The use of DODT as a non-malodorous scavenger in Fmoc-based peptide synthesis.

We have synthesized a random group of peptides and performed cleavages using various cleavage cocktails including 3,6-dioxa-1,8-octanedithiol (DODT). Purity of the peptides was compared to that obtained with standard protocols for cleavage using RP-HPLC and Maldi-Tof mass spectrometry. We show that stinking thiols can be replaced by the almost odourless (DODT) without negatively affecting the purity of the end product.

Design and synthesis of a multivalent homing device for targeting to murine CD22.

CD22 is a cell-surface glycoprotein uniquely located on mature B-cells and B-cell derived tumour cells. Current evidence suggests that binding of endogenous ligands to CD22 leads to modulation of B-cell activation by antigen. Incidentally, however, B-cell activation may derail. and lead to an undesired immune response, for example in cases of allergy, rheumatoid arthritis and Crohn's disease. In this situation, synthetic high-affinity ligands for CD22 may be of therapeutic value as inhibitors of B-cell activation. Recent studies have revealed that natural ligands for CD22 contain the trisaccharide NeuAc alpha-2,6-Lac as the basic binding motif. In addition, it has been demonstrated that binding to CD22 is strongly enhanced by multivalent presentation of the basic binding motif (cluster effect). In this paper. the stepwise development of a novel multivalent high-affinity ligand for CD22 is described. In the first stage, a series of monovalent NeuAc alpha-2,6-Glc(Y)X type binding motifs was prepared, and their affinity for murine CD22 was monitored, to obtain more insight into the effect of separate structure elements on ligand recognition. In the second stage, we prepared a trivalent cluster, based on the monovalent motif that displayed the highest affinity for CD22, NeuAc alpha-2,6-GlcNBzNO2OMe (7). This cluster, TRIS(NeuAc alpha-2,6-GlcNBzNO2)3 (52), displayed a more than 58-fold higher affinity for CD22 than the reference structure NeuAc alpha-2,6-LacOMe (10). To our knowledge, the cluster 52 is one of the most potent antagonists for CD22 yet synthesised.

Spirophostins: conformationally restricted analogues of adenophostin A.

The synthesis, biological evaluation, and molecular modeling of two conformationally restricted analogues of adenophostinA (1), denominated as spirophostin (3R)-10 and (3S)-11, as novel ligands for the D-myo-inositol 1,4,5-trisphosphate receptor (IP3R), is presented. These diastereoisomeric spiroketals are synthesized by spiroketalization of D-glucose derivatives (2S)-15 and (2R)-16, separation of the protected isomers (3R)-19 and (3S)-20, followed by phosphorylation and deprotection. The spirophostins (3R)-10 and (3S)-11 display comparable biological activity, with a 3H-IP3-displacing and Ca2+-releasing potency less than IP3 and adenophostin A.

Novel hepatotrophic prodrugs of the antiviral nucleoside 9-(2-phosphonylmethoxyethyl)adenine with improved pharmacokinetics and antiviral activity.

The device of new hepatotrophic prodrugs of the antiviral nucleoside 9-(2-phosphonylmethoxyethyl)adenine (PMEA) with specificity for the asialoglycoprotein receptor on parenchymal liver cells is described. PMEA was conjugated to bi- and trivalent cluster glycosides (K(GN)(2) and K(2)(GN)(3), respectively) with nanomolar affinity for the asialoglycoprotein receptor. The liver uptake of the PMEA prodrugs was more than 10-fold higher than that of the parent drug (52+/-6% and 62+/-3% vs. 4.8+/-0.7% of the injected dose for PMEA) and could be attributed for 90% to parenchymal cells. Accumulation of the PMEA prodrugs in extrahepatic tissue (e.g., kidney, skin) was substantially reduced. The ratio of parenchymal liver cell-to-kidney uptake-a measure of the prodrugs therapeutic window-was increased from 0.058 +/- 0.01 for PMEA to 1.86 +/- 0.57 for K(GN)(2)-PMEA and even 2.69 +/- 0.24 for K(2)(GN)(3)-PMEA. Apparently both glycosides have a similar capacity to redirect (antiviral) drugs to the liver. After cellular uptake, both PMEA prodrugs were converted into the parent drug, PMEA, during acidification of the lysosomal milieu (t(1/2) approximately 100 min), and the released PMEA was rapidly translocated into the cytosol. The antiviral activity of the prodrugs in vitro was dramatically enhanced as compared to the parent drug (5- and 52-fold for K(GN)(2)-PMEA and K(2)(GN)(3)-PMEA, respectively). Given the 15-fold enhanced liver uptake of the prodrugs, we anticipate that the potency in vivo will be similarly increased. We conclude that PMEA prodrugs have been developed with greatly improved pharmacokinetics and therapeutic activity against viral infections that implicate the liver parenchyma (e.g., HBV). In addition, the significance of the above prodrug concept also extends to drugs that intervene in other liver disorders such as cholestasis and dyslipidemia.

Synthesis of potent agonists of the D-myo-inositol 1,4, 5-trisphosphate receptor based on clustered disaccharide polyphosphate analogues of adenophostin A.

