Targeted antimicrobial peptides.

The existence of natural antimicrobial substances, contributing to the mechanisms of host defenses, has been recognized since the late nineteenth century. In 1963, the in vitro antibacterial activity of leukocyte extracts was attributed to basic proteins. Since the late 1980s, cationic peptides with antimicrobial properties have been subsequently identified in other host cells and tissues and in virtually every living species (Lehrer, 2004). The properties of these “Nature’s antibiotics” and their multiple functions in host defenses of multicellular organisms support the rationale of developing entirely novel peptide-based therapeutics harnessing the effector mechanisms of innate immunity (Hancock and Sahl, 2006). The term antimicrobial peptides covers different forms of natural macromolecules; ribosomally synthesized and non-post translationally modified innate immunity peptides, or their synthetic analogs, are predominantly considered here. Their antimicrobial and immunomodulatory activities will not be dissociated in general and they will be indistinctively described as (cationic) antimicrobial or host defense peptides.</p

Pre-professional international mobility of European pharmacy students - a French example.

Internationalisation, as well as the need to interact with international partners in academia and in the pharmaceutical industry, brings an international experience to the pharmacist's career, which is essential. The objective of present work is to provide a preliminary study of the current situation of the pre-professional mobility of pharmacy students. It represents the first case study of the international pre-professional mobility of pharmacy students in France, and in north-eastern France in particular. The study is based on a recent preliminary survey among pharmacy students, conducted in 2020 at the University of Lorraine's Faculty of Pharmacy, reflecting the impact of international mobility programmes, such as the European Union educational and training mobility programme Erasmus+, on the pharmacy curriculum. The results of the present work tend to show that, despite a number of barriers to the international mobility of pharmacy students, the outcomes of international pre-professional mobility are rather positive in their globality

Pre-professional international mobility of European pharmacy students - a French example.

Internationalisation, as well as the need to interact with international partners in academia and in the pharmaceutical industry, brings an international experience to the pharmacist's career, which is essential. The objective of present work is to provide a preliminary study of the current situation of the pre-professional mobility of pharmacy students. It represents the first case study of the international pre-professional mobility of pharmacy students in France, and in north-eastern France in particular. The study is based on a recent preliminary survey among pharmacy students, conducted in 2020 at the University of Lorraine's Faculty of Pharmacy, reflecting the impact of international mobility programmes, such as the European Union educational and training mobility programme Erasmus+, on the pharmacy curriculum. The results of the present work tend to show that, despite a number of barriers to the international mobility of pharmacy students, the outcomes of international pre-professional mobility are rather positive in their globality

Beyond conventional antibiotics for the future treatment of methicillin-resistant Staphylococcus aureus infections: two novel alternatives.

The majority of antibiotics currently used to treat methicillin-resistant Staphylococus aureus (MRSA) infections target bacterial cell wall synthesis or protein synthesis. Only daptomycin has a novel mode of action. Reliance on limited targets for MRSA chemotherapy, has contributed to antimicrobial resistance. Two alternative approaches to the treatment of S. aureus infection, particularly those caused by MRSA, that have alternative mechanisms of action and that address the challenge of antimicrobial resistance are cationic host defence peptides and agents that target S. aureus virulence. Cationic host defence peptides have multiple mechanisms of action and are less likely than conventional agents to select resistant mutants. They are amenable to modifications that improve their stability, effectiveness and selectivity. Some cationic defence peptides such as bactenecin, mucroporin and imcroporin have potent in vitro bactericidal activity against MRSA. Antipathogenic agents also have potential to limit the pathogenesis of S aureus. These are generally small molecules that inhibit virulence targets in S. aureus without killing the bacterium and therefore have limited capacity to promote resistance development. Potential antipathogenic targets include the sortase enzyme system, the accessory gene regulator (agr) and the carotenoid biosynthetic pathway. Inhibitors of these targets have been identified and these may have potential for further development.</p

Computational survey of peptides derived from disulphide-bonded protein loops that may serve as mediators of protein-protein interactions.

BACKGROUND: Bioactive cyclic peptides derived from natural sources are well studied, particularly those derived from non-ribosomal synthetases in fungi or bacteria. Ribosomally synthesised bioactive disulphide-bonded loops represent a large, naturally enriched library of potential bioactive compounds, worthy of systematic investigation. RESULTS: We examined the distribution of short cyclic loops on the surface of a large number of proteins, especially membrane or extracellular proteins. Available three-dimensional structures highlighted a number of disulphide-bonded loops responsible for the majority of the likely binding interactions in a variety of protein complexes, due to their location at protein-protein interfaces. We find that disulphide-bonded loops at protein-protein interfaces may, but do not necessarily, show biological activity independent of their parent protein. Examining the conservation of short disulphide bonded loops in proteins, we find a small but significant increase in conservation inside these loops compared to surrounding residues. We identify a subset of these loops that exhibit a high relative conservation, particularly among peptide hormones. CONCLUSIONS: We conclude that short disulphide-bonded loops are found in a wide variety of biological interactions. They may retain biological activity outside their parent proteins. Such structurally independent peptides may be useful as biologically active templates for the development of novel modulators of protein-protein interactions.</p

Ciprofloxacin as a tryptophan mimic within an antimicrobial peptide

Ciprofloxacin has been used to replace tryptophan at positions 3 and 6 in the antimicrobial peptide (AMP) Bac8c. Bac8c(Cip3,6) showed comparable antimicrobial activity but increased selectivity toward some Gram-negative bacteria with MIC values of r6.25 lM. Bac8c(Cip3,6) was also non cytotoxic to cultured HepG2 cells at antimicrobial concentrations, with a CC50 4300 lM.</p

Platinum(iv) oxaliplatin-peptide conjugates targeting memHsp70+ phenotype in colorectal cancer cells.

