Extraction of label during processing of brain tissue for electron microscopic autoradiographic investigation of glycoprotein metabolism

Summary Rats were injected intracerebrally with (³H) fucose and survived for 30 min and 24 h. Following perfusion fixation with aldehydes, Vibratome sections of the brains were processed for embedding in resin and the radioactivity in the various solutions measured by scintillation counting. The decline of radioactivity was monitored in up to 18 successive buffer washes. Whereas 85% of the initial radioactivity could be eluted after 30 min, only 7% were extractable after 24 h survival time. Addition of unlabelled L-fucose to the fixative and buffers caused a small insignificant increase of the total radioactivity extracted. Only small amounts of radioactivity could be removed by treatment with trichloroacetic acid after extensive rinsing in buffer. It is concluded that thorough rinsing in buffer (which is more important with shorttime experiments) is effective in removing the acid-soluble radioactivity. An additional safe-guard lies in dehydration by ethanol. The ethanol series also removes acid-soluble radioactivity in addition to small amounts of what is probably higher molecular weight material.     

Uptake and intracellular transport in rat liver of formaldehyde-treated bovine serum albumin labelled with 125I-tyramine-cellobiose

1. Endocytosis of formaldehyde-treated bovine serum albumin by rat liver sinusoidal cells has been followed by injecting rats with the protein labelled with 125I-tyramine cellobiose (125I-TCfBSA). 125I-TCfBSA is quickly taken up by the liver; the radioactivity present in the organ reaches a plateau 5-10 min after injection and is maintained for up to at least 180 min. During the first 5 min most of radioactivity remains acid-precipitable. After which, labelled acid-soluble components are produced at a constant rate for up to 30-40 min. 2. Differential centrifugation shows that radioactivity is first recovered mainly in the microsomal fraction. Within a few minutes it exhibits a distribution pattern similar to that of lysosomal enzymes, being chiefly located in the mitochondrial fractions. 3. Isopycnic centrifugation in a sucrose gradient of the microsomal fraction isolated 1 min after injection indicates a similar distribution for radioactivity and alkaline phosphodiesterase. Later, the microsomal radioactivity distribution curve is shifted towards higher densities and becomes distinct from that of the plasma-membrane enzyme. After isopycnic centrifugation in a sucrose gradient of the total mitochondrial fraction a considerable overlapping of acid-precipitable and acid-soluble radioactivity distributions is observed without significant changes with time. The same is observed in a Percoll gradient except that after a relatively long time (greater than 30 min) of injection a marked shift of radioactivity distribution towards higher densities occurs. 4. A pretreatment of rats with Triton WR 1339, a density perturbant of liver lysosomes, causes a striking shift of acid-soluble radioactivity distribution in a sucrose gradient towards lower densities while having markedly less influence on the acid-precipitable distribution. As a result, a distinction between the distribution of both kinds of radioactivity becomes clearly apparent. A preinjection of yeast invertase, modifies the acid-soluble distribution without having a significant effect on the acid-precipitable distribution up to 30 min after 125I-TCfBSA injection. 5. Glycyl-1-phenylalanine-2-naphthylamide largely releases acid-soluble radioactivity associated with the mitochondrial fraction, whatever the time after 125I-TCfBSA injection. On the other hand the proportion of acid-precipitable radioactivity present in the fraction that can be released is almost zero at 10 min after injection, and it later increases. 6. The results presented here are best explained by supposing that, after being trapped in small pinocytic vesicles, 125I-TCfBSA is quickly delivered to the endosomes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Quantitative aspects of the uptake and degradation of lysozyme in the rat kidney in vivo

