Biological half-lives of bromide and sodium in the rat are connected and dependent on the physiological state

The parallel course of the excretion rates of sodium and bromide ions was demonstrated in adult male rats administered simultaneously with ²⁴Na-sodium chloride and ⁸²Br-bromide. These excretion rates were inversely proportional to the magnitude of sodium intake in the animals. The biological half-life of bromide, as a substitute for sodium or chloride, was investigated with the aid of the radionuclide ⁸²Br in animals situated in very different physiological states (i.e., in lactating and nonlactating female rats as well as in young rats of varying ages [2,4,6, and 10 wk of age]). The ⁸²Br radioactivity retained in mothers and in whole litters was measured in vivo at appropriate time intervals (up to 240 h) after the application of ⁸²Br-bromide to the mothers. The time-course of the changes in the ⁸²Br radioactivity of the young was calculated as the difference between the rate of ⁸²Br intake in the mother's milk and the ⁸²Br excretion through the kidneys into the urine. The rate of ⁸²Br excretion through the kidneys of the dam could be calculated also. Nonweaned young rats (12 d) had the highest half-life (269 h) and lactating dams had the lowest (44 h). The determined values demonstrated that nonweaned young apparently conserve sodium, because of its relatively low concentration in mother's milk, whereas lactating dams, because of their large food intake, waste sodium. Presented in part at the 4th International Symposium on Trace Elements in Human: New Perspectives held in Athens (Greece) on 9–11 October 2003     

Bromide kinetics and distribution in the rat. I

Biological half-lives of bromine in 15 different organs and tissues of the rat, in addition to the whole-body half-life, were determined by measuring the radioactive concentration of 82Br-bromide in samples of tissues collected at the time intervals of 12-396 h from animals that continuously (up to 17 d) received 82Br-labeled bromide in their drinking water. The half-life values, calculated from the experimental data by the method of gradual estimates of the parameters in question with the SPSS statistical program, ranged from 94.3+/-14.6 h in the thyroid gland to 235.0+/-88.9 h in liver. In most of the studied tissues, the biological half-lives of bromine were shorter than in the whole body, in which it equaled 197.8+/-22.2 h. Significant correlation between the values of the steady-state concentration of bromide and of the biological half-life was found for most tissues (except for liver). The steady-state concentrations of 82Br in tissues are probably proportional to the magnitude of bromide space, and, consequently, of chloride space.     

Biological half-life of bromide in the rat depends primarily on the magnitude of sodium intake

The parallel course of the excretion rates of bromide and sodium ions was demonstrated in adult male and female rats administered simultaneously with potassium 82Br-bromide and 24Na-sodium chloride. The animals were exposed to various intakes of sodium ions accompanied with five different anions: Br-, Cl-, HCO3-, ClO4-, and SCN-. Regardless of the anion accompanying the sodium ion, the excretion rates of 82Br- and 24Na+ ions were proportional to the magnitude of sodium intake in the animals. Hence, we have proved our hypothesis that the biological half-life of bromide depends on the magnitude of sodium intake rather than on the intake of chloride.     

Extracellular volume estimation from ratios of bromide to chloride in urine or saliva.

Use of either urine or saliva samples to estimate extracellular water volume was investigated in 10 men using nonradioactive bromide (Br) and in seven newborn piglets using radioactive Br (82Br) and chloride (36Cl). The relation to Br to Cl concentrations in urine enabled an estimation of Br dilution volume from human urine (267 +/- 42 ml/kg, mean +/- SD) that was not significantly different (P = 1.0) from the Br dilution volume calculated from plasma Br concentration (268 +/- 20 ml/kg). Although the Br dilution volume estimated from saliva was not different from that of plasma, the error in the estimates of Br dilution volume from saliva was too large (mean difference, -36 +/- 64 ml/kg) to make its use practical. The data from piglets showed good agreement between 82Br and 36Cl dilution volumes calculated from 4-hr plasma samples (356 +/- 14 ml/kg and 347 +2- 12 ml/kg; P greater than 0.1) and between 82Br dilution volumes calculated from urine 82Br:36Cl and plasma 82Br (360 +/- 31 ml/kg and 356 +/- 14 ml/kg; P greater than 0.1). Extracellular water volume can be estimated in both adult and young animals using the Br dilution volume calculated from urine samples. It requires (i) two urine collections: one before and one 4 to 8 hr after administration of Br; (ii) a measurement or estimate of plasma Cl concentration; and (iii) a correction factor that describes the relationship of the ratio of Br to Cl in urine to that ratio in plasma.     

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.     

Effect of starvation and refeeding on amino acid uptake by mammary gland of the lactating rat. Role of ketone bodies.

