Total synthesis and biological evaluation of oscillatoxins D, E, and F.

Oscillatoxins (OTXs) and aplysiatoxins are biosynthetically related polyketides produced by marine cyanobacteria. We previously developed a synthetic route to phenolic O-methyl analogs of OTX-D and 30-methyl-OTX-D during collective synthesis of these natural products. According to our synthetic strategy, we achieved total synthesis of OTX-D, 30-methyl-OTX-D, OTX-E, and OTX-F by deprotecting the O-methyl group in an earlier intermediate, and determined their biological activities. Although OTX-D and 30-methyl-OTX-D have been reported to show antileukemic activity against L1210 cell line, we found that their cytotoxicity in vitro against this cell line is relatively weak (IC50: 29-52 µm). In contrast, OTX-F demonstrated cell line-selective antiproliferative activity against DMS-114 lung cancer cells, which implies that OTXs target as yet unknown target molecules as part of this unique activity.

Short Total Synthesis of [15N5]-Cylindrospermopsins from 15NH4Cl Enables Precise Quantification of Freshwater Cyanobacterial Contamination.

Fresh water cyanobacterial algal blooms represent a major health risk because these organisms produce cylindrospermopsin, a toxic, structurally complex, zwitterionic uracil-guanidine alkaloid recognized by the EPA as a dangerous drinking water contaminant. At present, the ability to detect and quantify the presence of cylindrospermospin in water samples is severely hampered by the lack of an isotopically labeled standard for analytical mass spectrometry. Herein, we present a concise, scaled total synthesis of 15N cylindrospermosin from 15N ammonium chloride, which leverages a unique stereoselective intramolecular double conjugate addition step to assemble the tricyclic guanidine core. In addition to providing the first pure isotopically labeled probe for precise quantification of this potent biotoxin in fresh water sources, our results demonstrate how unique constraints associated with isotope incorporation compel novel solutions to synthesis design.

Biosynthesis of 15N-labeled cylindrospermopsin and its application as internal standard in stable isotope dilution analysis.

Cylindrospermopsin (CYN) is a cyanobacterial toxin associated with human and animal poisonings. Due to its toxicity in combination with its widespread occurrence, the development of reliable methods for selective, sensitive detection and accurate quantification is mandatory. Liquid chromatography tandem mass spectrometry (LC-MS/MS) analysis using stable isotope dilution analysis (SIDA) represents an ideal tool for this purpose. U-[(15)N5]-CYN was synthesized by culturing Aphanizomenon flos-aquae in Na(15)NO3-containing cyanobacteria growth medium followed by a cleanup using graphitized carbon black columns and mass spectrometric characterization. Subsequently, a SIDA-LC-MS/MS method for the quantification of CYN in freshwater and Brassica matrices was developed showing satisfactory performance data. The recovery ranged between 98 and 103 %; the limit of quantification was 15 ng/L in freshwater and 50 µg/kg dry weight in Brassica samples. The novel SIDA was applied for CYN determination in real freshwater samples as well as in kale and in vegetable mustard exposed to toxin-containing irrigation water. Two of the freshwater samples taken from German lakes were found to be CYN-contaminated above limit of quantification (17.9 and 60.8 ng/L). CYN is systemically available to the examined vegetable species after exposure of the rootstock leading to CYN mass fractions in kale and vegetable mustard leaves of 15.0 µg/kg fresh weight and 23.9 µg/kg fresh weight, respectively. CYN measurements in both matrices are exemplary for the versatile applicability of the developed method in environmental analysis.

Chemistry of mycolactones, the causative toxins of Buruli ulcer.

Buruli ulcer is a severe and devastating skin disease caused by Mycobacterium ulcerans infection, yet it is one of the most neglected diseases. The causative toxin, referred to as mycolactone A/B, was isolated and characterized as a polyketide-derived macrolide in 1999. The current status of the mycolactone chemistry is described, highlighting the stereochemistry assignment of mycolactone A/B; total synthesis; the structure determination of mycolactone congeners from the human pathogen M. ulcerans, the frog pathogen Mycobacterium liflandii, and the fish pathogen Mycobacterium marinum; the structural diversity in the mycolactone class of natural products; the highly sensitive detection/structure-analysis of mycolactones; and some biological activity.

