The quorum sensing peptide EntF* promotes colorectal cancer metastasis in mice: a new factor in the host-microbiome interaction.

BACKGROUND: Colorectal cancer, one of the most common malignancies worldwide, is associated with a high mortality rate, mainly caused by metastasis. Comparative metagenome-wide association analyses of healthy individuals and cancer patients suggest a role for the human intestinal microbiota in tumor progression. However, the microbial molecules involved in host-microbe communication are largely unknown, with current studies mainly focusing on short-chain fatty acids and amino acid metabolites as potential mediators. Quorum sensing peptides are not yet considered in this context since their presence in vivo and their ability to affect host cells have not been reported so far. RESULTS: Here, we show that EntF*, a metabolite of the quorum sensing peptide EntF produced by Enterococcus faecium, is naturally present in mice bloodstream. Moreover, by using an orthotopic mouse model, we show that EntF* promotes colorectal cancer metastasis in vivo, with metastatic lesions in liver and lung tissues. In vitro tests suggest that EntF* regulates E-cadherin expression and consequently the epithelial-mesenchymal transition, via the CXCR4 receptor. In addition, alanine-scanning analysis indicates that the first, second, sixth, and tenth amino acid of EntF* are critical for epithelial-mesenchymal transition and tumor metastasis. CONCLUSION: Our work identifies a new class of molecules, quorum sensing peptides, as potential regulators of host-microbe interactions. We prove, for the first time, the presence of a selected quorum sensing peptide metabolite in a mouse model, and we demonstrate its effects on colorectal cancer metastasis. We believe that our work represents a starting point for future investigations on the role of microbiome in colorectal cancer metastasis and for the development of novel bio-therapeutics in other disease areas.

Effect of Amino Acid Substitutions on 70S Ribosomal Binding, Cellular Uptake, and Antimicrobial Activity of Oncocin Onc112.

Proline-rich antimicrobial peptides (PrAMPs) are promising candidates for the treatment of infections caused by high-priority human pathogens. Their mode of action consists of (I) passive diffusion across the outer membrane, (II) active transport through the inner membrane, and (III) inhibition of protein biosynthesis by blocking the exit tunnel of the 70S ribosome. We tested whether in vitro data on ribosomal binding and bacterial uptake could predict the antibacterial activity of PrAMPs against Gram-negative and Gram-positive bacteria. Ribosomal binding and bacterial uptake rates were measured for 47 derivatives of PrAMP Onc112 and compared to the minimal inhibitory concentrations (MIC) of each peptide. Ribosomal binding was evaluated for ribosome extracts from four Gram-negative bacteria. Bacterial uptake was assessed by quantifying each peptide in the supernatants of bacterial cultures. Oncocin analogues with a higher net positive charge appeared to be more active, although their ribosome binding and uptake rates were not necessarily better than for Onc112. The data suggest a complex mode of action influenced by further factors improving or reducing the antibacterial activity, including diffusion through membranes, transport mechanism, secondary targets, off-target binding, intracellular distribution, and membrane effects. Relying only on in vitro binding and uptake data may not be sufficient for the rational development of more active analogues.

Simultaneous Chromatographic Quantitation of Drug Substance and Excipients in Nanoformulations Using a Combination of Evaporative Light Scattering and Absorbance Detectors.

Nanomedicines including lipid- and polymer-based nanoparticles and polymer-drug conjugates enable targeted drug delivery for the treatment of numerous diseases. Quantitative analysis of components in nanomedicines is routinely performed to characterize the products to ensure quality and property consistency but has been mainly focused on the active pharmaceutical ingredients (APIs) in academic publications. It has been increasingly recognized that excipients in nanomedicines are critical in determining the product quality, stability, consistency, and safety. APIs are often analyzed by high-performance liquid chromatography (HPLC), and it would be convenient if the same method can be applied to excipients to robustly quantify all components in nanomedicines. Here, we report the development of a HPLC method that combined an evaporative light scattering (ELS) detector with an UV-vis detector to simultaneously analyze drugs and excipients in nanomedicines. This method was tested on diverse nanodrug delivery systems, including a niosomal nanoparticle encapsulating a phytotherapeutic, a liposome encapsulating an immune boosting agent, and a PEGylated peptide. This method can be utilized for a variety of applications, such as monitoring drug loading, studying drug release, and storage stability. The information obtained from the analyses is of importance for nanomedicine formulation development.