Arteriovenous differences of amino acids across the mammary glands of lactating rats are diminished when the rats are starved for 24 h. When 24 h-starved rats were refed for 2 1/2 h, the arteriovenous differences of amino acids returned to values similar to those found in well-fed rats. In order to find a possible explanation for these rapid changes, we tested the effect of ketone bodies on amino acid uptake by the gland. At 5 min after injection of acetoacetate to fed rats, when the total concentration of ketone bodies in blood was similar to that found in starvation, the uptake of amino acids by the mammary gland was similar to that found after starvation, i.e. lower than in fed rats. However, 30 min after administration of acetoacetate, when the arterial concentration of ketone bodies had returned to values similar to those in fed rats, the arteriovenous differences of amino acids were similar to those found in fed rats. We conclude that the changes in blood ketone bodies may be responsible, at least in part, for the changes in amino acid uptake that occur in starvation and in the starvation--refeeding transition.     

Radiobromine labeled norcholesterol analogs. Synthesis and tissue distribution study in rats of bromine-82 labeled 6β-bromomethyl-19- norcholest-5(10)-en-3β-ol

6β-Bromomethyl-19-norcholest-5(10)-en-3β-o1 (NCL-6-Br) was synthesized directly from cholest-5-ene-3β,19-diol 19-toluene-psulfonate $\text{via}$ homoallylic rearrangement with ammonium bromide or sodium bromide in acetonitrile. This method was applied to the radiolabeling of NCL-6-Br with bromine-82. Tissue distribution of bromine-82 labeled NCL-6-Br (NCL-6-Br-82) in rats was determined. The mean percent dose per gram uptake in adrenal at 24 and 120 h was 98 and 80 %/gm, respectively, which indicated a higher adrenal uptake as compared to iodine-131 labeled 19-iodocholest-5-en-3β-o1 (CL-19-I-131), but was at a lower level than that achieved with iodine-131 labeled 6β-iodomethy 119-norcholest-S(10)-en-3β-o1 (NCL-6-I-131). The ratio of radioactivity in the adrenal-to-liver concentration was also lower than that of CL-19-I-131 or NCL-6-I 131.     

Effects of dextranation on the pharmacokinetics of short peptides. A PET study on mEGF

The effects of dextranation on the biodistribution of mouse epidermal growth factor (mEGF, 6 kDa) were assessed. By reductive amination, mEGF was coupled to 13 and 46 kDa dextran. The two dextranated conjugates and free mEGF were labeled with the positron-emitting nuclide (76)Br (T(1/2) = 16 h). After intravenous administration to Sprague Dawley rats, the radioactivity biodistribution was evaluated by positron emission tomography (PET) and by measurements of dissected tissues. The dextranation prolonged the retention time in blood, especially when the dextran chain was long. [(76)Br]mEGF-dextran conjugates were shown to have significantly, more than 5 times, lower kidney accumulation than the nonconjugated [(76)Br]mEGF. In conclusion, dextranation affects the biodistribution of mEGF in vivo giving a prolonged circulation time, a decreased uptake in kidney, and an increased spleen accumulation.     

Metabolic interactions of dichloroacetate and insulin in experimental diabetic ketoacidosis.

1. The infusion of sodium dichloroacetate into rats with severe diabetic ketoacidosis over 4h caused a 2mM decrease in blood glucose, and small falls in blood lactate and pyruvate concentrations. Similar findings had been reported in normal rats (Blackshear et al., 1974). In contrast there was a marked decrease in blood ketone-body concentration in the diabetic ketoacidotic rats after dichloroacetate treatment. 2. The infusion of insulin alone rapidly decreased blood glucose and ketone bodies, but caused an increase in blood lactate and pyruvate. 3. Dichloroacetate did not affect the response to insulin of blood glucose and ketone bodies, but abolished the increase of lactate and pyruvate seen after insulin infusion. 4. Neither insulin nor dichloroacetate stimulated glucose disappearance after functional hepatectomy, but both agents decreased the accumulation in blood of lactate, pyruvate and alanine. 5. Dichloroacetate inhibited 3-hydroxybutyrate uptake by the extra-splachnic tissues; insulin reversed this effect. Ketone-body production must have decreased, as hepatic ketone-body content was unchanged by dicholoracetate yet blood concentrations decreased. 6. It was concluded that: (a) dichloroacetate had qualitatively similar effects on glucose metabolism in severely ketotic rats to those observed in non-diabetic starved animals; (b) insulin and dichloroacetate both separately and together, decreased the net release of lactate, pyruvate and alanine from the extra-splachnic tissues, possibly through a similar mechanism; (c) insulin reversed the inhibition of 3-hydroxybutyrate uptake caused by dichloroacetate; (d) dichloroacetate inhibited ketone-body production in severe ketoacidosis.     

