Synthesis of novel 6-amido-6-deoxy-l-galactose derivatives as sialyl Lewis X mimetics.

The synthesis and biological potency of several sialyl Lewis X (SLe(x)) mimetics is described. These mimics incorporate all of the critical functional groups present in SLe(x) necessary for binding to E-selectin. L-Galactose is used to mimic the naturally occurring L-fucose residue in SLe(x) due to the identical arrangement of the 2-, 3-, and 4-hydroxyl groups. Several synthetically and enzymatically prepared amino acids were used to mimic the D-galactose residue. Because of the variability incorporated in the synthesis of these amino acids the spatial requirements necessary for efficient binding were investigated. A carboxylate bearing side chain was introduced as a sialic acid mimic and the chain length was varied to maximize biological activity. By investigating the optimal arrangement of these two factors mimics were produced which were up twofold more active than SLe(x).

Molecular diversity of peptidomimetics: approaches to the solid-phase synthesis of peptidosulfonamides.

In order to use the potential molecular diversity of the peptidosulfonamide peptidomimetics ultimately in libraries, approaches towards the solid-phase synthesis of peptidosulfonamides are a prerequisite. It is shown that peptidosulfonamides can be synthesized by solid-phase synthesis methods using either a Merrifield or a Tentagel resin. Better and more reproducible results are obtained using the latter resin. The possibility to prepare cyclic peptidosulfonamides was illustrated by the synthesis of cyclo-phenylalanyl psi[CH2S(O)2N]-glycine. However, translation of synthesis of peptidosulfonamides in solution to a solid-phase method was rather laborious and still requires careful optimization.

Peptides containing the sulfonamide transition-state isostere: synthesis and structure of N-acetyl-tauryl-L-proline methylamide.

The structure of the sulfonamide isostere-containing peptide N-acetyl-tauryl-proline methylamide 4 was compared to information on the structure of the peptide N-acetyl-beta-alanyl-proline methylamide 6. NMR measurements of the beta-alanine containing peptide 6 showed the presence of two conformations due to cis/trans isomerism of the beta-Ala-Pro amide bond, whereas the sulfonamide-containing peptide 4 appeared in only one conformation. The crystal structure of N-acetyl-tauryl-proline methylamide 4 gave additional evidence for the absence of cis/trans isomerism. The crystals are orthorhombic, space group P2(1)2(1)2(1), Z = 4, F(000) = 592, a = 7.5919(3), b = 10.3822(2), c = 17.1908(7) A, V = 1354.99(8) A3, Dx = 1.359 g cm-3. The oxygen atoms connected to the sulfur take positions similar to both the cis and trans positions of the carbonyl oxygen of an amide. Consequently the tauryl part is placed perpendicular to the proline alpha-C-C(O) bond, giving it an extended conformation in contrast to the cis/trans isomers of N-acetyl-beta-alanyl-proline methylamide 6.

Inhibition of glutathione S-transferase 3-3 by glutathione derivatives that bind covalently to the active site.

In all, 13 GSH derivatives have been synthesized and tested for their potency to inhibit glutathione S-transferase (GST) 3-3. All of these derivatives contained a reactive group that could potentially react with the enzyme active site. Best results were obtained with the phenylthiosulphonate derivative of GSH, GSSO2Ph. Preincubation of GST 3-3 with a 100 microM concentration of this inhibitor resulted in a time-dependent loss of activity: after 30 min at pH 6.5 and 25 degrees C, 51% of the activity was lost. At more alkaline pH, the activity is more rapidly inhibited: at pH 8.0 the 90%-inhibition level is already reached after 10 min preincubation. Separation of enzyme and excess unbound GSSO2Ph after preincubation by gel-filtration chromatography did not result in a reappearance of enzyme activity. If 100 microM-GSH was added to the preincubation mixture at pH 7.4, inhibition was almost completely prevented. Addition of S-(hexyl)glutathione (20 microM) could delay the inhibition but, ultimately, not prevent it. The inhibited enzyme could be re-activated by addition of 10 mM-2-mercaptoethanol: 60 min after this thiol was added, the inhibited GST-3- activity was bacxk to the control level. GSH at the same concentration could not re-activate the enzyme. On the basis of these results, on the known reactivity of thiosulphonate compounds, and on current knowledge about the amino acid residues involved in GST catalysis, a covalent modification of an active-site cysteine residue by mixed-disulphide formation between enzyme and the cosubstrate GSH is postulated. Information on the synthesis and characterization of the GSH derivatives is given in Supplementary Publication SUP 50166 (5 pages) which has been deposited at the British Library Document Supply Centre, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1991) 273, 5.