Solid-phase synthesis of D-fructose-derived Heyns peptides utilizing Nα-Fmoc-Lysin[Nε-(2-deoxy-D-glucos-2-yl),Nε-Boc]-OH as building block.

Aldoses and ketoses can glycate proteins yielding isomeric Amadori and Heyns products, respectively. Evidently, D-fructose is more involved in glycoxidation than D-glucose favoring the formation of advanced glycation endproducts (AGEs). While Amadori products and glucation have been studied extensively, the in vivo effects of fructation are largely unknown. The characterization of isomeric Amadori and Heyns peptides requires sufficient quantities of pure peptides. Thus, the glycated building block Nα-Fmoc-Lys[Nε-(2-deoxy-D-glucos-2-yl),Nε-Boc]-OH (Fmoc-Lys(Glc,Boc)-OH), which was synthesized in two steps starting from unprotected D-fructose and Fmoc-L-lysine hydrochloride, was site-specifically incorporated during solid-phase peptide synthesis. The building block allowed the synthesis of a peptide identified in tryptic digests of human serum albumin containing the reported glycation site at Lys233. The structure of the glycated amino acid derivatives and the peptide was confirmed by mass spectrometry and NMR spectroscopy. Importantly, the unprotected sugar moiety showed neither notable epimerization nor undesired side reactions during peptide elongation, allowing the incorporation of epimerically pure glucosyllysine. Upon acidic treatment, the building block as well as the resin-bound peptide formed one major byproduct due to incomplete Boc-deprotection, which was well separated by reversed-phase chromatography. Expectedly, the tandem mass spectra of the fructated amino acid and peptide were dominated by signals indicating neutral losses of 18, 36, 54, 84 and 96 m/z-units generating pyrylium and furylium ions.

Ribosomal Target-Binding Sites of Antimicrobial Peptides Api137 and Onc112 Are Conserved among Pathogens Indicating New Lead Structures To Develop Novel Broad-Spectrum Antibiotics.

Proline-rich antimicrobial peptides expressed in insects are primarily active against Enterobacteriaceae. Mechanistically, they target the bacterial (70S) ribosome after partially transporter-based cellular uptake, as revealed for Api137 and Onc112 on Escherichia coli. Following molecular modeling indicating that the Onc112 contact site is conserved among the ribosomes of high-priority pathogens, the ribosome binding of Api137 and Onc112 was studied. The dissociation constants (Kd ) of Onc112 were ∼75 nmol/L for Escherichia coli, Klebsiella pneumoniae, and Acinetobacter baumannii, 36 nmol/L for Pseudomonas aeruginosa, and 102 nmol/L for Staphylococcus aureus, thus indicating a very promising lead structure for developing broad-spectrum antibiotics. Api137 bound weaker with Kd values ranging from 155 nmol/L to 13 µmol/L. For most bacteria, the antibacterial activities were lower than predicted from the Kd values, which was only partially explained by their ability to enter bacterial cells. Other factors limiting the activity expected from the ribosome binding might be off-target binding.

Proline-rich antimicrobial peptides show a long-lasting post-antibiotic effect on Enterobacteriaceae and Pseudomonas aeruginosa.

Background: Proline-rich antimicrobial peptides (PrAMPs) represent a promising class of potential therapeutics to treat multiresistant infections. They inhibit bacterial protein translation at the 70S ribosome by either blocking the peptide-exit tunnel (oncocin type) or trapping release factors (apidaecin type). Objectives: Besides direct concentration-dependent antibacterial effects, the post-antibiotic effect (PAE) is the second most important criterion of antimicrobial pharmacodynamics to be determined in vitro. Here, PAEs of 10 PrAMPs and three antibiotics against three Escherichia coli strains, Klebsiella pneumoniae ATCC 10031 and Pseudomonas aeruginosa ATCC 27853 were studied after 1 h of exposure. Methods: A robust high-throughput screening to determine PAEs was established, i.e. liquid handling by a 96-channel pipetting system and continuous incubation and absorbance measurement in a microplate reader. Results: Prolonged PAEs (≥4 h) were detected for all peptides at their MIC values against all strains; PAEs were even >10 h for Api88, Api137, Bac7(1-60) and A3-APO. The PAEs increased further at 4 × MIC. Aminoglycosides gentamicin and kanamycin usually showed lower PAEs (≤4 h) at MIC, but PAEs increased to > 10 h at 4 × MIC. Bacteriostatic chloramphenicol exhibited the shortest PAEs (<4 h). Conclusions: The PAEs of PrAMPs studied against Enterobacteriaceae and P. aeruginosa for the first time were typically 4-fold stronger than for conventional antibiotics. Together with their fast and irreversible uptake by bacteria, the observed prolonged PAE of PrAMPs helps to explain their high in vivo efficacy despite unfavourable pharmacokinetics.

