IL-1 beta- and IL-4-induced down-regulation of autotaxin mRNA and PC-1 in fibroblast-like synoviocytes of patients with rheumatoid arthritis (RA).

Autotaxin (ATX) is a 125-kD ectonucleotide pyrophosphate/phosphodiesterase, which was initially isolated and cloned from human melanoma cells as a potent stimulator of tumour cell motility. ATX shows 44% identity to the plasma cell membrane marker PC-1. Recently, we described the decreased expression of ATX mRNA in cultured fibroblast-like synoviocytes (SFC) of patients with RA by interferon-gamma. In this study using a competitive reverse transcriptase-polymerase chain reaction, we show an increased ATX mRNA expression in SFC from patients with RA in comparison with synoviocytes from non-RA patients. The median ATX mRNA amount in SFC of RA patients (440 pg/microg total RNA) was five-fold higher than the expression in synoviocytes from non-RA patients (80 pg/microg total RNA) or foreskin fibroblasts (MRHF cells, 90 pg/microg total RNA). In contrast to the elevated ATX mRNA expression in SFC of patients with RA, we did not measure increased mRNA amounts of PC-1 in these cells. Both the ATX mRNA amount and the 5'-nucleotide phosphodiesterase (PDE) activity of SFC lysate were reduced after treatment of SFC with the cytokines IL-1beta or IL-4. IL-1beta and IL-4 induced a down-regulation of PC-1 mRNA and protein expression in SFC. In SFC treated with transforming growth factor-beta the expression of PC-1 mRNA and protein was increased, whereas no significant effect on ATX mRNA expression was detectable. Pharmacological drugs used in therapy for RA, such as dexamethasone, cyclosporin, methotrexate and indomethacin, did not show a statistically significant effect on either ATX mRNA or PC-1 mRNA expression. Only pentoxifylline suppressed ATX mRNA as well as PC-1 mRNA expression. In conclusion, we show a tight regulation of ATX and PC-1 gene expression by cytokines detectable in the inflamed tissue of RA. Further investigations will deal with the regulation of ATX protein expression as well as with the function of ATX in RA.

Various functions of selenols and thiols in anaerobic gram-positive, amino acids-utilizing bacteria.

Electron transfer reactions for the reduction of glycine in Eubacterium acidaminophilum involve many selenocysteine (U)- and thiol-containing proteins, as shown by biochemical and molecular analysis. These include an unusual thioredoxin system (-CXXC-), protein A (-CXXU-) and the substrate-specific protein B of glycine reductase (-UXXCXXC-). Most probably a selenoether is formed at protein B by splitting the C-N-bond after binding of the substrate. The carboxymethyl group is then transferred to the selenocysteine of protein A containing a conserved motif. The latter protein acts as a carbon and electron donor by giving rise to a protein C-bound acetyl-thioester and a mixed selenide-sulfide bond at protein A that will be reduced by the thioredoxin system. The dithiothreitol-dependent D-proline reductase of Clostridium sticklandii exhibits many similarities to protein B of glycine reductase including the motif containing selenocysteine. In both cases proprotein processing at a cysteine residue gives rise to a blocked N-terminus, most probably a pyruvoyl group. Formate dehydrogenase and some other proteins from E. acidaminophilum contain selenocysteine, e.g., a 22 kDa protein showing an extensive homology to peroxiredoxins involved in the detoxification of peroxides.

Identification of D-proline reductase from Clostridium sticklandii as a selenoenzyme and indications for a catalytically active pyruvoyl group derived from a cysteine residue by cleavage of a proprotein.

Highly active D-proline reductase was obtained from Clostridium sticklandii by a modified purification scheme. The cytoplasmic enzyme had a molecular mass of about 870 kDa and was composed of three subunits with molecular masses of 23, 26, and 45 kDa. The 23-kDa subunit contained a carbonyl group at its N terminus, which could either be labeled with fluorescein thiosemicarbazide or removed by o-phenylenediamine; thus, N-terminal sequencing became feasible for this subunit. L-[14C]proline was covalently bound to the 23-kDa subunit if proline racemase and NaBH4 were added. Selenocysteine was detected in the 26-kDa subunit, which correlated with an observed selenium content of 10.6 g-atoms in D-proline reductase. No other non-proteinaceous cofactor was identified in the enzyme. A 4.8-kilobase pair (kb) EcoRI fragment was isolated and sequenced containing the two genes prdA and prdB. prdA coding for a 68-kDa protein was most likely translated as a proprotein that was posttranslationally cleaved at a threonine-cysteine site to give the 45-kDa subunit and most probably a pyruvoyl-containing 23-kDa subunit. The gene prdB encoded the 26-kDa subunit and contained an in frame UGA codon for selenocysteine insertion. prdA and prdB were transcribed together on a transcript of 4.5 kb; prdB was additionally transcribed as indicated by a 0.8-kb mRNA species.