Uptake and degradation of lysozyme in the rat kidney were studied in vivo. The protein was labeled with 125I by way of a moiety (tyramine-cellobiose or 'TC') which remained trapped inside the cells even after proteolysis of the peptide chain (in contrast, the label from conventionally labeled proteins escapes after degradation). Following the injection of 'trapped-label' lysozyme, the radioactivity in the kidneys represented the total amount of lysozyme that was taken up during the experiment. Proteolysis could be followed by determining the amount of acid-soluble degradation products. By adding the radioactivity in the urine to that in the kidneys, a measure of the total filtered load was obtained. When only a trace dose of 125I-labeled TC lysozyme was injected into rats, the amount of radioactivity in the kidneys increased on average by 0.09% per min, after the concentration in the blood had become nearly stable. After 100 min, 30% of the injected dose was recovered in the kidneys. The labeled protein was degraded to acid-soluble molecules of Mr less than 1000. There was apparently a 'lag period' between the endocytosis in the kidneys and the start of degradation. 40 min after the injection of a trace dose, about 0.6% of the 'trapped-label' lysozyme in the kidneys was degraded per min.; subsequently, there was a decline in the fraction which was degraded per min. The amount of lysozyme in the urine increased after the injection of increasing amounts of lysozyme, showing that the capacity of the uptake mechanism was being exceeded, but truly saturating levels of lysozyme could not be reached in vivo.     

Stages of uptake and incorporation of micellar palmitic acid by hamster proximal intestinal mucosa

The stages of uptake and incorporation of micellar palmitic acid by hamster proximal intestinal mucosa were investigated by incubation of everted sacs at 4 degrees C and 37 degrees C for 2, 5, 10, and 15 min in a micellar solution (10 micro moles of [1-(14)C]palmitic acid, 10 micro moles of monoolein, and 100 micro moles of sodium taurodeoxycholate) and subsequent serial rinsing of the sacs in ice-cold solutions as follows: one 20-sec rinse in unlabeled micellar solution, five 1-min rinses in Krebs-Ringer buffer (0.15 m, pH 6.3), and ten 2-min rinses in 2.5% albumin solution. The fatty acid-solubilizing capacity of all the rinsing solutions was always in excess of the amounts of radioactive palmitic acid released during each rinse. Radioactivity was determined in the tissue homogenates, rinsing solutions, and serosal fluids. The results indicate that a significant proportion of radioactive palmitic acid taken up by the sacs during the short incubation was released into the rinsing solutions. Rinsing in Krebs-Ringer buffer resulted in release of 15.5 +/- 2.4% of the labeled fatty acid, and this fraction was independent of the temperature of incubation. In contrast, the amounts of palmitic acid released in albumin were significantly greater and were markedly dependent on the temperature of incubation; a total of 48.6 +/- 7.0% and 26.3 +/- 5.1% was released from sacs incubated at 4 degrees C and 37 degrees C, respectively. While the proportion of radioactive palmitic acid in the free fatty acid fraction of the tissue after the rinsing sequence remained reasonably constant regardless of the temperature and duration of incubation, the radioactivity of the esterified palmitic acid in the tissue was much greater in the sacs incubated at 37 degrees C and tended to increase linearly up to 10 min of incubation. A highly significant inverse relationship was found between the fraction of radioactive palmitic acid released by rinsing in albumin and the fraction of the label in the tissue esterified fatty acids. The results suggest that the initial uptake of micellar fatty acid by intestinal mucosa may involve reversible binding to superficial sites with at least two strengths of binding: a weak, temperature-independent binding which could be easily dissociated by rinsing in Krebs-Ringer buffer, and a stronger, temperature-dependent binding which could be dissociated by rinsing in albumin, but not in Krebs-Ringer buffer. Analogous binding of micellar palmitic acid occurred in a brush border preparation of proximal intestine which was devoid of any fatty acid esterifying activity. This suggested that the reversible binding of fatty acid by the intestinal mucosa may be a property of its superficial components, namely the glycocalyx or microvillous membranes, and that it may be independent of the esterifying capacity of the tissue.     