Distinct roles of phenol-soluble modulins in spreading of Staphylococcus aureus on wet surfaces.

The human pathogen Staphylococcus aureus is renowned for the rapid colonization of contaminated wounds, medical implants, and food products. Nevertheless, little is known about the mechanisms that allow S. aureus to colonize the respective wet surfaces. The present studies were therefore aimed at identifying factors used by S. aureus cells to spread over wet surfaces, starting either from planktonic or biofilm-associated states. Through proteomics analyses we pinpoint phenol-soluble modulins (PSMs) as prime facilitators of the spreading process. To dissect the roles of the eight PSMs produced by S. aureus, these peptides were chemically synthesized and tested in spreading assays with different psm mutant strains. The results show that PSMα3 and PSMγ are the strongest facilitators of spreading both for planktonic cells and cells in catheter-associated biofilms. Compared to the six other PSMs of S. aureus, PSMα3 and PSMγ combine strong surfactant activities with a relatively low overall hydropathicity. Importantly, we show that PSM-mediated motility of S. aureus facilitates the rapid colonization of wet surfaces next to catheters and the colonization of fresh meat.

A modular approach to assembly of totally synthetic self-adjuvanting lipopeptide-based vaccines allows conformational epitope building.

The technology described here allows the chemical synthesis of vaccines requiring correctly folded epitopes and that contain difficult or long peptide sequences. The final self-adjuvanting product promotes strong humoral and/or cell-mediated immunity. A module containing common components of the vaccine (T helper cell epitope and the adjuvanting lipid moiety S-[2,3-bis(palmitoyloxy)propyl]cysteine) was assembled to enable a plug and play approach to vaccine assembly. The inclusion within the module of a chemical group with chemical properties complementary and orthogonal to a chemical group present in the target epitope allowed chemoselective ligation of the two vaccine components. The heat-stable enterotoxin of enterotoxigenic Escherichia coli that requires strict conformational integrity for biological activity and the reproductive hormone luteinizing hormone-releasing hormone were used as the target epitopes for the antibody vaccines. An epitope from the acid polymerase of influenza virus was used to assemble a CD8(+) T cell vaccine. Evaluation of each vaccine candidate in animals demonstrated the feasibility of the approach and that the type of immune response required, viz. antibody or cytotoxic T lymphocyte, dictates the nature of the chemical linkage between the module and target epitope. The use of a thioether bond between the module and target epitope had little or no adverse effect on antibody responses, whereas the use of a disulfide bond between the module and target epitope almost completely abrogated the antibody response. In contrast, better cytotoxic T lymphocyte responses were obtained when a disulfide bond was used.

Highly stereoselective total synthesis of fully hydroxy-protected mycolactones A and B and their stereoisomerization upon deprotection.

Unprecedentedly efficient and highly (≥98 %) stereoselective syntheses of mycolactones A and B side chains relied heavily on Pd-catalyzed alkenylation (Negishi version) and were completed in 11 longest linear steps from ethyl (S)-3-hydroxybutyrate in 12% and 11% overall yield, respectively, roughly corresponding to an average of 82% yield per step. The synthesis of mycolactone core was realized by using Pd-catalyzed alkenyl-allyl coupling and an epoxide-opening reaction with a trialkylalkenylaluminate as key steps. Fully hydroxy-protected mycolactones A and B of ≥98% isomeric purity were synthesized successfully for the first time. However, unexpected 4:3-5:4 inseparable mixtures of mycolactones A and B were obtained upon deprotection.

A ring-closing metathesis (RCM)-based approach to mycolactones†A/B.

