Pascal Prochnow

Analysis of the Mechanism of Action of Potent Antibacterial Hetero-tri-organometallic Compounds: A Structurally New Class of Antibiotics

Two hetero-tri-organometallic compounds with potent activity against Gram-positive bacteria including multi-resistant Staphylococcus aureus (MRSA) were identified. The compounds consist of a peptide nucleic acid backbone with an alkyne side chain, substituted with a cymantrene, a (dipicolyl)Re(CO)3 moiety, and either a ferrocene (FcPNA) or a ruthenocene (RcPNA). Comparative proteomic analysis indicates the bacterial membrane as antibiotic target structure. FcPNA accumulation in the membrane was confirmed by manganese tracing with atomic absorption spectroscopy. Both organometallics disturbed several essential cellular processes taking place at the membrane such as respiration and cell wall biosynthesis, suggesting that the compounds affect membrane architecture. Correlating with enhanced antibacterial activity, oxidative stress was induced only by the ferrocene-substituted compound. The organometallics described here target the cytoplasmic membrane, a clinically proven antibacterial target structure, feature a bactericidal but non-bacteriolytic mode of action and limited cytotoxicity within the limits of solubility. Thus, FcPNA represents a promising lead structure for the development of a new synthetic class of antibiotics.

Short Antibacterial Peptides with Significantly Reduced Hemolytic Activity can be Identified by a Systematic l-to-d Exchange Scan of their Amino Acid Residues

High systemic toxicity of antimicrobial peptides (AMPs) limits their clinical application to the treatment of topical infections; in parenteral systemic application of AMPs the problem of hemolysis is one of the first to be tackled. We now show that the selectivity of lipidated short synthetic AMPs can be optimized substantially by reducing their hemolytic activity without affecting their activity against methicillin resistant Staphylococcus aureus (MRSA). In order to identify the optimized peptides, two sets of 32 diastereomeric H-(D)Arg-WRWRW-(L)Lys(C(O)CnH2n+1)-NH2 (n = 7 or 9) peptides were prepared using a split-split procedure to perform a systematic L-to-D exchange scan on the central WRWRW-fragment. Compared to the all-L C8-lipidated lead sequence, diastereomeric peptides had very similar antibacterial properties, but were over 30 times less hemolytic. We show that the observed hemolysis and antibacterial activity is affected by both differences in lipophilicity of the different peptides and specific combinations of L- and D-amino acid residues. This study identified several peptides that can be used as tools to precisely unravel the origin of hemolysis and thus help to design even further optimized nontoxic very active short antibacterial peptides.

Highly active antibacterial ferrocenoylated or ruthenocenoylated Arg-Trp peptides can be discovered by an L-to-D substitution scan

The rapid increase in resistance against common antibiotics calls for the development of novel antibiotics, particularly against multi-resistant bacteria such as the methicillin-resistant Staphylococcus aureus (MRSA). In this work, the two group 8 metallocenoyl derivatives ferrocenoyl (FcC(O)-) or ruthenocenoyl (RcC(O)-) were attached to the N-terminus of two libraries of short antimicrobial peptides (AMPs), resulting in organometallic-AMP derivatives with as yet unparalleled antibacterial activities. In addition, these organometallic AMPs only cause limited lysis of human red blood cells (hRBCs). Our structure–activity relationship (SAR) study on these metallocenoylated peptides showed that specific combinations of L- and D-amino acid residues result in peptides with significantly improved antibacterial activity. Whereas the all-L FcC(O)-containing lead peptide had a MIC of 12 μM against MRSA, several peptides were found with MIC-values as low as 1.5–3 μM, a 4–8-fold increase in activity. For the RcC(O)-derivatized peptides a similar result was obtained: against MRSA a MIC value of 5.8 μM for the all-L peptide could be lowered to 0.7 μM, an 8-fold improvement. In addition, exposure of human red blood cells with 121 μM of the most active peptides led to a maximum hemolysis of 6%, indicating prominent selectivity that can be used to realize antibiotics based on organometallic-AMPs. We have hereby performed a systematic and highly successful SAR optimization against the two crucial parameters, i.e. antibacterial activity and hemolysis. Importantly, some of the RcC(O)-derivatized peptides presented here are among the most active antibacterial peptides; they approach or even exceed the activity of vancomycin.