Uptake and degradation of 125I-labeled rat asialoorosomucoid by the perfused rat liver

The uptake and degradation of a homologous rat serum asialoglycoprotein, 125I-asialoorosomucoid, and the effects on this metabolism by leupeptin, a proteinase inhibitor, were studied in the perfused rat liver. 125I-Asialoorosomucoid was rapidly taken up by the liver (t1/2 = 5.7 min) and acid-soluble degradation products began to appear in the circulating perfusate medium after 20-30 min. These products accounted for 60-65% of the initially added radioactivity after 90 min of perfusion. The early events in the galactose-mediated uptake of 125I-asialoorosomucoid were unchanged by the presence of leupeptin. However, the appearance of acid-soluble degradation products was greatly reduced when livers had been pretreated with the inhibitor (1.0 mg for 60 min). This effect corresponded with an increase in acid-precipitable material being located within the lysosomal-rich fraction from homogenates of leupeptin-treated livers. Leupeptin inhibited degradation of 125I-asialoorosomucoid by approx. 85% relative to control values over 90 min of perfusion. Inhibition of asialoorosomucoid degradation was also demonstrated in vitro. Leupeptin (1.0 mM) reduced hydrolysis of this glycoprotein substrate by greater than 50% during a 24 h incubation with isolated lysosomal enzymes. The thiol proteinases, cathepsin B, H and L, which are known to be inhibited by leupeptin, are apparently involved in initiating digestion of rat 125I-asialoorosomucoid within liver lysosomes. As a result of inhibition by leupeptin both in the perfused liver and in vitro very limited changes occurred in the native molecular weight of the starting glycoprotein.     

Deglycosylated human chorionic gonadotropin. An antagonist to desensitization and down-regulation of the gonadotropin receptor-adenylate cyclase system

Human chorionic gonadotropin (hCG) was deglycosylated with anhydrous HF and compared with native hCG for binding and biological activity. The deglycosylated hormone (DG-hCG) had the same affinity as hCG for gonadotropin receptors in murine Leydig tumor cells (MLTC-1) but was less than 1% as potent as hCG in stimulating cyclic AMP production in these cells. Exposure of MLTC-1 cells for 30 min to hCG caused a desensitization of hCG-stimulated adenylate cyclase activity, whereas DG-hCG did not induce desensitization even after 4 h. hCG induced down-regulation of hCG receptors; by 4 h, 40% of the receptors had disappeared, whereas there was no receptor loss in cells exposed to DG-hCG for the same time. By 6 h, receptor down-regulation began to occur in the DG-hCG-treated cells and could be mimicked by exposing the cells to dibutyryl cyclic AMP or cholera toxin. Thus, the small increase in cyclic AMP generated by DG-hCG appears to result in some loss of receptors. Cells were incubated with iodinated hCG or DG-hCG for 30 min, washed, and incubated in fresh medium. Both bound ligands were degraded as measured by disappearance of cell-associated radioactivity and appearance of trichloroacetic acid-soluble label in the medium. The half-lives were 3 and 6 h for hCG and DG-hCG, respectively. Our results indicate that DG-hCG in contrast to hCG does not cause either rapid desensitization of hCG-stimulated adenylated cyclase or rapid down-regulation of hCG receptors. Therefore, receptor occupancy alone is insufficient to induce these phenomena.     

