Expression and subcellular localization of RAGE in melanoma cells.

The receptor for advanced glycation end products (RAGE) is involved in multiple stages of tumor development and malignization. To gain further knowledge on the RAGE role in tumor progression, we investigated the receptor expression profile and its subcellular localization in melanoma cells at different stages of malignancy. We found that RAGE clustered at membrane ruffles and leading edges, and at sites of cell-to-cell contact in primary melanoma cells (e.g., MelJuSo), in contrast with a more dispersed localization in metastatic cells (e.g., SK-Mel28). RAGE silencing by RNAi selectively inhibited migration of MelJuSo cells, whilst having no influence on SK-Mel28 cell migration, in a "wound healing" assay. Western blot detection of RAGE showed a more complex RAGE oligomerization in MelJuSo cells compared to melanocytes and SK-Mel28 cells. By competing the binding of antibodies with recombinant soluble RAGE, an oligomeric form running at approximately 200 kDa was detected, as it was the monomeric RAGE of 55-60 kDa. SDS-PAGE electrophoresis under reducing versus nonreducing conditions indicated that the oligomer of about 200 kDa is formed by disulfide bonds, but other interactions are likely to be important for RAGE multimerization in melanoma cells. Immunofluorescence microscopy revealed that treatment with two cholesterol-chelating drugs, nystatin and filipin, significantly affected RAGE localization in MelJuSo cells. SK-Mel28 cells showed a reduced RAGE glycosylation and association with cholesterol-rich membranes and also a considerable downregulation of the soluble forms. Our results indicate that RAGE isoform expression and subcellular localization could be important determinants for the regulation of its function in tumor progression.

Refolding of hexameric porcine leucine aminopeptidase using a cationic detergent and dextrin-10 as artificial chaperones.

The application of artificial chaperones in biotechnology has been inspired by the mechanism of molecular chaperones like GroEL/GroES. It involves addition of a capturing detergent during dilution of the chaotropic reagent, that prevents protein aggregation, and finally, addition of a oligosaccharide that removes the detergent allowing the protein to refold. Here, guanidinium hydrochloride-denatured hexameric leucine aminopeptidase is shown to be efficiently refolded by using the cationic detergent cetyltrimethylammonium bromide and the linear polysaccharide dextrin-10 as artificial chaperones. The effect of these additives and the time dependence on the recovery of total enzymatic activity, kinetic parameters (K(M), k(cat)), intrinsic steady-state tryptophan fluorescence and oligomeric structure is presented. The method described is very promising since 92% of fully active and correct folded LAP could be produced. Moreover, we showed that the stripping process is relatively slow, it allows the protein to refold almost entirely to its native state.

Protection against glycation and similar post-translational modifications of proteins.

Glycation and other non-enzymic post-translational modifications of proteins have been implicated in the complications of diabetes and other conditions. In recent years there has been extensive progress in the search for ways to prevent the modifications and prevent the consequences of the modifications. These areas are covered in this review together with newer ideas on possibilities of reversing the chemical modifications.

Glutathione-related enzymes and the eye.

Glutathione and the related enzymes belong to the defence system protecting the eye against chemical and oxidative stress. This review focuses on GSH and two key enzymes, glutathione reductase and glucose-6-phosphate dehydrogenase in lens, cornea, and retina. Lens contains a high concentration of reduced glutathione, which maintains the thiol groups in the reduced form. These contribute to lens complete transparency as well as to the transparent and refractive properties of the mammalian cornea, which are essential for proper image formation on the retina. In cornea, gluthatione also plays an important role in maintaining normal hydration level, and in protecting cellular membrane integrity. In retina, glutathione is distributed in the different types of retinal cells. Intracellular enzyme, glutathione reductase, involved in reducing the oxidized glutathione has been found at highest activity in human and primate lenses, as compared to other species. Besides the enzymes directly involved in maintaining the normal redox status of the cell, glucose-6-phosphate dehydrogenase which catalyzes the first reaction of the pentose phosphate pathway, plays a key role in protection of the eye against reactive oxygen species. Cornea has a high activity of the pentose phosphate pathway and glucose-6-phosphate dehydrogenase activity. Glycation, the non-enzymic reaction between a free amino group in proteins and a reducing sugar, slowly inactivates gluthathione-related and other enzymes. In addition, glutathione can be also glycated. The presence of glutathione, and of the related enzymes has been also reported in other parts of the eye, such as ciliary body and trabecular meshwork, suggesting that the same enzyme systems are present in all tissues of the eye to generate NADPH and to maintain gluthatione in the reduced form. Changes of glutathione and related enzymes activity in lens, cornea, retina and other eye tissues, occur with ageing, cataract, diabetes, irradiation and administration of some drugs.

Trehalose and 6-aminohexanoic acid stabilize and renature glucose-6-phosphate dehydrogenase inactivated by glycation and by guanidinium hydrochloride.

A number of naturally occurring small organic molecules, primarily involved in maintaining osmotic pressure in the cell, display chaperone-like activity, stabilizing the native conformation of proteins and protecting them from various kinds of stress. Most of them are sugars, polyols, amino acids or methylamines. In addition to their intrinsic protein-stabilizing activity, these small organic stress molecules regulate the activity of some molecular chaperones, and may stabilize the folded state of proteins involved in unfolding or in misfolding diseases, such as Alzheimer's and Parkinson's diseases, or alpha1-antitrypsin deficiency and cystic fibrosis, respectively. Similar to molecular chaperones, most of these compounds have no substrate specificity, but some specifically stabilize certain proteins, e.g., 6-aminohexanoic acid (AHA) stabilizes apolipoprotein A. In the present work, the capacity of 6-aminohexanoic acid to stabilize non-specifically other proteins is demonstrated. Both trehalose and AHA significantly protect glucose-6-phosphate dehydrogenase (G6PD) against glycation-induced inactivation, and renatured enzyme already inactivated by glycation and by guanidinium hydrochloride (GuHCl). To the best of our knowledge, there are no data on the effect of these compounds on protein glycation. The correlation between the recovery of enzyme activity and structural changes indicated by fluorescence spectroscopy and Western blotting contribute to better understanding of the protein stabilization mechanism.