iSPAAC: Isomer-Free Generation of a Bcl-xL -Inhibitor in Living Cells.

Strain-promoted azide-alkyne cycloadditions (SPAAC) have proven extremely useful for labeling of biomolecules, but typically produce isomeric mixtures. This is not appropriate for the formation of bioactive molecules in living cells. Here, the first use of SPAAC for the isomer-free synthesis of a bioactive molecule is reported both in vitro and inside cultured cells. We developed the symmetrical cyclooctyne SYPCO and used it for the generation of a chemically uniform triazole inhibitor of protein-protein interactions mediated by Bcl-xL via isomer-free SPAAC (iSPAAC). Tumor cells treated with the reactants of the iSPAAC reaction contained higher concentrations of triazole, and displayed higher apoptosis levels, than cells treated with pre-synthesized triazole. We envision iSPAAC as a broadly applicable method for modulating intracellular targets with organic molecules with molecular weights prohibitively large for cellular uptake, via smaller and thus more cell-permeable components.

Correlating uptake and activity of proline-rich antimicrobial peptides in Escherichia coli.

Increasing death tolls accounted for by antimicrobial drug resistance demand novel antibiotic lead compounds. Among different promising candidate classes, proline-rich antimicrobial peptides (PrAMPs) are very favorable due to their intracellular mechanism, i.e., binding to the 70S ribosome and DnaK, after active uptake relying on bacterial transporters like SbmA and MdtM. Studies on peptide internalization as the first step of their complex mode of action rely typically on fluorophore or radioactive labeling and quantification using microscopy, flow cytometry, or radioactivity. Here, a liquid chromatography based assay was applied to quantify the unlabeled internalized full-length peptides and their proteolytic degradation products (metabolites) using UV absorbance and mass spectrometry. Knockout mutants lacking transporter proteins showed reduced PrAMP uptakes, explaining their reduced susceptibility against PrAMPs. Interestingly, major metabolites produced by bacterial proteases still bound to the 70S ribosome provide evidence that degradation by cytosolic proteases as a possible resistance mechanism is not very efficient. Graphical abstract The uptake of unlabeled proline-rich antimicrobial peptides (PrAMPs) is analyzed in Escherichia coli BW25113 wild-type and transporter knockout mutants ΔsbmA and BS2 (ΔsbmA yjiL::Tn10) by reversed-phase chromatography and quantified by UV detection or mass spectrometry with multi-reaction monitoring (scheme right). Internalized peptide amounts correlated to minimal inhibitory concentrations and bacterial transport activities based on the present transporter proteins (scheme left).

Identification of New Resistance Mechanisms in Escherichia coli against Apidaecin 1b Using Quantitative Gel- and LC-MS-Based Proteomics.

Bacteria have acquired resistance mechanisms to overcome antibiotic treatments, triggering major concerns about the return of epidemic infections. Antimicrobial peptides identified in insects, animals, and plants represent a huge pool of promising lead structures that can be further developed for medical applications. Short proline-rich antimicrobial peptides (PrAMPs) have gained much attention due to their clinically interesting activity spectrum, serum protease stability, efficacy in murine infection models, and low adverse effects. Here we induced resistances by incubating Escherichia coli with increasing concentrations of apidaecin 1b, a PrAMP isolated from honeybees, and quantitatively evaluated the proteomes between wild-type and resistant strains. Surprisingly, 2D differential gel electrophoresis did not reveal differences, indicating that the expression levels of dominant proteins were very similar. Reversed-phase chromatography coupled online to a mass spectrometer identified 2131 proteins in the soluble fraction (cytosolic fraction) and 1296 proteins in the nonsolubilized pellet (membrane fraction). Overall 29 proteins showed a statistically significant upregulation in the resistant E. coli strain, whereas 18 proteins were downregulated. Interestingly, periplasmic chaperone FimC, fimbrial protein FimA, and mannose-binding domain protein FimH, which are part of the fimbrial complex, were not detected in the resistant strain that was also unable to form biofilms. Furthermore, the expression of a few other proteins known as virulence factors was downregulated. Additionally, the expression level of isochorismatase hydrolase (YcaC) decreased in the membrane fraction of the resistant strain to 35%, and the corresponding knockout mutant of E. coli BW25113 was eight times less susceptible to apidaecin 1b and the related designer peptide Api88.