Tuning the Activity of a Short Arg-Trp Antimicrobial Peptide by Lipidation of a C- or N-Terminal Lysine Side-Chain

The attachment of lipids to C- or N-terminally positioned lysine side-chain amino groups increases the activity of a short synthetic (Arg-Trp)3 antimicrobial peptide significantly, making these peptides even active against pathogenic Gram-negative bacteria. Thus, a peptide with strong activity against S. aureus (1.1-2 μM) and good activity against A. baumannii and P. aeruginosa (9-18 μM) was identified. The most promising peptide causes 50% hemolysis at 285 μM and shows some selectivity against human cancer cell lines. Interestingly, the increased activity of ferrocenoylated peptides is mostly due to the lipophilicity of the organometallic fragment.

Allicin Induces Thiol Stress in Bacteria through S-Allylmercapto Modification of Protein Cysteines.

Allicin (diallyl thiosulfinate) from garlic is a highly potent natural antimicrobial substance. It inhibits growth of a variety of microorganisms, among them antibiotic-resistant strains. However, the precise mode of action of allicin is unknown. Here, we show that growth inhibition of Escherichia coli during allicin exposure coincides with a depletion of the glutathione pool and S-allylmercapto modification of proteins, resulting in overall decreased total sulfhydryl levels. This is accompanied by the induction of the oxidative and heat stress response. We identified and quantified the allicin-induced modification S-allylmercaptocysteine for a set of cytoplasmic proteins by using a combination of label-free mass spectrometry and differential isotope-coded affinity tag labeling of reduced and oxidized thiol residues. Activity of isocitrate lyase AceA, an S-allylmercapto-modified candidate protein, is largely inhibited by allicin treatment in vivo. Allicin-induced protein modifications trigger protein aggregation, which largely stabilizes RpoH and thereby induces the heat stress response. At sublethal concentrations, the heat stress response is crucial to overcome allicin stress. Our results indicate that the mode of action of allicin is a combination of a decrease of glutathione levels, unfolding stress, and inactivation of crucial metabolic enzymes through S-allylmercapto modification of cysteines.

Influence of lipidation on the mode of action of a small RW-rich antimicrobial peptide.

Antimicrobial peptides are a potent class of antibiotics. In the Gram-positive model organism Bacillus subtilis the synthetic peptide RWRWRW-NH2 integrates into the bacterial membrane and delocalizes essential peripheral membrane proteins involved in cell wall biosynthesis and respiration. A lysine residue has been added to the hexapeptide core structure, either C or N-terminally. Lipidation of the lysine residues by a C8-acyl chain significantly improved antibacterial activity against both Gram-positive and Gram-negative bacteria. Here, we report a comparative proteomic study in B. subtilis on the mechanism of action of the lipidated and non-lipidated peptides. All derivatives depolarized the bacterial membrane without forming pores and all affected cell wall integrity. Proteomic profiling of the bacterial stress responses to the small RW-rich antimicrobial peptides was reflective of non-disruptive membrane integration. Overall, our results indicate that antimicrobial peptides can be derivatized with lipid chains enhancing antibacterial activity without significantly altering the mechanism of action. This article is part of a Special Issue entitled: Antimicrobial peptides edited by Karl Lohner and Kai Hilpert.