The total synthesis of the mycobacterial toxins mycolactones A/B (1 a/b) has been accomplished based on a strategy built around the construction of the mycolactone core through ring-closing metathesis. By employing the Grubbs second-generation catalyst, the 12-membered core macrocycle of mycolactones, with a functionalized C2 handle attached to C11, was obtained in 60-80 % yield. The C-linked upper side chain (comprising C12-C20) was completed by a highly efficient modified Suzuki coupling between C13 and C14, while the attachment of the C5-O-linked polyunsaturated acyl side chain was achieved by Yamaguchi esterification. Surprisingly, a diene containing a simple isopropyl group attached to C11 could not be induced to undergo ring-closing metathesis. By employing fluorescence microscopy and flow cytometry techniques, the synthetic mycolactones A/B (1 a/b) were demonstrated to display similar apoptosis-inducing and cytopathic effects as mycolactones A/B extracted from Mycobacterium ulcerans. In contrast, a simplified analogue with truncated upper and lower side chains was found to be inactive.

A diverted total synthesis of mycolactone analogues: an insight into Buruli ulcer toxins.

Mycolactones are complex macrolides responsible for a severe necrotizing skin disease called Buruli ulcer. Deciphering their functional interactions is of fundamental importance for the understanding, and ultimately, the control of this devastating mycobacterial infection. We report herein a diverted total synthesis approach of mycolactones analogues and provide the first insights into their structure-activity relationship based on cytopathic assays on L929 fibroblasts. The lowest concentration inducing a cytopathic effect was determined for selected analogues, allowing a clear picture to emerge by comparison with the natural toxins.

Synthetic studies on the mycolactone core.

Two approaches are presented for the synthesis of the macrolide core of the mycolactone polyketides. The first intertwines ring closing metathesis (RCM) within a two-step Julia olefination protocol, while the second intercepts the optimized routes of Kishi, thereby providing formal access to the mycolactones.

Quantitative analysis of cell-free synthesized membrane proteins at the stabilized droplet interface bilayer.

We report the functional synthesis and quantification of membrane proteins-α-hemolysin from Staphylococcus aureus and the multidrug transporter EmrE from Escherichia coli-at the stabilized droplet interface bilayer using an in vitro transcription-translation system. The system developed here can expand the list of integral membrane proteins applicable for quantitative functional analysis.

Synthesis of the mycolactone core by ring-closing metathesis.

The undecenolide core of mycolactone was synthesized by ring-closing metathesis and the structure confirmed using single-crystal X-ray diffraction techniques.

Converting a Staphylococcus aureus toxin into effective cyclic pseudopeptide antibiotics.

Staphylococcus aureus produces peptide toxins that it uses to respond to environmental cues. We previously characterized PepA1, a peptide toxin from S. aureus, that induces lytic cell death of both bacterial and host cells. That led us to suggest that PepA1 has an antibacterial activity. Here, we demonstrate that exogenously provided PepA1 has activity against both Gram-positive and Gram-negative bacteria. We also see that PepA1 is significantly hemolytic, thus limiting its use as an antibacterial agent. To overcome these limitations, we converted PepA1 into nonhemolytic derivatives. Our most promising derivative is a cyclic heptapseudopeptide with inconsequential toxicity to human cells, enhanced stability in human sera, and sharp antibacterial activity. Mechanistically, linear and helical PepA1 derivatives form pores at the bacterial and erythrocyte surfaces, while the cyclic peptide induces bacterial envelope reorganization, with insignificant action on the erythrocytes. Our work demonstrates that bacterial toxins might be an attractive starting point for antibacterial drug development.

Anthrax fusion protein therapy of cancer.