Development of Bifunctional Inhibitors of Polo-Like Kinase†1 with Low-Nanomolar Activities Against the Polo-Box Domain.

Polo-like kinase 1 (Plk1), a validated cancer target, harbors a protein-protein interaction domain referred to as the polo-box domain (PBD), in addition to its enzymatic domain. Although functional inhibition either of the enzymatic domain or of the PBD has been shown to inhibit Plk1, so far there have been no reports of bifunctional agents with the potential to target both protein domains. Here we report the development of Plk1 inhibitors that incorporate both an ATP-competitive ligand of the enzymatic domain, derived from BI 2536, and a functional inhibitor of the PBD, based either on the small molecule poloxin-2 or on a PBD-binding peptide. Although these bifunctional agents do not seem to bind both protein domains simultaneously, the most potent compound displays low-nanomolar activity against the Plk1 PBD, with excellent selectivity over the PBDs of Plk2 and Plk3. Our data provide insights into challenges and opportunities relating to the optimization of Plk1 PBD ligands as potent Plk1 inhibitors.

Pharmacokinetics and in vivo efficacy of optimized oncocin derivatives.

OBJECTIVES: To evaluate the efficacy of antimicrobial peptide Onc112 in a lethal Escherichia coli infection model and the pharmacokinetics of Onc72 and Onc112 administered intravenously or intraperitoneally in mice. METHODS: Onc72, Onc112 and their major metabolites in blood, kidneys, liver, brain and urine were quantified by MS using multiple reaction monitoring (MRM) and isotope-labelled peptides. RESULTS: Onc112 rescued all animals when administered intraperitoneally at a dose of 2.5 mg/kg and was thus slightly more efficient than Onc72. The MRM method provided limits of quantification in plasma, urine and kidney, liver and brain homogenates of 7-80 µg/L, well below the MICs of 2-4 mg/L. Onc72 and Onc112 reached all organs within 10 min when administered intraperitoneally (5 mg/kg). Their initial concentrations in plasma were 11.9 and 22.6 mg/L, respectively, with elimination t1/2 values of ∼14 and 21 min. The peptide concentrations in blood remained above their MICs for 20 min for Onc72 and 80 min for Onc112. The highest peptide concentrations were detected in kidney homogenates, which also contained the highest content of metabolites, indicating, together with the results from analysis of urine samples, that both peptides are cleared through the kidneys. CONCLUSIONS: Onc72 and Onc112 reach organs, including the brain, within 10 min after intravenous and intraperitoneal administration. Onc112 remained in blood at concentrations above its MIC for 80 min. The pharmacokinetic profiles explain the high in vivo efficacies in models of systemic infection and indicate the potential use of these agents for the treatment of urinary tract infections.

Optimization of oncocin for antibacterial activity using a SPOT synthesis approach: extending the pathogen spectrum to Staphylococcus aureus.

The identification of lead molecules against multidrug-resistant bacteria ensuing the development of novel antimicrobial drugs is an urgent task. Proline-rich antimicrobial peptides are highly active in vitro and in vivo, but only against a few Gram-negative human pathogens, with rather weak activities against Pseudomonas aeruginosa and Staphylococcus aureus. This reduced level of efficacy could be related to inadequate uptake mechanisms or structural differences of the intracellular target proteins, i.e., the 70S ribosome or chaperone DnaK. Here we synthesized peptide arrays on cellulose membranes using cleavable linkers to release the free individual peptides for further antimicrobial tests. Thus, a library of singly substituted oncocin analogs was produced by replacing each residue by all other 19 canonical amino acids yielding a set of 361 individual peptides to be evaluated against a luminescent P. aeruginosa strain. Thirteen substitutions appeared promising and their improved antibacterial activities were confirmed for different bacteria after larger scale synthesis of these analogs. By combining two favorable substitutions into one peptide, we finally obtained an oncocin analog that was ten times more active against P. aeruginosa and even 100-fold more active against S. aureus than the original oncocin, providing minimal inhibitory concentrations of 4-8 and 0.5 µg/mL, respectively.