Clustered disaccharide analogues of adenophostin A (2), i.e. mono-, di-, and tetravalent derivatives 6-8, respectively, were synthesized and evaluated as novel ligands for the tetrameric D-myo-inositol 1,4, 5-trisphosphate receptor (IP(3)R). The synthesis was accomplished via Sonogashira coupling of propargyl 2-O-acetyl-5-O-benzyl-3-O-(3, 4-di-O-acetyl-2, 6-di-O-benzyl-alpha-D-glucopyranosyl)-beta-D-ribofuranoside (16) with iodobenzene 18, 22, or 25, followed by deacetylation, phosphorylation, and deprotection. The abilities of the target compounds 6-8, as well as ribophostin 4, propylphostin 5, and IP(3) (1), to evoke Ca(2+) release from permeabilized hepatocytes or displacement of [(3)H]IP(3) from its receptor in hepatic membranes were compared. Although the binding affinities of 4-8 were similar, there were modest though significant differences in their potencies in Ca(2+) release assays: tetraphostin 8 > IP(3) approximately diphostin 7 > phenylphostin 6 > ribophostin 4 approximately propylphostin 5.

Design and synthesis of novel amphiphilic dendritic galactosides for selective targeting of liposomes to the hepatic asialoglycoprotein receptor.

A series of glycolipids have been prepared which contain a cluster galactoside moiety with high affinity for the hepatic asialoglycoprotein receptor and a bile acid ester moiety which mediates stable incorporation into liposomes. Loading of liposomes with these glycolipids at a ratio of 5% (w/w) resulted in efficient recognition and uptake of the liposomes by the liver. Preinjection with asialofetuin almost completely inhibited the uptake, establishing that the liposomes were selectively recognized and processed by the asialoglycoprotein receptor on liver parenchymal cells. In contrast, a glycolipid content of 50% (w/w) led to a liver uptake that could not be inhibited by preinjection with asialofetuin, indicating that the liposomes were now processed by the Gal/Fuc-recognizing receptor on liver macrophages. The results presented in this study are important for future targeting of water-soluble and amphiphilic drugs, enveloped in these glycolipid-laden liposomes, to parenchymal liver cells.

Inhibition of human smooth muscle cell proliferation in culture by farnesyl pyrophosphate analogues, inhibitors of in vitro protein: farnesyl transferase.

In this study, it was investigated whether and how inhibitors of protein:farnesyl transferase (PFT) can inhibit the proliferation of human smooth muscle cells (HSMC) in culture. Several farnesyl pyrophosphate (FPP) analogues were synthesized and tested in vitro for their specificity in inhibiting squalene synthase (SS), PFT, or protein:geranylgeranyl transferase-1 (PGGT-1) activities (the latter was determined using a newly designed assay). One of these compounds appeared to be a strong PFT inhibitor (IC50 value: 340 nM) and a weak inhibitor in the other two enzyme assays. This compound (designated as TR006) inhibited the farnesylation of Ras in a Ha-ras transfected cell line (Cohen et al., Biochem. Phamacol. 49: 839-845, 1995) and concomitantly slowed down the growth of these cells. Twenty-five microM of TR006 inhibited the proliferation of HSMC isolated from left internal mammary artery, as measured by counting the cells over a period of three cell cycles (10 days). A structurally related compound (TR007), a specific SS inhibitor, did not influence HSMC proliferation under the same conditions. The inhibition by TR006 was concentration-dependent. In HSMC, synchronized by serum depletion, platelet-derived growth factor (PDGF) or basic fibroblast growth factor (bFGF)-induced DNA synthesis was decreased by a 29-hr pretreatment with 100 microM of TR006, indicating that this inhibitor acted in an early phase of the cell cycle, probably by preventing protein isoprenylation. Some other FPP analogues with comparable IC50 values in the in vitro PFT assay were also able to decrease bFGF-induced DNA synthesis without affecting cell viability. A more negatively charged member of this group, TR018, did not influence the growth factor-induced DNA synthesis, probably due to an impaired uptake into the cells. However, the pivaloyloxomethyl derivative of this compound, which is uncharged, and is thought to be converted into TR018 within the cells, showed a strong decrease in bFGF-induced DNA synthesis in HSMC. These data suggest that the compounds investigated may be developed further for treatment of conditions in which undesirable proliferation of smooth muscle cells plays an important role.

Different analogues of farnesyl pyrophosphate inhibit squalene synthase and protein:farnesyltransferase to different extents.

The inhibitory potency of farnesyl pyrophosphate analogues was investigated on two farnesyl pyrophosphate-consuming enzymes: squalene synthase, a secondary regulation site in the cholesterol synthesis pathway, and protein:farnesyl transferase, which plays a role in the function of Ras-proteins. For the transferase determination a rapid in vitro assay, using Sepharose-bound Ras-peptides, was developed. The distinct farnesyl pyrophosphate analogues showed a different order of potency in the inhibition of these two enzymes. Using the farnesyl transferase assay with pre-p21Ha-ras as substrate the same result was obtained. The difference observed in the in vitro assays was also reflected in the inhibition of cholesterol synthesis, protein prenylation in general and Ha-ras farnesylation in Rat-1.H-ras13 cells, a rat fibroblast cell line that overproduces human p21Ha-ras. This work shows that farnesyl pyrophosphate analogues can be developed for specific inhibition of different processes such as cholesterol synthesis and protein prenylation.