Most patients with cancer are treated with chemotherapy but die from progressive disease or toxicities of therapy. Current chemotherapy regimens primarily use cytotoxic drugs which damage cell DNA or impair cell proliferation in both malignant and normal tissues. After several treatment courses, the patients' tumor cells often overexpress multi-drug resistance genes which prevent further tumor cytoreduction. Novel agents which can kill such resistant tumor cells are needed. One such class of agents are targeted peptide toxins. Targeted peptide toxins consist of peptide toxins covalently linked to tumor selective peptide ligands. These molecules bind tumor cell surface receptors, internalize, and facilitate transfer of the toxin catalytic domains to the cytosol. Once in the cytosol, the enzyme activity leads to cell death. A number of plant, bacterial and fungal toxins have been used, and clinical trials with several of these have produced complete remissions in chemoresistant neoplasms. Nevertheless, there is a continuing need for novel targeted toxins. Many patients have pre-existing antibodies against the currently clinically used toxins and many toxins are inactive when used for myeloid malignancies where internalized proteins are rapidly routed and degraded in lysosomes. Anthrax toxins are the cytotoxic components of Bacillus anthracis. While the bacteria has been the source of serious illness, deaths and global anxieties related to past or future bioterrorism, the isolated toxins do not pose public health hazards. In fact, toxin treated patients will likely develop protective antibodies. Anthrax toxin is an excellent choice for tumor cell surface targeting. Other than U.S. military personnel immunized during the Gulf War, most people lack pre-existing antibodies. This may change in the future due to threats of additional terrorist acts, but for the present few patients will have antibodies to anthrax proteins. The separate subunits for binding, translocation and cell killing facilitate genetic engineering to yield tumor-specific cell killing. The toxins are more potent than most of the other peptide toxins and may yield highly efficacious targeted molecules. This essay will review anthrax toxin structure-function, preliminary experiments with re-targeted anthrax toxin and potential designs for new ligand-anthrax therapeutics.

Mode of disulfide bond formation of a heat-stable enterotoxin (STh) produced by a human strain of enterotoxigenic Escherichia coli.

To determine the modes of three disulfide linkages in the heat-stable enterotoxin (STh) produced by a human strain of enterotoxigenic Escherichia coli, we synthesized STh(6-18), which consists of 13 amino acid residues and has the same intramolecular disulfide linkages as native STh [(1985) FEBS Lett. 181, 138-142], by stepwise and selective formation of disulfide bonds using different types of removable protecting groups for the Cys residues. Synthesis of the peptide with different modes of disulfide bond formation provided three peptides consistent with standard STh(6-18) in their physicochemical and biological properties, thereby indicating that the disulfide bonds in STh(6-18) are Cys-Cys-Glu-Leu-Cys-Cys-Asn-Pro-Ala-Cys-Thr-Gly-Cys.

Folding of a synthetic parallel beta-roll protein.

Recently, the design of beta-sheet proteins and concomitant folding studies have attracted increasing attention. A unique natural all-beta domain occurs in a family of cytolytic bacterial toxins, the so-called RTX toxins. This domain consists of a variable number (about 6-45) of tandem repeats of a glycine-rich nine-residue motif with the consensus sequence GGXGXDX(L/I/F)X. The analysis of the three-dimensional structure of alkaline protease from Pseudomonas aeruginosa which possesses six of these repeats revealed that they fold into a novel 'parallel beta-roll' where calcium is bound within the turns connecting the beta-strands. A 75-mer peptide of the sequence NH(2)-WLS-[GGSGNDNLS](8)-COOH was chemically synthesised. Circular dichroism spectroscopy showed that this polypeptide folds in the presence of Ca(2+) and polyethylene glycol into a beta-structure which is presumably identical with the parallel beta-roll. This synthetic beta-roll behaves similarly to the isolated beta-roll domains from Escherichia coli haemolysin or Bordetella pertussis cyclolysin in terms of calcium binding and polymerisation behaviour.

Application of intramolecular enyne metathesis to the synthesis of aza[4.2.1]bicyclics: enantiospecific total synthesis of (+)-anatoxin-a.

A concise synthesis of the potent nAChR agonist (+)-anatoxin-a (1) has been completed in a series of only nine chemical operations and 27% overall yield from commercially available D-methyl pyroglutamate (4). The synthesis features a novel procedure for the diastereoselective preparation of cis-2,5-disubstituted pyrrolidines leading to 10, which underwent an intramolecular enyne metathesis to afford a bridged azabicyclic intermediate that was transformed into 1. [reaction: see text]

Antimicrobial properties of the Escherichia coli R1 plasmid host killing peptide.

