Frank W. Foss

Follicular shuttling of marginal zone B cells facilitates antigen transport

The splenic marginal zone is a site of blood flow, and the specialized B cell population that inhabits this compartment has been linked to the capture and follicular delivery of blood-borne antigens. However, the mechanism of this antigen transport has remained unknown. Here we show that marginal zone B cells were not confined to the marginal zone but continuously shuttled between the marginal zone and follicular areas, such that many of the cells visited a follicle every few hours. Migration to the follicle required the chemokine receptor CXCR5, whereas return to the marginal zone was promoted by the sphingosine 1-phosphate receptors S1P1 and S1P3. Treatment with an S1P1 antagonist caused displacement of marginal zone B cells from the marginal zone. Marginal zone–follicle shuttling of marginal zone B cells provides an efficient mechanism for systemic antigen capture and delivery to follicular dendritic cells.

Nutrient isothiocyanates covalently modify and inhibit the inflammatory cytokine macrophage migration inhibitory factor (MIF).

Dietary ITCs (isothiocyanates) prevent cancer and show other bioactivities in vivo. As electrophiles, ITCs may covalently modify cellular proteins. Using a novel proteomics screen, we identified MIF (macrophage migration inhibitory factor) as the principal target of nutrient ITCs in intact cells. ITCs covalently modify the N-terminal proline residue of MIF and extinguish its catalytic tautomerase activity. MIF deficiency does not prevent induction of Phase 2 gene expression, a hallmark of many cancer chemopreventives, including ITCs. Due to the emerging role of MIF in the control of malignant cell growth and its clear involvement in inflammation, inhibition of MIF by nutrient ITCs suggests therapeutic strategies for inflammatory diseases and cancer.

Organocatalytic Dakin oxidation by nucleophilic flavin catalysts.

Flavin catalysts perform the first organocatalytic Dakin oxidation of electron-rich arylaldehydes to phenols under mild, basic conditions. Catechols are readily prepared, and the oxidation of 2-hydroxyacetophenone was achieved. Aerobic oxidation is displayed in the presence of Zn(0) as a reducing agent. This reactivity broadens the scope of biomimetic flavin catalysis in the realm of nucleophilic oxidations, providing a framework for mechanistic investigations for related oxidations, such as the Baeyer-Villiger oxidation and Weitz-Scheffer epoxidation.

Artificial Enzymes with Thiazolium and Imidazolium Coenzyme Mimics

Hydrophobic thiazolium and imidazolium coenzyme mimics in the presence of modified-polyethylenimine enzyme mimics catalyze the benzoin condensation 2300-3300 times faster than the coenzyme mimics alone. Polycationic enzyme mimics provide not only a hydrophobic binding domain for coenzyme and substrate, but also electrostatic stabilization of anionic species that arise along the reaction pathway of the benzoin condensation.

Aerobic Organocatalytic Oxidation of Aryl Aldehydes: Flavin Catalyst Turnover by Hantzsch’s Ester

The first Dakin oxidation fueled by molecular oxygen as the terminal oxidant is reported. Flavin and NAD(P)H coenzymes, from natural enzymatic redox systems, inspired the use of flavin organocatalysts and a Hantzsch ester to perform transition-metal-free, aerobic oxidations. Catechols and electron-rich phenols are achieved with as low as a 0.1 mol % catalyst loading, 1 equiv of Hantzsch ester, and O(2) or air as the stoichiometric oxidant source.

In Vitro Metabolism of a Model Cyclopropylamine to Reactive Intermediate: Insights into Trovafloxacin-Induced Hepatotoxicity

