Iron and phosphorus content of rabbit liver ferritin fractions with different subunit composition

After isolation of subtypes of rabbit liver-ferritin, the phosphorus to iron ratio (P/Fe-ratio) in the samples was found to parallel the shift in subunit composition of the two types of subunits of which ferritins generally consist. No relation was found with the amount of iron per ferritin molecule. The increase of the P/Fe-ratio, in relation to subunit composition, is postulated to be a result of the change of total surface area of the iron microcrystallites inside the ferritin molecule. This surface area depends on the number of nucleation points and thereby may be dependent on the subunit composition.     

Bicarbonate ion-ATPase in rat liver cell fractions.

The distribution of HCO3MINUS-ATPase activity was studied in cell fractions prepared from homogenates of rat liver. The level of mitochondrial contamination in the microsomal fraction depended on the fractionation procedure and on the method of homogenization. With proper care, microsomes with undetectable mitochondrial contamination could be prepared. These microsomes had no detectable HCO3MINUS-ATPase activity. Approximately 85% of the total HCO3minus-ATPase activity of the post 6000 times g-min supernatant was recovered in the mitochondrial fraction. The properties of this mitochondrial HCO3minus-ATPase were not distinguishable from those of the various microsomal HCO3minus-ATPases previously described by other investigators.     

Distribution of adenylate cyclase among membrane fractions of rat liver.

Adenylate cyclase activity was detected in plasma membranes, Golgi apparatus, and endoplasmic reticulum from rat liver. Adenylate cyclase activities of purified membranes were determined biochemically by two methods. In one, the synthesis of radioactive cyclic AMP from ATalpha32P was monitored. In the other, the synthesis of cyclic AMP was quantitiated using a protein which specifically binds cyclic AMP. The enzyme activity was responsive to activation by both glucagon and sodium fluoride although differences in degree of activation were noted comparing plasma membrane, Golgi apparatus, and endoplasmic reticulum. Cytochemical studies, using both whole tissue and purified cell fractions and conducted in parallel, confirmed the biochemical results. Deposition of lead phosphate, enhanced by glucagon and NaF with samples incubated with appropriate substrates, was not restricted to plasma membranes of hepatocytes but was present in intracellular membranes as well. Adenylate cyclase of rat hepatocytes appears more widely distributed among internal membranes than previously recognized.     

Lithocholic acid-cholesterol interactions in rat liver plasma membrane fractions

This study was designed to elucidate the steps involved in the incorporation of lithocholic acid and the increase in cholesterol in liver plasma membranes after lithocholic acid injection. In vitro, cholesterol incorporation or binding to liver plasma membrane fractions enriched in bile canalicular structures occurred only when cholesterol was added simultaneously with lithocholic acid. The addition of cholic acid did not prevent the incorporation or binding of lithocholic acid and of cholesterol. However, when cholic acid was incubated with membranes already containing lithocholic acid and cholesterol, the ratio of cholesterol to lithocholic acid increased from 2 to more than 3 via a reduction of lithocholic acid. The binding of lithocholic acid and cholesterol to membranes rose 5-fold in the presence of cytosolic proteins. By electron microscopy the canalicular membrane structures with a high cholesterol content exhibited few microvilli, and their lumen appeared to have collapsed. These data suggest that simultaneous interaction of lithocholic acid and cholesterol, and not prior incorporation or binding of lithocholic acid to the membrane, may be a prerequisite to cholesterol accumulation in the membrane.     

Biosynthesis of liver catalase in rats treated with allylisopropylacetylcarbamide. I. Immunochemical assay of catalase in liver cell fractions.

Rats were injected twice intraperitoneally with 20 mg of allylisopropylacetylcarbamide (Sedormid) per 100 g of body weight at an interval of 12 hr. The level of catalase [EC 1.11.1.6] in various liver cell fractions was determined both enzymatically and immunochemically 12 hr after the second injection. 1. The decrease in catalase protein assayed by the immunochemical method directly confirmed the inhibition of biosynthesis of the enzyme by this porphyrinogenic drug. 2. The occurrence of a considerable amount of catalase protein with no enzymatic activity was demonstrated both in the peroxisomes and in the supernatant fraction. 3. The amount of catalase-synthesizing polysomes in hepatic cell was reduced in Sedormid-treated rats by the extent comparable to the decrease in the concentration of liver catalase.     