The 52 amino acid host killing peptide (Hok) from the hok/sok post-segregational killer system of the Escherichia coli plasmid R1 was synthesized using Fmoc (9-fluorenylmethoxycarbonyl) chemistry, and its molecular weight was confirmed by mass spectroscopy. Hok kills cells by depolarizing the cytoplasmic membrane when it is made in the cytosol. Six microorganisms, E. coli, Bacillus subtilis, Pseudomonas aeruginosa, P. putida, Salmonella typhimurium, and Staphylococcus aureus were exposed to the purified peptide but showed no significant killing. However, electroporation of Hok (200 microgml(-1)) into E. coli cells showed a dramatic reduction (100000-fold) in the number of cells transformed with plasmid DNA which indicates that the synthetic Hok peptide killed cells. Electroporation of Hok into P. putida was also very effective with a 500-fold reduction in electrocompetent cells (100 microgml(-1)). Heat shock in the presence of Hok (380 microgml(-1)) resulted in a 5-fold reduction in E. coli cells but had no effect on B. subtilis. In addition, three Hok fragments (Hok(1-28), Hok(31-52) and Hok(16-52)) killed cells when electroporated into E. coli at 200 microgml(-1) (over 1000-fold killing for Hok(1-28), 50-fold killing for Hok(16-52) and over 1000-fold killing for Hok(31-52)). E. coli cells electroporated with Hok and visualized using transmission electron microscopy showed the same morphological changes as control cells to which Hok was induced using a plasmid inside the cell.

A totally synthetic lipopeptide-based self-adjuvanting vaccine induces neutralizing antibodies against heat-stable enterotoxin from enterotoxigenic Escherichia coli.

ST-based lipopeptide vaccine candidates were constructed in which ST was chemically synthesized and folded into the correct conformation prior to ligation to a module containing a T-helper cell epitope (T(H)) and the Toll-like receptor 2 (TLR2) agonist, S-[2,3-bis(palmitoyloxy)propyl]cysteine (P2C). Two different chemistries, thioether-based and oxime-based, were then used to ligate ST to the lipidated T(H) epitope. The enterotoxic activity of synthetic ST and the ST-based lipopeptide vaccines was determined in mice followed by an evaluation of immunological efficacy. The importance of the fine detail in chemical composition used in vaccine design was demonstrated by the findings that (i) the oxime-based vaccine exhibited little or no toxicity but the thioether-based vaccine, exhibited residual toxicity in suckling mice, (ii) although each of the synthetic vaccines generated specific anti-ST antibodies, it was the low titer antibodies induced by the oxime-based vaccine that demonstrated better neutralizing activity suggesting that the chemical linkage also affects the specificity of antibodies, (iii) the geometric arrangement of ST within a vaccine can profoundly affect the specificity and biological function of the antibodies that are elicited, and (iv) the lipopeptide-based ST vaccine candidate assembled using oxime chemistry induced a better neutralizing antibody response to ST when administered by the mucosal (intranasal) route.

A semisynthesis platform for investigating structure-function relationships in the N-terminal domain of the anthrax Lethal Factor.

Many bacterial toxins act by covalently altering molecular targets within the cytosol of mammalian cells and therefore must transport their catalytic moieties across a membrane. The Protective-Antigen (PA) moiety of anthrax toxin forms multimeric pores that transport the two enzymatic moieties, the Lethal Factor (LF) and the Edema Factor, across the endosomal membrane to the cytosol. The homologous PA-binding domains of these enzymes contain N-terminal segments of highly charged amino acids that are believed to enter the pore and initiate N- to C-terminal translocation. Here we describe a semisynthesis platform that allows chemical control of this segment in LF(N), the PA-binding domain of LF. Semisynthetic LF(N) was prepared in milligram quantities by native chemical ligation of synthetic LF(N)(14-28)alphathioester with recombinant N29C-LF(N)(29-263) and compared with two variants containing alterations in residues 14-28 of the N-terminal region. The properties of the variants in blocking ion conductance through the PA pore and translocating across planar phospholipid bilayers in response to a pH gradient were consistent with current concepts of the mechanism of polypeptide translocation through the pore. The semisynthesis platform thus makes new analytical approaches available to investigate the interaction of the pore with its substrates.