Ribosomal binding and antibacterial activity of ethylene glycol-bridged apidaecin Api137 and oncocin Onc112 conjugates.

Recent surveillance data on antimicrobial resistance predict the beginning of the post-antibiotic era with pan-resistant bacteria even overcoming polymyxin as the last available treatment option. Thus, new substances using novel modes of antimicrobial action are urgently needed to reduce this health threat. Antimicrobial peptides are part of the innate immune system of most vertebrates and invertebrates and accepted as valid substances for antibiotic drug development efforts. Especially, short proline-rich antimicrobial peptides (PrAMP) of insect origin have been optimized for activity against Gram-negative strains. They inhibit protein expression in bacteria by blocking the 70S ribosome exit tunnel (oncocin-type) or the assembly of the 50S subunit (apidaecin-type binding). Thus, apidaecin analog Api137 and oncocin analog Onc112 supposedly bind to different nearby or possibly partially overlapping binding sites. Here, we synthesized Api137/Onc112-conjugates bridged by ethylene glycol spacers of different length to probe synergistic activities and binding modes. Indeed, the antimicrobial activities against Escherichia coli and Pseudomonas aeruginosa improved for some constructs, although the conjugates did not bind better to the 70S ribosome of E. coli than Api137 and Onc112 using 5(6)-carboxyfluorescein-labelled Api137 and Onc112 in a competitive fluorescence polarization assay. In conclusion, Api137/Onc112-conjugates showed increased antimicrobial activities against P. aeruginosa and PrAMP-susceptible and -resistant E. coli most likely because of improved membrane interactions, whereas the interaction to the 70S ribosome was most likely not improved relying still on the independent apidaecin- and oncocin-type binding modes. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.

Identification of Api88 Binding Partners in Escherichia coli Using a Photoaffinity-Cross-Link Strategy and Label-Free Quantification.

Gene-encoded antimicrobial peptides (AMPs) kill bacteria very efficiently by either lytic mechanisms or inhibition of specific bacterial targets. Proline-rich AMPs (PrAMPs), for example, produced in insects and mammals rely on the second mechanism. They bind to the 70 kDa bacterial heat shock protein DnaK and the 60 kDa chaperonin GroEL and interfere with protein folding, but this does not explain their strong bactericidal effects. Thus, we looked for further binding partners of apidaecin 1b, originally identified in honey bees, and two rationally optimized analogues (Api88 and Api137). Because affinity chromatography using Api88 as an immobilized ligand enriched only a few proteins at low levels besides DnaK, we synthesized Api88 analogues substituting Tyr7 with p-benzoyl-phenylalanine (Bpa), which can cross-link the peptide to binding partners after UV irradiation. Escherichia coli was incubated with biotinylated Api88 Tyr7Bpa or the corresponding all-d-peptide, irradiated, and lysed. The protein extract was enriched by streptavidin, separated by SDS-PAGE, digested with trypsin, and analyzed by nanoRP-UPLC-ESI-QqTOF-MS/MS. Among the 41 proteins identified, 34 were detected only in the l-Api88 Tyr7Bpa sample, including five 70S ribosomal proteins, DNA-directed RNA polymerase, and pyruvate dehydrogenase, indicating that PrAMPs might interfere with protein translation and energy metabolism.

Influence of the yjiL-mdtM Gene Cluster on the Antibacterial Activity of Proline-Rich Antimicrobial Peptides Overcoming Escherichia coli Resistance Induced by the Missing SbmA Transporter System.