Cholinesterase activities in subcellular fractions of rat liver: Association of acetylcholinesterase with the surface membrane and other properties of the enzyme

Rat liver contains two cholinesterase activities: “true” or acetylcholinesterase (EC 3.1.1.7) and pseudocholinesterase (EC 3.1.1.8). Differences in subcellular distribution are observed between the two activities.Subcellular fractions rich in surface membrane are observed to be enriched with respect to acetylcholinesterase; this distribution is different from that of pseudocholinesterase and non-specific esterase. The activity in surface membrane preparations cannot be accounted for by contamination of the fraction with membranes derived from other subcellular organelles, or by erythrocyte membranes.The behaviour of the cholinesterases towards several acetylcholine analogues is described, together with several inhibition and kinetic properties.     

Topology of asialoglycoprotein receptor in rat liver subcellular fractions: a ferritin immunoelectron microscopic study

Direct ferritin immunoelectron microscopy was used to visualize the asialoglycoprotein receptor in various rat liver subcellular fractions. The cytoplasmic surfaces of cytoplasmic organelles such as the rough and smooth microsomes, Golgi cisternae and lysosomes showed hardly any ferritin label exception for the slight labeling of secretory granules found mainly in the light Golgi fraction (GF1). Occasionally, however, open membrane sheet structures, smooth vesicular or tubular structures heavily labeled with ferritin, were present in all these subcellular fractions. These structures probably correspond to fragmented sinusoidal or lateral hepatocyte plasma membranes recovered to these subcellular fractions. When the limiting membranes of the secretion granules were partially broken by mechanical force, a number of ferritin particles frequently were seen attached in large clusters to the luminal surface of the membrane, the cytoplasmic surface of the corresponding domain being slightly labeled. These observations are strong evidence that the receptor protein is never translocated vertically throughout the intracellular transport from ER to plasma membrane via Golgi apparatus and from plasma membrane back to trans-Golgi elements and also in lysosomes, always exposing the major antigenic sites to the luminal or extracellular surface and the minor counterparts to the cytoplasmic surface of the membranes. The receptor protein also is suggested to be concentrated in clusters on the luminal surface of secretion granules when they form on the trans-side of the Golgi apparatus.     

Association of sialic acid with microsomal membrane structures in rat liver

The amount of sialic acid on phospholipid basis increases from rough, through smooth II and smooth I microsomes, to Golgi membranes, all of them free from most of the adsorbed and luminal protein. The incorporation rate of glucosamine-³H into sialic acid also follows a similar order. Deoxycholate removes phospholipid and sialic acid to an identical extent, and a significant part of the latter remains after trypsin and neuraminidase treatment. The sialic acid/phospholipid ratio decreases in phenobarbital-induced smooth but not in rough membranes, while the incorporation rate of glycosamine-³H into sialic acid decreases in both subfractions.     

Permeability of the liver cell membrane to quinolinate.

Quinolinate was taken up by both rat and guinea-pig liver cells. Equilibrium was reached after approx. 20 min with rat cells, but guinea-pig cells had not achieved a steady state after 60 min. There was no evidence to suggest that quinolinate is rapidly metabolized by either species. The concentrations of quinolinate attained in rat and guinea-pig cells after short periods of incubation with 0.5 mM-quinolinate did not inhibit gluconeogenesis. These results raise further doubts as to the mechanism of quinolinate action in liver.     

Distribution of phosphatidylinositol biosynthetic activities among cell fractions from rat liver.

The distribution of activities for synthesis of phosphatidylinositol among cell fractions from rat liver was determined. Activity was concentrated in endoplasmic reticulum; rough and smooth fractions were nearly equal. Golgi apparatus exhibited a biosynthetic rate 44% that of endoplasmic reticulum. Plasma membranes and mitochondrial fractions were only 6% as active as endoplasmic reticulum. Thus, endoplasmic reticulum and Golgi apparatus fractions from rat liver catalyze the net synthesis of phosphatidylinositol in vitro, whereas plasma membrane and mitochondrial fractions do not.