Hepatic and extrahepatic uptake of intravenously injected lipoprotein lipase

Rats were injected intravenously with 125I-labeled bovine lipoprotein lipase. The lipase disappeared within minutes from the blood due to uptake both in the liver (about 50% of the injected dose) and in extrahepatic tissues. Lipase enzyme activity disappeared in parallel to the 125I radioactivity. Thus, there was no inactivation of lipase in the circulating blood. Similar results were obtained when lipoprotein lipase purified from guinea pigs was injected into guinea pigs. Using supradiphragmatic rats we could show that the extrahepatic uptake was saturable and that the amounts of lipase that could be bound far exceeded the amounts of endogenous lipase expected to be present on the endothelium. When the lipase was denatured before injection, its removal in supradiaphragmatic rats became slower, and in intact rats the fraction of the uptake that occurred in extrahepatic tissues was much decreased. It is concluded that recognition by the extrahepatic receptors depends on the native conformation of the lipase. The extrahepatic uptake was strongly impeded by injection of heparin prior to injection of the lipase, and the uptake could to a large extent be reversed by injection of heparin after the lipase. Even after 1 h lipase that had been taken up by extrahepatic tissues reappeared immediately in the blood on injection of heparin. This was true both for enzyme activity and for enzyme radioactivity. Thus, internalization-inactivation-degradation occur only slowly in extrahepatic tissues. It is possible that the extrahepatic binding occurs to the enzyme's physiological receptors. The hepatic uptake was not dependent on the native conformation of the lipase, was less sensitive to heparin, could not be reversed by heparin and was not saturable. The enzyme was not rapidly inactivated after uptake; its activity could be detected in liver homogenates even after 1 h. Degradation to acid-soluble products in the liver was relatively slow; the t1/2 for native lipase was about 1 h. In comparison, in parallel experiments asialofetuin was degraded with a t1/2 of about 15 min.     

Rapid removal to the liver of intravenously injected lipoprotein lipase.

Lipoprotein lipase was purified from bovine milk and labeled with 125I. After intravenous injection to rats the labeled lipase rapidly disappeared from the blood. The initial half-life was about 1 min and more than 70% of the radioactivity was found in the liver at 10 min. 30 min after the injection about 10% of the injected radioactivity was present in acid-soluble form in blood, indicating that the enzyme had been rapidly degraded. Injection of asialofetuin, ribonuclease B or mannan in amounts known to block the hepatic receptors for glycoproteins with exposed galactose, N-acetylglucosamine or mannose residues did not retard the removal of the lipoprotein lipase. Thus, some other, as yet undefined, receptor is implicated. Lipoprotein lipase is known to bind to heparin and some related polysacchrides. Heparin injected before the enzyme delayed its removal and heparin injected after the enzyme caused an immediate increase in blood radioactivity, signifying return from tissues to blood of labeled enzyme. Lipoprotein lipase is present at the endothelium in several extrahepatic tissues and is rapidly turned over. Its presence in blood in appreciable amounts would cause a derangement of lipid transport. The efficient hepatic removal of the enzyme may thus serve an important physiological purpose in keeping the blood levels of this enzyme low.     

STUDIES ON LIVER REGENERATION: I. 131IODODEOXYURIDINE AS A PRECURSOR of DNA IN NORMAL and REGENERATING RAT LIVER

Abstract. ¹³¹Iododeoxyuridine (¹³¹IDU) was injected into normal and partially hepatectomized rats, and the specificity of incorporation of this thymidine analogue into liver DNA was determined 2, 24 and 48 hr following intramuscular injection. At 2 and 24 hr after ¹³¹DU injection, a major proportion of radioactivity in the liver was in the acid-soluble fraction, whereas 48 hr after injection the label in the acid-soluble fraction had decreased considerably. In liver obtained 2 hr after injection of ¹³¹IDU, only 1.8–16.6% of the total radioactivity were in DNA. If, however, the tissue was subjected to formalin fixation, the acid-soluble label was extracted selectively, and of the remaining radioactivity 64–88% was in DNA. Therefore, the radioactivity that is not extracted by formalin may be used as a measure of DNA synthesis at the time of injection of ¹³¹IDU, thus obviating time-consuming biochemical fractionation procedures.     

LABELING OF MURINE MASTOCYTOMA CELLS IN VITRO WITH PLASMA TRITIATED THYMIDINE-LABELED ANIMALS

40 min after injecting tritiated thymidine into an animal, 20–30% of the total plasma radioactivity is nonvolatile. This fraction decreases to about 6% 10 hr after the injection and 3% 24 hr after the injection. There appears to be material in this nonvolatile fraction that can label mastocytoma cells in culture. The labeling indices decrease with time after injection in the same way as the nonvolatile fraction. The 40 min plasma sample contains sufficient material to allow accurate assessment of the fraction of cells in S in culture after a 6 wk exposure. The circulating material is not apparently available for incorporation into those cells in cycle in the donor animal. The material appears to be related to the G₀ cell-specific pool that has been described elsewhere. The trichloroacetic acid-soluble or ethanol-soluble nonvolatile activity appears to contain thymine, and some thymidine-phosphorylated compounds.     