In view of increasing health threats from multiresistant pathogens, antimicrobial peptides (AMPs) and, specifically, proline-rich AMPs (PrAMPs) have been investigated in animal models. PrAMPs enter bacteria via the ABC transporter SbmA and inhibit intracellular targets. We used phage transduction (Tn10 insertion) to screen by random mutagenesis for alternative uptake mechanisms for analogs of apidaecin 1b, a honeybee-derived PrAMP. All 24 apidaecin-resistant mutants had the Tn10 insertion in the sbmA gene. These sbmA::Tn10 insertion mutants and the Escherichia coli BW25113 ΔsbmA (JW0368) strain were still susceptible to the bactenecin PrAMP Bac7(1-35) and oncocin PrAMPs Onc18 and Onc112, as well as to Chex1-Arg20, despite significantly reduced internalizations. In a second round of random mutagenesis, the remaining susceptibility was linked to the yjiL-mdtM gene cluster. E. coli BW25113 and its ΔyjiL null mutant (JW5785) were equally susceptible to all PrAMPs tested, whereas the BW25113 ΔmdtM mutant was less susceptible to oncocins. The JW0368 yjiL::Tn10 transposon mutant (BS2) was resistant to all short PrAMPs and susceptible only to full-length Bac7 and A3-APO. Interestingly, PrAMPs appear to enter bacteria via MdtM, a multidrug resistance transporter (drug/H(+) antiporter) of the major facilitator superfamily (MFS) that can efflux antibiotics, biocides, and bile salts. In conclusion, PrAMPs enter bacteria via ABC and MFS transporters that efflux antibiotics and cytotoxic compounds from the cytoplasm to the periplasm.

Short Proline-Rich Antimicrobial Peptides Inhibit Either the Bacterial 70S Ribosome or the Assembly of its Large 50S Subunit.

Short proline-rich antimicrobial peptides (PrAMPs) are a promising class of antibiotics that use novel mechanisms, thus offering the potential to overcome the health threat of multiresistant pathogens. The peptides bind to the bacterial 70S ribosome and can inhibit protein translation. We report that PrAMPs can be divided into two classes, with each class binding to a different site, and thus use different lethal mechanisms. Oncocin-type peptides inhibit protein translation in Escherichia coli by binding to the exit tunnel of the 70S ribosome with half maximal inhibitory concentrations (IC50 values) of around 2 to 6 µmol L(-1), whereas apidaecin-type peptides block the assembly of the large (50S) subunit of the ribosome, resulting in similar IC50 values. The revealed mechanisms should allow the design of new antibiotics to overcome current bacterial resistance mechanisms.

Epitope mapping of monoclonal antibody HPT-101: a study combining dynamic force spectroscopy, ELISA and molecular dynamics simulations.

By combining enzyme-linked immunosorbent assay (ELISA) and optical tweezers-assisted dynamic force spectroscopy (DFS), we identify for the first time the binding epitope of the phosphorylation-specific monoclonal antibody (mAb) HPT-101 to the Alzheimer's disease relevant peptide tau[pThr231/pSer235] on the level of single amino acids. In particular, seven tau isoforms are synthesized by replacing binding relevant amino acids by a neutral alanine (alanine scanning). From the binding between mAb HPT-101 and the alanine-scan derivatives, we extract specific binding parameters such as bond lifetime τ0, binding length x(ts), free energy of activation ΔG (DFS) and affinity constant K(a) (ELISA, DFS). Based on these quantities, we propose criteria to identify essential, secondary and non-essential amino acids, being representative of the antibody binding epitope. The obtained results are found to be in full accord for both experimental techniques. In order to elucidate the microscopic origin of the change in binding parameters, we perform molecular dynamics (MD) simulations of the free epitope in solution for both its parent and modified form. By taking the end-to-end distance d(E-E) and the distance between the α-carbons d(C-C) of the phosphorylated residues as gauging parameters, we measure how the structure of the epitope depends on the type of substitution. In particular, whereas d(C-C) is sometimes conserved between the parent and modified form, d(E-E) strongly changes depending on the type of substitution, correlating well with the experimental data. These results are highly significant, offering a detailed microscopic picture of molecular recognition.

Oncocin Onc72 is efficacious against antibiotic-susceptible Klebsiella pneumoniae ATCC 43816 in a murine thigh infection model.