Novel Pt(iv) tumour penetrating peptide (TPP) conjugates are reported. They are the first example of metallodrugs to target a membrane bound heat shock protein 70 positive (memHSP70+) phenotype in cancer cells. The conjugates exhibit superior cytotoxicity as compared to oxaliplatin alone in Pt resistant colorectal cancer cells with relatively high memHSP70+ expression. Substitution of TPP in Pt(iv) peptide conjugates with scrambled peptide (ScP) essentially abolishes the observed cytotoxicity.</p

Synthesis and characterisation of a novel mono functionalisable Pt(IV) oxaliplatin-type complex and its peptide conjugate

The synthesis and characterisation of a novel Pt(IV) monocarboxy precursor complex c,c,t-[Pt(DACH)(Ox)(OEt)(Suc)], which can be employed to synthesise mono functionalised Pt(IV) oxaliplatin-based complexes is reported. Reaction of c,c,t-[Pt(DACH)(Ox)(OEt)(Suc)] with a tumour penetrating peptide, TPP, afforded the corresponding novel monofunctionalised Pt(IV) peptide conjugate c,c,t-[Pt(DACH)(Ox)(OEt)(SucTPP)] in high purity. Conjugation of TPP to c,c,t-[Pt(DACH)(Ox)(OEt)(Suc)] was demonstrated to ameliorate its inherent cytotoxicity fifteen fold in the Pt sensitive HCT116 colorectal cancer cell line and two fold in the relatively resistant HT29 colorectal cancer cell line

Action of antimicrobial peptides and their prodrugs on model and biological membranes.

Antimicrobial peptides (AMPs) are promising broad-spectrum antibiotic candidates in the wake of multi-drug resistant pathogens. Their clinical use still requires a solution based on lead optimisation and/or formulation to overcome certain limitations, such as unwanted cytotoxicity. A prodrug approach could overcome this safety barrier and can be achieved through reversible reduction or neutralisation of the AMPs' net cationic charge. By prodrug activation through pathogen associated enzymes, this approach could increase the therapeutic index of membrane active peptides. P18, a cecropin/magainin hybrid, and WMR, a myxinidin analogue from hagfish, were used as templates for the design strategy. The membrane permeabilizing activities of these AMPs and their prodrugs are reported here for liposomes of either Escherichia coli polar lipid extract or a human model lipid system of phosphatidylcholine and cholesterol. These results are compared with their antibacterial and haemolytic activities. Overall, correlation between liposome permeabilization and the corresponding bioactivity is observed and indicate that the broad-spectrum antibacterial effect exerted by these peptides is associated with membrane disruption. Furthermore, the prodrug modification had a general negative influence on membrane disruption and bioactivity, notably as much on bacterial as on human membranes. This prodrug strategy is particularly successful when complete neutralisation of the AMP's net charge occurs. Thus, on-target selectivity between bacterial and human membranes can be improved, which may be used to prevent the unnecessary exposure of host cells and commensal bacteria to active AMPs.</p

Action of antimicrobial peptides and their prodrugs on model and biological membranes.

Antimicrobial peptides (AMPs) are promising broad-spectrum antibiotic candidates in the wake of multi-drug resistant pathogens. Their clinical use still requires a solution based on lead optimisation and/or formulation to overcome certain limitations, such as unwanted cytotoxicity. A prodrug approach could overcome this safety barrier and can be achieved through reversible reduction or neutralisation of the AMPs' net cationic charge. By prodrug activation through pathogen associated enzymes, this approach could increase the therapeutic index of membrane active peptides. P18, a cecropin/magainin hybrid, and WMR, a myxinidin analogue from hagfish, were used as templates for the design strategy. The membrane permeabilizing activities of these AMPs and their prodrugs are reported here for liposomes of either Escherichia coli polar lipid extract or a human model lipid system of phosphatidylcholine and cholesterol. These results are compared with their antibacterial and haemolytic activities. Overall, correlation between liposome permeabilization and the corresponding bioactivity is observed and indicate that the broad-spectrum antibacterial effect exerted by these peptides is associated with membrane disruption. Furthermore, the prodrug modification had a general negative influence on membrane disruption and bioactivity, notably as much on bacterial as on human membranes. This prodrug strategy is particularly successful when complete neutralisation of the AMP's net charge occurs. Thus, on-target selectivity between bacterial and human membranes can be improved, which may be used to prevent the unnecessary exposure of host cells and commensal bacteria to active AMPs.</p