Incorporation of [1-14C]Palmitic Acid into Neutral Lipids and Phospholipids of Rat Cerebral Cortex In Vitro

Abstract: Incorporation of [1-¹⁴C]palmitic acid into neutral lipids and phospholipids of rat cerebral cortex was examined in vitro in normal Krebs-Ringer bicarbonate buffer containing 3% (wthol) albumin and 0.75 mM palmitic acid. Under standard assay conditions, radioactivity in the triacylglycerol fraction increased rapidly during the first 30 min, and then decreased after 60 min, with corresponding increase in radioactivity in phosphatidyl choline, phosphatidyl ethanolamine, and a fraction of phosphatidyl inositol plus phosphatidyl serine. Diacylglycerol was shown to be an intermediate metabolite. Radioactivity increased in triacylglycerol, and decreased in phosphatidyl choline and phosphatidyl ethanolamine throughout incubation under NZ gas. In the fraction of phosphatidyl inositol plus phosphatidyl serine, radioactivity decreased after 30 min during incubation under N, gas. A possible acylation-deacylation cycle, in which triacylglycerol could be a source of free fatty acids for phospholipids, is discussed.     

Metabolites of estradiol in serum, bile, intestine and feces of the domestic cat (Felis catus )

We wished to develop an efficient, noninvasive method for monitoring ovarian function in domestic and nondomestic Felidae. We hypothesized that the method could be based on measurement of one of the major excreted estrogen metabolites. To identify and characterize the major excreted metabolites, a bolus of (14)C-estradiol was administered into the femoral vein of adult female cats. We measured the amounts of total radioactivity per unit time contained in unconjugated and conjugated estradiol metabolites, in conjugated metabolites that were hydrolyzable, and in those not hydrolyzable by beta Glucuronidase / aryl sulfatase (the enzyme). Radionuclide levels were determined in voided feces and urine, in jugular vein plasma, bile, contents of the duodenum, and in the small intestine. Metabolites of (14)C-estradiol were voided preferentially in feces and in equal amounts either as unconjugated estradiol or as conjugates not hydrolyzable by the enzyme. In plasma, conjugated estrogens comprised an increasing proportion of the total radioactivity during the first 40 min after administration. Plasma pools of samples from 0.5 to 30 min and 40 to 360 min contained a monoconjugate and a diconjugate, respectively; both were hydrolyzable by the enzyme. Bile and intestinal samples were collected at 360 min after administration. In the bile, 99% of the total radioactivity was in conjugated compounds, only 20% of which were not hydrolysable by the enzyme. The proportion of unconjugated metabolites increased to 18% in the duodenum and to 45% in the small intestine. The major conjugates contained in voided feces not hydrolyzable by the enzyme were estradiol sulfate (m/z = 351.6836), distributed as the 3-sulfate (20%) and 17-sulfate (80%); of the latter, 70% were 17alpha- and 30% 17beta-estradiol sulfates. These data document the fate of estradiol in the circulation of the cat, they demonstrate that a large portion of the voided estradiol metabolites are not hydrolyzable by the enzyme, and account for those conjugates previously termed nonhydrolyzable.     

