Caffeine does not bind covalently to liver microsomes from different animal species and to proteins and DNA from perfused rat liver

Caffeine was found not to bind covalently to liver microsomal proteins from mice, rats and rabbits. Microsomes metabolized caffeine only to a limited extent, the highest rate (about 2% of the substrate concentration) being obtained with rabbit microsomal preparations. The rat liver perfusion technique represents a good model for in vitro caffeine biotransformation studies and therefore for covalent binding experiments. After 2 h perfusion caffeine was extensively metabolized mainly to dimethyl and monomethyl xanthines, a minor pathway to 1,3,7-trimethyluric acid was also seen. However, covalent binding studies using the liver perfusion technique did not reveal any appreciable amount of caffeine metabolites irreversibly bound to either microsomal and total proteins and to DNA

Secretion of lipoproteins, apolipoprotein A-I and apolipoprotein E by isolated and perfused liver of rat with experimental nephrotic syndrome.

Nephrotic syndrome induced in the rat by the administration of puromycin aminonucleoside is accompanied by a hyperlipoproteinemia characterized by an elevation of all plasma lipoproteins, particularly of VLDL (1.006 g/ml) and HDL1 (1.050-1.090 g/ml). The increase of HDL1 is due to the accumulation of a lipoprotein species floating mainly in the density interval 1.050-1.090 g/ml, in which apolipoprotein A-I replaces apolipoprotein E as the major constituent peptide. This lipoprotein has been designated nephrotic HDL. The present study was conducted to establish whether nephrotic liver secreted more lipoproteins than the control liver and, in addition, produced a lipoprotein similar to nephrotic HDL found in plasma. Isolated livers from control and nephrotic rats were perfused with a lipoprotein-free medium for 3 h in a recirculating system. Lipoproteins were isolated by ultracentrifugation; apolipoprotein A-I and apolipoprotein E were measured in the whole perfusate at various time intervals. Nephrotic liver secreted twice as much VLDL and HDL2 and 30% more LDL and HDL1 than the control liver. This was accompanied by an increased secretion of both apolipoprotein A-I and apolipoprotein E, the levels of which were 6.5- and 2-fold, respectively, of those found in the control perfusates at the end of the perfusion. In view of the increased secretion of apolipoprotein A-I, the apolipoprotein A-I to apolipoprotein E ratio was much higher in the perfusates of nephrotic livers than in those of the controls. The concentration of apolipoproteins A-I and E in plasma of nephrotic rats was 7- and 2-fold, respectively, of that found in the plasma of the controls. In the perfusates of the nephrotic livers, we could not find a HDL1 (1.050-1.090 g/ml) rich in apolipoprotein A-I similar to that isolated from plasma (nephrotic HDL). We suggest that the latter is formed in the circulation from the intravascular modification of HDL2 secreted in excess by the li

Bone invasion by Walker 256 carcinoma, line A in young and adult rats: effects of etidronate

Line A of Walker 256 carcinoma implanted in the muscle adjacent to the tibia of young (6 weeks) and adult (9 months) male rats invaded the bone. Osteolysis and reactive growth were greater in the bone of young animals than in adults. Ethane-1-hydroxy-1,1-bisphosphonate prevented bone lysis and tumor invasion of the cortex both in young and adult animals. This model may be useful for studies of age-related differences in tumor infiltration into the bone and for investigating drug effects on this process