QUINAZOLINONES .18. SYNTHESIS AND H1/H2-ANTIHISTAMINIC ACTIVITY OF OMEGA-[2-ARYL-2,3-DIHYDRO-4(1H)-QUINAZOLINON-1-YL]ALKYL-SUBSTITUTED UREAS AND CYANOGUANIDINES

A series of (2-aryl-2,3-dihydro-4(1H)-quinazolinon-1-yl)alkyl-substituted cyanoguanidines and ureas with histamine, cimetidine or roxatidine partial structure was prepared and tested for H-1- and H-2-antagonism at the isolated ileum and the isolated right atrium of the guinea-pig. All compounds investigated were only very weak H-1-antagonists, whereas the 3-[3-(1-piperidinylmethyl)phenoxy]propyl-cyanoguanidines and -ureas were more potent H-2-antagonists than cimetidine, maximally achieving about ranitidine's potency

Kinetics of Hyal1 and PH-20 hyaluronidases: comparison of minimal substrates and analysis of the transglycosylation reaction.

The availability of recombinant expression systems for the production of purified human hyaluronidases PH-20 and Hyal-1 facilitated the first detailed analysis of the enzymatic reaction products. The human recombinant enzymes, both expressed by Drosophila Schneider-2 (DS-2) cells, were compared to bovine testicular hyaluronidase (BTH), a commercially available hyaluronidase preparation, which has long been considered a prototype of mammalian hyaluronidases. The conversion of low molecular weight hyaluronic acid (HA) fragments was detected by a capillary zone electrophoresis (CZE) method. Surprisingly, the HA hexasaccharide, which is generally accepted to be the minimum substrate of BTH, was not a substrate of recombinant human PH-20 and Hyal-1. However, HA octasaccharide was converted efficiently by both enzymes, thus representing the minimum substrate for human PH-20 and Hyal-1. Additionally, BTH was shown to catabolize the HA hexasaccharide at pH 4.0 mainly by hydrolysis, while at pH 6.0 transglycosylation prevailed. Human PH-20 was found to catalyze both hydrolysis and transglycosylation of the HA octasaccharide. On the contrary, human Hyal-1 converted the HA octasaccharide mainly by hydrolysis with transglycosylation products occurring only at high substrate concentrations (> or = 500 microM). The differences between the hyaluronidase subtypes and isoenzymes were much more prominent than expected. Obviously, the different hyaluronidase subtypes have evolved into very specialized enzymes with respect to their catalytic mechanism of action

Isoenzyme-specific differences in the degradation of hyaluronic acid by mammalian-type hyaluronidases.

Bovine testicular hyaluronidase (BTH) has been used as a spreading factor for many years and was primarily characterized by its enzymatic activity. As recombinant human hyaluronidases are now available the bovine preparations can be replaced by the human enzymes. However, data on the pH-dependent activity of hyaluronidases reported in literature are inconsistent in part or even contradictory. Detection of the pH-dependent activity of PH-20 type hyaluronidases, i.e. recombinant human PH-20 (rhPH-20) and BTH, showed a shift of the pH optimum from acidic pH values in a colorimetric activity assay to higher pH values in a turbidimetric activity assay. Contrarily, recombinant human Hyal-1 (rhHyal-1) and bee venom hyaluronidase (BVH) exhibited nearly identical pH profiles in both commonly used types of activity assays. Analysis of the hyaluronic acid (HA) degradation products by capillary zone electrophoresis showed that hyaluronan was catabolized by rhHyal-1 continuously into HA oligosaccharides. BTH and, to a less extent, rhPH-20 exhibited a different mode of action: at acidic pH (pH 4.5) HA was degraded as described for rhHyal-1, while at elevated pH (pH 5.5) small oligosaccharides were produced in addition to HA fragments of medium molecular weight, thus explaining the pH-dependent discrepancies in the activity assays. Our results suggest a sub-classification of mammalian-type hyaluronidases into a PH-20/BTH and a Hyal-1/BVH subtype. As the biological effects of HA fragments are reported to depend on the size of the molecules it can be speculated that different pH values at the site of hyaluronan degradation may result in different biological responses

Recombinant human hyaluronidase Hyal-1: insect cells versus E. coli as expression system and identification of low molecular weight inhibitors.

The human hyaluronidase Hyal-1, one of six human hyaluronidase subtypes, preferentially degrades hyaluronic acid present in the extracellular matrix of somatic tissues. Modulations of Hyal-1 expression have been observed in a number of malignant tumors. However, its role in disease progression is discussed controversially due to limited information on enzyme properties as well as the lack of specific inhibitors. Therefore, we expressed human Hyal-1 in a prokaryotic and in an insect cell system to produce larger amounts of the purified enzyme. In Escherichia coli, Hyal-1 formed inclusion bodies and was refolded in vitro after purification by metal ion affinity chromatography. However, the enzyme was produced with extremely low folding yields (0.5%) and exhibited a low specific activity (0.1 U/mg). Alternatively, Hyal-1 was secreted into the medium of stably transfected Drosophila Schneider-2 (DS-2) cells. After several purification steps, highly pure enzyme with a specific activity of 8.6 U/mg (consistent with the reported activity of human Hyal-1 from plasma) was obtained. Both Hyal-1 enzymes showed pH profiles similar to the hyaluronidase of human plasma with an activity maximum at pH 3.5-4.0. Deglycosylation of Hyal-1, expressed in DS-2 cells, resulted in a decrease in the enzymatic activity determined by a colorimetric hyaluronidase activity assay. Purified Hyal-1 from DS-2 cells was used for the investigation of the inhibitory activity of new ascorbic acid derivatives. Within this series, l-ascorbic acid tridecanoate was identified as the most potent inhibitor with an IC(50) of 50 +/- 4 microM comparable with glycyrrhizic acid