Substantivity of zinc salts used as rinsing solutions and their effect on the inhibition of Streptococcus mutans

The antimicrobial efficacy of zinc (Zn) salts (sulfate and acetate) against Streptococcus mutans (S. mutans) present in the oral cavity was tested in this study. The substantivity of Zn salts was assessed by determining the concentration of Zn in whole, unstimulated saliva and by measuring the magnitude of suppression of salivary S. mutans, 2h after rinsing. The concentration of Zn was measured by atomic absorption spectrometry (AAS) with electrothermal atomization (ET AAS) in saliva sampled before (basal) and 24h after mouth rinsing with different concentrations of Zn (0.1%, 0.5% and 1%) administrated as sulfate and acetate. The estimation of Zn levels in samples collected 30, 60, 90 and 120 min after rinsing was carried out by AAS with flame atomization (FAAS). Immediately after rinsing, the concentration of Zn in saliva sharply increased with respect to the baseline values (0.055+/-0.017 mg/L), followed by a sustained decrease, probably due to clearance of salivary flow or swallowing during sampling. A significant reduction (>87%) in the total mean S. mutans counts was found 2h after rinsing either with sulfate or acetate solutions, as evidence of the high substantivity and effectiveness of the Zn salts tested. A statistically significant inverse relationship (p<0.001 and the Pearson correlation coefficients between -34% and -50%) was found between Zn levels and the respective pH values measured in the samples collected 60 and 120 min after rinsing, sustaining the theory of bacterial glycolysis inhibition.     

Measurement of local rates of brain protein synthesis by quantitative autoradiography: Validation with L-[3H]valine

Following the injection of 4-day old rats with 150 mMl-[3,4-³H]valine (10mol/g, IP) the incorporation of³H into protein was linear 2 hours. Valine specific activity in the brain acid-soluble fraction was constant between 30 and 120 min after injection with a mean value of 82.3% of the injectate. Significant amounts of tritated metabolites accumulated in the brain acid-soluble fraction (41.4% of radioactivity at 120 min) but do not prove an impediment to measuring rates of protein synthesis. The rate of protein synthesis in cerebral cortex of the 4-day old rat was measured by quantitative autoradiography using [³H]valine and³H-sensitive film. The measured rate shows excellent agreement with that found previously usingl-[1-¹⁴C]valine. Our results suggest that [³H]valine can be a useful precursor to measure local rates of brain protein synthesis by quantitative autoradiography.     

EFFECT OF ACTINOMYCIN-D ON LABELLED MATERIAL IN THE RETINA AND OPTIC TECTUM OF GOLDFISH AFTER INTRAOCULAR INJECTION OF TRITIATED RNA PRECURSORS

—After injection of [³H]guanosine or [³H]uridine into the eye of goldfish, labelled acid-soluble radioactivity and RNA appeared in the contralateral optic tectum. When 0·1 μg actinomycin-D was injected into the eye 4 h before the precursor, the labelled RNA in the retina by 18 h after the injection was only 23 per cent of normal, but the acid-soluble radioactivity in the retina and the small amount of labelled acid-soluble material conveyed to the tectum were not significantly affected; by 15–20 days after the injection the acid-soluble radioactivity in the retina was reduced and the amount of labelled material conveyed to the tectum, including both RNA and acid-soluble fractions, was less than normal. When the actinomycin was injected at various times before or after the precursor and measurements were made 6 days later, it was found that the amount of labelled RNA conveyed to the tectum was maximally decreased if the inhibitor was given simultaneously with or up to 4 h before the precursor, whereas the amount of RNA was normal if the incorporation of the precursor had been allowed to proceed for 12 h before the inhibitor was given. This result would be consistent with the view that much of the RNA conveyed to the tectum had been synthesized in the retina within 12 h of the injection of the precursor, and had then presumably been axonally transported in the optic nerve to the tectum. However, since the acid-soluble material conveyed to the tectum was also reduced as a result of the actinomycin treatment, the results of these experiments with actinomycin do not unequivocally rule out the possibility that the RNA appearing in the tectum had been locally synthesized from the axonally transported acid-soluble material. In the retina, both the labelled RNA and acid-soluble fractions were reduced, to about 15 and 60 per cent of normal, respectively, without any relationship to the time between the injection of inhibitor and precursor. The discrepancy between the effects of the labelling of the retina and the labelling of material conveyed to the tectum could be correlated with the fact that the actinomycin caused severe damage to the retinal receptor cells, while leaving the ganglion cells relatively intact. The more pronounced effect of actinomycin on the receptor cells could in turn be correlated with the fact that these cells had a higher rate of RNA synthesis than the ganglion cells. This was demonstrated autoradiographically by the higher rate of incorporation of [³H]uridine into the receptor cells. Intracranial injection of actinomycin did not affect significantly the amount of labelled RNA conveyed to the tectum, which would argue against the local synthesis of this RNA. It is not certain, however, that the actinomycin penetrated deeply enough into the tectum to be effective.     

