterionic phospholipids, which led to greater cell selectivity. A membrane depolarization assay showed that GLI13-5 killed bacteria by targeting the cytoplasmic membrane. These results suggest that the short peptide developed by truncation of linear β-defensin may be a promising candidate for future antibacterial agents.
A novel α-helical antimicrobial peptide G6 rich in Val/Arg residues has been screened previously. In this study, we further evaluated the biochemical stability, interaction with whole bacteria, and in vivo therapeutic or prophylactic role of the peptide in Salmonella typhimurium-infected mice. The results showed that G6 exhibited strong resistance to pH, heat, and salts. But G6 lost the antimicrobial activity when treated with proteolytic enzymes. G6 had no toxicity on mammalian cell. An intraperitoneal model of sepsis caused by Salmonella typhimurium was established in mice. G6 was administered intraperitoneally 1 h before or after mice were infected with Salmonella typhimurium. For the mice given peptide post-bacterial infection, the mortality of the mice and the peritoneal bacterial counts were significantly lower in the groups that were administered 2.5 mg/kg BW and 5.0 mg/kg BW of G6 (P < 0.05) compared to the PBS-treated group. Similar trend was obtained when G6 was given 1 h prior to Salmonella typhimurium infection. Peptide-membrane experiments showed that G6 was effective in permeabilizing the outer and inner membrane in a dose dependent manner, indicating that the peptide targets the cell membrane. Taken together, the results revealed that the peptide G6 may provide a useful alternative to antibiotic agents to treat or prevent bacterial infections.
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