Trovafloxacin (Trovan) is a fluoroquinolone antibiotic drug with a long half-life and broad-spectrum activity. Since its entry into the market in 1998, trovafloxacin has been associated with numerous cases of hepatotoxicity, which has limited its clinical usefulness. Trovafloxacin possesses two substructural elements that have the potential to generate reactive intermediates: a cyclopropylamine moiety and a difluoroanilino system. The results presented here describe the in vitro metabolic activation of a synthetic drug model (DM) of trovafloxacin that contains the cyclopropylamine moiety. Cyclopropylamine can be oxidized to reactive ring-opened products-a carbon-centered radical and a subsequently oxidized alpha,beta-unsaturated aldehyde. Experiments with monoamine oxygenases, horseradish peroxidase, flavin monooxygenase 3, and cDNA-expressed P450 isoenzymes revealed that P450 1A2 oxidizes DM to a reactive alpha,beta-unsaturated aldehyde, M 1. Furthermore, myeloperoxidase (MPO) was also demonstrated to oxidize DM in the presence of chloride ion to produce M 1. DM proved to be a suicide inhibitor of MPO while showing no inhibition of P450 1A2. The structure of the reactive metabolite was confirmed by LC-MS/MS analysis by comparison with a synthetic standard. M 1 was further shown to react with glutathione and the related thiol nucleophile, 4-bromobenzyl mercaptan, suggesting the potential of this intermediate to react with protein nucleophiles. In summary, these data provide evidence that trovafloxacin-induced hepatotoxicity may be mediated through the oxidation of the cyclopropylamine substructure to reactive intermediates that may form covalent adducts to hepatic proteins, resulting in damage to liver tissue.

The electrical properties of biphenylenes.

The effect of the partial antiaromaticity of biphenylene on its substitution chemistry, its oxidation potential, and its single-molecule conductance is explored. Biphenylene and fluorene molecules with linkers of two amino groups or two cyclic thioether groups were synthesized and their conduction properties were investigated using scanning tunneling microscopy (STM) break-junction techniques and DFT calculations. Despite the partial antiaromaticity of biphenylene, which causes the biphenylenes to be much more easily oxidizable, no significant increase in molecular conductance was found.

Charge transport in nanoscale aromatic and antiaromatic systems

Molecules such as benzene, that have six pi electrons cyclically delocalized, have the special stability that chemists call aromaticity. When electricity passes through a molecular wire containing a benzene ring a quinone-like structure is induced, and there is some loss of aromaticity. The conductance of such systems correlates with the magnitude of this effect. A molecule such as cyclobutadiene with only four cyclically delocalized pi electrons has special instability, called antiaromaticity. Evidence that such antiaromatic systems could convey high conductance in appropriate systems is derived from electrochemical studies, which also detect geometric changes in some thiophene-derived nanolength wires.

Synthesis and Biological Evaluation of Sphingosine Kinase Substrates as Sphingosine-1-Phosphate Receptor Prodrugs

In the search for bioactive sphingosine 1-phosphate (S1P) receptor ligands, a series of 2-amino-2-heterocyclic-propanols were synthesized. These molecules were discovered to be substrates of human-sphingosine kinases 1 and 2 (SPHK1 and SPHK2). When phosphorylated, the resultant phosphates showed varied activities at the five sphingosine-1-phosphate (S1P) receptors (S1P(1-5)). Agonism at S1P(1) was displayed in vivo by induction of lymphopenia. A stereochemical preference of the quaternary carbon was crucial for phosphorylation by the kinases and alters binding affinities at the S1P receptors. Oxazole and oxadiazole compounds are superior kinase substrates to FTY720, the prototypical prodrug immunomodulator, fingolimod (FTY720). The oxazole-derived structure was the most active for human SPHK2. Imidazole analogues were less active substrates for SPHKs, but more potent and selective agonists of the S1P(1) receptor; additionally, the imidazole class of compounds rendered mice lymphopenic.

Multilayer chitosan-based open tubular capillary anion exchange column with integrated monolithic capillary suppressor.

We describe a multilayered open tubular anion exchange column fabricated by alternately pumping solutions of chitosan and glutaraldehyde. The column is terminated in an integrally bonded monolithic suppressor cast around a mandrel of a tungsten wire, composed of an acrylic acid (AA)-ethylene dimethacrylate (EDMA) monolith that is made with sufficient porogen for the monolith to function as a membrane. For a 4.5m long 75 μm bore column coated with 24 successive layers of the condensation polymer (estimated to contain ~72 molecular layers) and coupled to 1cm length of a suppressor fabricated with 55-60% AA, effective separation of several common anions (F(-), Cl(-), NO(2)(-), Br(-), NO(3)(-), average number of theoretical plates ~12,000) and adequate suppression of 1 mM KOH used as eluent was observed at a flow rate of 800 nL min(-1) to obtain sub-picomol detection limits at an operating pressure of ~1 bar. The separation is not time efficient but the system can be meritorious in unique niche applications where a small form factor is desired and liquid volume and power consumption are more important than separation speed.