The effects of dissociated glucocorticoids RU24858 and RU24782 on TPA-induced skin tumor promotion biomarkers in SENCAR mice.

Glucocorticoids (GCs) are very effective at preventing carcinogen- and tumor promoter-induced skin inflammation, hyperplasia, and mouse skin tumor formation. The effects of GCs are mediated by a well-known transcription factor, the glucocorticoid receptor (GR). GR acts via two different mechanisms: transcriptional regulation that requires DNA-binding (transactivation) and DNA binding-independent protein-protein interactions between GR and other transcription factors, such as nuclear factor kappa B (NF-κB) or activator protein 1 (AP-1; transrepression). We hypothesize that the transrepression activities of the GR are sufficient to suppress skin tumor promotion. We obtained two GCs (RU24858 and RU24782) that have dissociated downstream effects and induce only transrepression activities of the GR in a number of systems. These compounds bind the GR with high affinity and repress AP-1 and NF-κB activities while showing a lack of GR transactivation. RU24858, RU24782, or control full GCs desoximetasone (DES) and fluocinolone acetonide (FA) were applied to the dorsal skin of SENCAR mice prior to application of the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA), two times per week for 2 weeks. DES, FA and RU24858 reversed TPA-induced epidermal hyperplasia and proliferation, while RU24782 treatment had no effect on these markers of skin tumor promotion. All tested compounds decreased TPA-induced c-jun mRNA levels in skin. DES, FA, and RU24858, but not RU24782, were also able to reverse TPA-induced increases in the mRNA levels of COX-2 and iNOS. These findings show that RU24858 but not RU24782 reduced TPA-induced epidermal hyperplasia, proliferation, and inflammation, while both compounds reversed c-jun mRNA increases in the skin.

The role of the Val57 amino-acid residue in the hinge loop of the human cystatin C. Conformational studies of the beta2-L1-beta3 segments of wild-type human cystatin C and its mutants.

Human cystatin C (HCC) is one of the amyloidogenic proteins to be shown to oligomerize via a three-dimensional domain swapping mechanism. This process precedes the formation of a stable dimer and proceeds particularly easily in the case of the L68Q mutant. According to the proposed mechanism, dimerization of the HCC precedes conformational changes within the beta2 and beta3 strands. In this article, we present conformational studies, using circular dichroism and MD methods, of the beta2-L1-beta3 (His43-Thr72) fragment of the HCC involved in HCC dimer formation. We also carried out studies of the beta2-L1-beta3 peptide, in which the Val57 residue was replaced by residues promoting beta-turn structure formation (Asp, Asn, or Pro). The present study established that point mutation could modify the structure of the L1 loop in the beta-hairpin peptide. Our results showed that the L1 loop in the peptide excised from human cystatin C is broader than that in cystatin C. In the HCC protein, broadening of the L1 loop together with the unfavorable L68Q mutation in the hydrophobic pocket could be a force sufficient to cause the partial unfolding and then the opening of HCC or its L68Q mutant structure for further dimerization. We presume further that the Asp57 and Asn57 mutations in the L1 loop of HCC could stabilize the closed form of HCC, whereas the Pro57 mutation could lead to the opening of the HCC structure and then to dimer/oligomer formation.

Fluorogenic peptide substrates for carboxydipeptidase activity of cathepsin B.

Cathepsin B is a lysosomal cysteine protease exhibiting mainly dipeptidyl carboxypeptidase activity, which decreases dramatically above pH 5.5, when the enzyme starts acting as an endopeptidase. Since the common cathepsin B assays are performed at pH 6 and do not distinguish between these activities, we synthesized a series of peptide substrates specifically designed for the carboxydipeptidase activity of cathepsin B. The amino-acid sequences of the P(5)-P(1) part of these substrates were based on the binding fragments of cystatin C and cystatin SA, the natural reversible inhibitors of papain-like cysteine protease. The sequences of the P'(1)-P'(2) dipeptide fragments of the substrates were chosen on the basis of the specificity of the S'(1)-S'(2) sites of the cathepsin B catalytic cleft. The rates of hydrolysis by cathepsin B and papain, the archetypal cysteine protease, were monitored by a continuous fluorescence assay based on internal resonance energy transfer from an Edans to a Dabcyl group. The fluorescence energy donor and acceptor were attached to the C- and the N-terminal amino-acid residues, respectively. The kinetics of hydrolysis followed the Michaelis-Menten model. Out of all the examined peptides Dabcyl-R-L-V-G-F- E(Edans) turned out to be a very good substrate for both papain and cathepsin B at both pH 6 and pH 5. The replacement of Glu by Asp turned this peptide into an exclusive substrate for cathepsin B not hydrolyzed by papain. The substitution of Phe by Nal in the original substrate caused an increase of the specificity constant for cathepsin B at pH 5, and a significant decrease at pH 6. The results of kinetic studies also suggest that Arg in position P(4) is not important for the exopeptidase activity of cathepsin B, and that introducing Glu in place of Val in position P(2) causes an increase of the substrate preference towards this activity.

Effect of antisense peptide binding on the dimerization of human cystatin C--gel electrophoresis and molecular modeling studies.

Human cystatin C (HCC) shows a tendency to dimerize. This process is particularly easy in the case of the L68Q HCC mutant and might lead to formation of amyloid deposits in brain arteries of young adults. Our purpose was to find ligands of monomeric HCC that can prevent its dimerization. Eleven antisense peptide ligands of monomeric HCC were designed and synthesized. The influence of these ligands on HCC dimerization was studied using gel electrophoresis and molecular modeling methods. The results suggest that all the designed peptides interact with monomeric HCC facilitating its dimerization rather than preventing it.