Oncocins and apidaecins are short proline-rich antimicrobial peptides (PrAMPs) representing novel antibiotic drug lead compounds that kill bacteria after internalization and inhibition of intracellular targets (e.g. 70S ribosome and DnaK). Oncocin Onc72 is highly active against Gram-negative bacteria in vitro and in vivo protecting mice in systemic infection models with Escherichia coli and KPC-producing Klebsiella pneumoniae. Here we studied its efficacy in a murine thigh infection model using meropenem as antibiotic comparator that had a 44-fold higher molar in vitro activity than Onc72. Male CD1 mice were rendered neutropenic using cyclophosphamide for four days before intramuscular infection with K. pneumoniae ATCC 43816. After 75 min oncocin Onc72 or the antibiotic comparator meropenem were administered subcutaneously with 100 mg (43 µmol) and 25 mg (65 µmol) per kg of body weight, respectively, six times every 75 min. Onc72 and meropenem administered subcutaneously reduced the thigh tissue burden of K. pneumoniae ATCC 43816 in neutropenic mice significantly by 4.14 and 4.65 a log10 cfu/g, respectively. The bacterial counts were ∼0.5 and ∼1 log10 below the pre-treatment burden, respectively, indicating bactericidal effects for both compounds. Thus, Onc72 was as efficacious as meropenem in vivo despite its much lower in vitro activity determined according to CLSI standard antimicrobial activity tests.

Optimization of adiponectin-derived peptides for inhibition of cancer cell growth and signaling.

Adiponectin, an adipose tissue-excreted adipokine plays protective roles in metabolic and cardiovascular diseases and exerts anti-cancer activities, partially by interfering with leptin-induced signaling. Previously we identified the active site in the adiponectin protein, and generated both a nanomolar monomeric agonist of the adiponectin receptor (10-mer ADP355) and an antagonist (8-mer ADP400) to modulate various adiponectin receptor-mediated cellular functions. As physiologically circulating adiponectin forms multimeric complexes, we also generated an agonist dimer with improved biodistribution and in vitro efficacy. In the current report, we attempted to optimize the monomeric agonist structure. Neither extension of the peptide up to 14-mer analogs nor reinstallation of native residues in permissible positions enhanced significantly the activity profile. The only substitutions that resulted in 5-10-fold improved agonistic activity were the replacement of turn-forming Gly4 and Tyr7 residues with Pro and Hyp, respectively, yielding the more active native ß-sheet structure. All peptides retained good stability in human serum exhibiting half-lives >2 h. The cellular efficacy and stability rankings among the peptides followed expected structure-activity relationship trends. To investigate whether simultaneous activation of adiponectin pathways and inhibition of leptin-induced signals can result in cytostatic and anti-oncogenic signal transduction processes, we developed a chimera of the leptin receptor antagonist peptide Allo-aca (placed to the N-terminus) and ADP355 (at the C-terminus). The in vitro anti-tumor activity and intracellular signaling of the chimera were dominated by the more active Allo-aca component. The ADP355 part, however, reversed unfavorable in vivo metabolic effects of the leptin receptor antagonist.

The designer leptin antagonist peptide Allo-aca compensates for short serum half-life with very tight binding to the receptor.

The leptin receptor antagonist peptide Allo-aca exhibits picomolar activities in various cellular systems and sub-mg/kg subcutaneous efficacies in animal models making it a prime drug candidate and target validation tool. Here we identified the biochemical basis for its remarkable in vivo activity. Allo-aca decomposed within 30 min in pooled human serum and was undetectable beyond the same time period from mouse plasma during pharmacokinetic measurements. The C max of 8.9 µg/mL at 5 min corresponds to approximately 22% injected peptide present in the circulation. The half-life was extended to over 2 h in bovine vitreous fluid and 10 h in human tears suggesting potential efficacy in ophthalmic diseases. The peptide retained picomolar anti-proliferation activity against a chronic myeloid leukemia cell line; addition of a C-terminal biotin label increased the IC50 value by approximately 200-fold. In surface plasmon resonance assays with the biotin-labeled peptide immobilized to a NeutrAvidin-coated chip, Allo-aca exhibited exceptionally tight binding to the binding domain of the human leptin receptor with ka = 5 × 10(5) M(-1) s(-1) and kdiss = 1.5 × 10(-4) s(-1) values. Peptides excel in terms of high activity and selectivity to their targets, and may activate or inactivate receptor functions considerably longer than molecular turnovers that take place in experimental animals.