In vivo studies on the metabolism of pyrimidine nucleosides (author's transl)]

3H-labelled metabolites were determined in the perchloric acid-soluble fraction of blood plasma and liver of adult male Wistar rats, following the application of [5 - 3H]uridine. Ten minutes after the injection of uridine, only 20% of the total 3H activity of the plasma could be attributed to [3H]uridine. The remaining radioactivity was found chiefly in [3H]uracil (40%) and 3H2O (20%). In the liver, at 10 min, [3H]-uridine and [3H]uracil together accounted for less than 0.5% of the total radioactivity; about 70% of the radioactivity was due to [3H]beta-alanine, and 15% to 3H2O. 45 min after the injection, 70% of the radioactivity in the plasma was due to 3H2O, whereas uridine and uracil represented about 4% and 6%, respectively. At this time, about 55% of the radioactivity in the liver was due to [3H]beta-alanine, about 40% to 3H2O, and about 5% to unidentified metabolites; [3H]uridine and [3H]uracil were not observed. A comparison of the rate of catabolism of [5-3H]-uridine, [5-3H]cytidine and [6-3H]thymidine showed that cytidine is degraded in the organism 25 times more slowly than uridine or thymidine. The biological half lives for the total degradation of the [3H]nucleosides to 3H2O, based on the values in the plasma, were: uridine 1.1 h; thymidine 1.3 h; cytidine 25 h. Furthermore, the turnover time of exogenous uridine in the plasma was found to be 9 min, which gives a half life of 6 min for the metabolism of exogenous uridine to uracil.     

Effects of Chronic Ethanol Administration on Rat Brain Phospholipid Metabolism

Alterations in brain phospholipid metabolism were observed after chronic ethanol administration for 16 days to developing rats. Animals were injected intraperitoneally with 32Pi 16 h prior to killing. Overall uptake of 32Pi by brain did not differ between the control and ethanol-treated groups, which were killed 2 h and 24 h after the last ethanol feeding. Except for an increase in the labeling of myelin after ethanol treatment, the amount of radioactivity recovered in the synaptosomal-mitochondrial and plasma membrane fractions of control and ethanol-treated groups was not different. Relative to the radioactivity of phosphatidylcholines, which indicated no change, there were increases (20-44%) in labeling of ethanolamine plasmalogens, phosphatidic acids, and phosphatidylinositols in cortical synaptosomes from the 2-h ethanol-treated group. In the plasma membrane fractions, however, increases (9-14%) in labeling of phosphatidylserines and phosphatidylinositols were observed in both 2- and 24-h ethanol-treated groups. In both membrane fractions, there was an obvious increase (44-86%) in labeling of polyphosphoinositides at 24 h after withdrawal from ethanol. Results thus indicate an adaptive increase in the biosynthesis of ethanolamine plasmalogen and brain acidic phospholipids due to chronic ethanol administration. Furthermore, the increase in labeling of polyphosphoinositides in the 24-h withdrawal group may reflect the hypoactivity associated with ethanol withdrawal.     