Synthesis and antibacterial activity of trivalent ultrashort Arg-Trp-based antimicrobial peptides (AMPs)

Multivalent display of identical ultrashort (only 2–3 amino acids long) antimicrobial peptides (AMPs) was used in order to create potential new antimicrobial agents. A series of small synthetic arginine and tryptophan containing peptides was synthesized and covalently bound to two different trivalent scaffold molecules using the copper(I)-catalyzed alkyne–azide cycloaddition (CuAAC) reaction. The effect of steric preorganization of AMPs on the antibacterial activity was studied using a 1,3,5-tris(azidomethyl)benzene and a 1,3,5-tris(azidomethyl)-2,4,6-triethylbenzene substituted scaffold. The comparison of these two scaffolds showed that preorganisation leads to at least twice as active compounds. We furthermore obtained a synergistic effect and could show that the presence of a certain number of amino acids in close proximity is more important than their relative spatial orientation.

Influence of the Multivalency of Ultrashort Arg-Trp-Based Antimicrobial Peptides (AMP) on Their Antibacterial Activity

Peptide dendrimers are a class of molecules of high interest in the search for new antibiotics. We used microwave‐assisted, copper(I)‐catalyzed alkyne–azide cycloaddition (CuAAC; “click” chemistry) for the simple and versatile synthesis of a new class of multivalent antimicrobial peptides (AMPs) containing solely arginine and tryptophan residues. To investigate the influence of multivalency on antibacterial activity, short solid‐phase‐ synthesized azide‐modified Arg‐Trp‐containing peptides were “clicked” to three different alkyne‐modified benzene scaffolds to access scaffolds with one, two, or three peptides. The antibacterial activity of 15 new AMPs was investigated by minimal inhibitory concentration (MIC) assays on five different bacterial strains, including a multidrug‐resistant Staphylococcus aureus (MRSA) strain. With ultrashort (2–3 residues) peptides, a clear synergistic effect of the trivalent display was observed, whereas this effect was not apparent with longer peptides. The best candidates showed activities in the low‐micromolar range against Gram‐positive MRSA. Surprisingly, the best activity against Gram‐negative Acinetobacter baumannii was observed with an ultrashort dipeptide on the trivalent scaffold (MIC: 7.5 μM). The hemolytic activity was explored for the three most active peptides. At concentrations ten times the MIC values, <1 % hemolysis of red blood cells was observed.

Purine biosynthesis is the bottleneck in trimethoprim-treated Bacillus subtilis.

Trimethoprim is a folate biosynthesis inhibitor. Tetrahydrofolates are essential for the transfer of C1 units in several biochemical pathways including purine, thymine, methionine, and glycine biosynthesis. This study addressed the effects of folate biosynthesis inhibition on bacterial physiology.

Towards Profiles of Resistance Development and Toxicity for the Small Cationic Hexapeptide RWRWRW-NH2.

RWRWRW-NH2 (MP196) is an amphipathic hexapeptide that targets the bacterial cytoplasmic membrane and inhibits cellular respiration and cell wall synthesis. In previous studies it showed promising activity against Gram-positive bacteria and no significant cytotoxicity or hemolysis. MP196 is therefore used as lead structure for developing more potent antibiotic derivatives. Here we present a more comprehensive study on the parent peptide MP196 with regard to clinically relevant parameters. We found that MP196 acts rapidly bactericidal killing 97% of initial CFU within 10 min at two times MIC. We were unable to detect resistance in standard 24 and 48 h resistance frequency assays. However, MP196 was effective against some but not all MRSA and VISA strains. Serum binding of MP196 was intermediate and we confirmed its low toxicity against mammalian cell lines. MP196 did neither induce NFκB activation nor cause an increase in IL8 levels at 250 μg/mL, and no IgE-dependent activation of basophil granulocytes was detected at 500 μg/mL. Yet, MP196 demonstrated acute toxicity in mice upon injection into the blood stream. Phase contrast microscopy of mouse blood treated with MP196 revealed a shrinking of erythrocytes at 250 μg/mL and severe morphological changes and lysis of erythrocytes at 500 μg/mL. These data suggest that MP196 derivatization directed at further lowering hemolysis could be instrumental in overcoming acute toxicity. The assessment of hemolysis is a critical step in the evaluation of the clinical potential of promising antimicrobial peptides and should be accompanied by microscopy-based morphological analysis of blood cells.