Metabolism of high-density lipoproteins in cultured rat luteal cells

The uptake of cholesterol from high-density lipoproteins (HDL) labeled with 125I and [3H]cholesterol was examined in cultured rat luteal cells. Luteal cells were incubated with labeled HDL, following which the metabolic fate of the apolipoproteins and cholesterol moieties of the receptor-bound HDL were examined. About 50% of the originally bound HDL apolipoproteins were released into the medium in 24 h by a temperature-dependent process while only 5% of the HDL cholesterol was released unmetabolized. Inclusion of unlabeled HDL in the chase incubation resulted in increased release of apolipoprotein-derived radioactive products without significant change in the release of unmetabolized cholesterol. 60% of the apolipoprotein-derived radioactivity could be precipitated with trichloroacetic acid; the remaining trichloroacetic acid-soluble radioactive fraction was identified as [125I]iodotyrosine. Gel filtration chromatography of the chase-released material showed that the trichloroacetic acid-precipitable products, which contained no detectable amounts of cholesterol, eluted over a range of molecular sizes (9-80 kDa). No intact HDL was retroendocytosed. About 80% of trichloroacetic acid-precipitable products could be immunoadsorbed on anti-apolipoprotein A-I antibody immobilized on CNBr-activated Sepharose, suggesting the presence of fragments containing apolipoprotein A-I. This material was also capable of reassociating with native HDL. Lysosomal inhibitors were partially effective in inhibiting the amount of trichloroacetic acid-soluble products formed. The lysosomal degradation appeared to have no role in the uptake of HDL-derived cholesterol. These studies demonstrate preferential and total uptake of HDL cholesterol by luteal cells, with concomitant degradation of the lipoprotein.     

Metabolism of Adenine and Hypoxanthine in a Hormone Autonomous Genetic Tumour Line of Tobacco

Genetic tumour tissues of Nicotiana glauca (Grah.) × N. langsdorffii (Weinm.), which grow on auxin and cytokinin-free medium, were incubated with [14C]-/[3H]-adenine or [3H]-hypoxanthine to investigate cytokinin biosynthesis. Adenine was supplied to tissues of two different ages (2- and 3.5-week-old) for 8, 24 or 30 h. The uptake was over 91.0 % (of "supplied radioactivity") by 2-week-old tissues as compared to around 50.0 % uptake by 3.5-week-old tissues. Incorporation into cytokinins could not be detected. While unmetabolized adenine accounted for only about 24.0 and 13.4 % of "extracted radioactivity" (following 8 and 30 h incubation, respectively) in 2-week-old tissues, relatively higher levels, i.e. 36.0 and 34.5 % (following 8 and 24 h incubation, respectively) were present in 3.5-week-old tissues. The metabolites formed were adenosine and its nucleotides (4.5 - 16.5 % and 37.4 - 60.2 % of the extracted radioactivity, respectively). Hypoxanthine was supplied to 3.5-week-old tissues for 8 and 24 h. While the uptake was low (<28.0 % of supplied radioactivity), the major proportion of extracted radioactivity was due to unmetabolized hypoxanthine (79.8 % and 85.9 % after 8 and 24 h incubation periods, respectively); the minor metabolites were inosine and adenosine (both <0.5 %) and their nucleotides (< 3.5 %). Radioactivity incorporation into cytokinins from hypoxanthine was not detected. Thus in the present investigations precursor incorporation from either adenine or hypoxanthine into cytokinins could not be demonstrated. It is possible that this may be due to slow rate of cytokinin turnover in these tissues.     

Kinetic studies of glutaraldehyde binding in liver

To study the kinetics of glutaraldehyde fixation, fresh rabbit liver cubes were immersed in 3% buffered ³H-glutaraldehyde for various periods of time. Following weighing and a brief rinse in water, the tissues were solubilized, and the radioactivity was measured in a scintillation counter. Binding of the isotope was half-maximal after approximately 4 h and a plateau was reached after approximately 20 h. We also investigated the reversibility of glutaraldehyde fixation. Fixed liver cubes were weighed and immersed in water for various periods of time, and after solubilization, the radioactivity was determined. After rinsing for 48 h, approximately 95% of the radioactivity was lost from the tissue specimens, indicating that fixation with glutaraldehyde is largely reversible. Light and electron microscopy of specimens rinsed for 1 and 48 h showed essentially similar morphology. Rinsing for 48 h restored some of the immunoreactivity that was absent after rinsing for only 1 h.