Relations between 3H-estradiol uptake and receptor content of estrogen responsive tissues of castrated female rat

The time course of 3H-Estradiol-17 beta (3H-E2) uptake, and estrogen receptor content in estrogen responsive tissues were studied between 0 and 12 h after injection of 0.5 microgram/kg of 3H-E2 or cold E2 injection to castrated adult female rats. The plasma concentration of 3H-E2 between 10 min and 2 h after injection was in the range of the plasma E2 level of cyclic rat. The total 3H-E2 uptake was well correlated with the receptor content in all tissues. The rank order of 3H-E2 uptake was: uterus (Ut) greater than anterior pituitary (Ap) greater than hypothalamus (Ht) greater than plasma. The cytosol 3H-E2 uptake showed its maximal level 10 min after injection in all tissues. Parallel time course between plasma 3H-E2 and cytosol uptake was obtained for each separate tissue. The nuclear 3H-E2 uptake showed its maximal values 2 h after injection with a subsequent decline. Cytosolic estrogen receptor (Rc) content showed a depletion-replenishment cycle after cold E2 injection in all tissues. Nuclear estrogen receptor (Rn) content in Ut increased progressively from 0 to 14 h after injection, but in Ap it showed its maximal level 2 h after injection, declining afterwards. In Ap, nuclear 3H-E2 uptake and Rn level showed parallel time courses. The maximal level of both parameters coinciding with the time of maximal Rc depletion. However, the Rn level in Ut increases more slowly at greater length than the nuclear 3H-E2 uptake, both processes being divergent. These findings are interpreted as the expression of tissular differences in the rate of nuclear receptor formation from the Rc-E complex previously translocated into nucleus and attached to chromatin.     

1,2-Diacylglycerol and ceramide levels in insulin-resistant tissues of the rat in vivo

Phorbol esters have been reported to decrease sensitivity or responsiveness to insulin in cells in vitro. Since phorbol esters are analogues of endogenously produced 1,2-diacylglycerol, the present study investigated whether 1,2-diacylglycerol concentration is elevated in insulin-resistant tissues of the rat in vivo. Studies were done on 11-12-week-old genetically obese Zucker rats, which are insulin-resistant. Lean Zucker rats served as controls. Levels of 1,2-diacylglycerol in obese rats were increased 82% in liver, 136% in calf muscles, 72% in soleus muscle, a slow-twitch muscle, and 40% in plantaris muscle, a fast-twitch muscle. Ceramide levels in the same tissues were increased 26, 52, 69, and 13%, respectively. Studies were also done on normal, non-obese Sprague-Dawley rats 3 h, 1, 3, 8, and 15 days after interrupting the nerve supply to hindlimb muscles. We have previously shown that 3-17 days after denervation, soleus muscles are completely unresponsive to insulin and do not increase glucose uptake in response to insulin stimulation in vivo, whereas plantaris muscles show a normal glucose uptake when stimulated by insulin; however, the insulin-induced increment in glucose uptake is reduced 68% because it is superimposed on already elevated basal glucose uptake (Turinsky, J. (1987) Am. J. Physiol. 252, R531-R537). In the present study, the denervated soleus muscles exhibited a sustained increase of 23-56% in 1,2-diacylglycerol concentration between 3 h and 15 days after interruption of nerve supply. The denervated soleus muscles also showed 34 and 42% increases in ceramide concentration at 3 and 8 days after denervation, respectively. In contrast, no increases in 1,2-diacylglycerol concentration were observed in plantaris muscles at shorter intervals than 15 days after denervation. Ceramide concentrations in plantaris muscles were increased 43 and 75% at 8 and 15 days after denervation, respectively. These observations demonstrate that tissue insulin resistance is frequently associated with a long term increase in tissue 1,2-diacylglycerol concentration. This suggests the possibility that augmented 1,2-diacylglycerol levels contribute to the development of some types of tissue insulin resistance.     

Changes of hydration of rats' tissues after in vivo exposure to 0.2 Tesla steady magnetic field

Hydration and [3H]ouabain uptake by different tissues of adult male rats were measured immediately after exposure to homogenous 0.2 T steady magnetic field. A time-dependent decrease of hydration and adaptation, followed by disadaptation, was detected in brain and liver tissues in most of the rats after 3.5-5 h of exposure. The number of functional active ouabain binding receptors, which correlates with cell volume, was also decreased in brain, liver, and spleen and increased in kidney tissue after half an hour of exposure. It is suggested that cell hydration is a second messenger through which the SMF exerts its influence.     

Comparative effect and fate of non-entrapped and liposome-entrapped neuraminidase injected into rats

Non-entrapped and liposome-entrapped Clostridium perfringens neuraminidase (0.5-0.6 unit) was injected into rats and its fate as well as its effect on plasma and erythrocyte N-acetylneuraminic acid was investigated. The following observations were made. (1) Although removal of both non-entrapped and liposome-entrapped neuraminidase from the circulation was completed within 5h after injection, their recovery in tissues was distinctly different; 7-10% of the injected non-entrapped enzyme was found in the liver and none in the liver lysosomal fraction or the spleen. In contrast, 20-26% of the liposome-entrapped enzyme was found in the liver of which 60-69% was in the lysosomal fraction. Spleen contained 3.6-5.0% of the enzyme. (2) The presence of the non-entrapped neuraminidase in blood led to the extensive desialylation of plasma and to a decrease in the concentration or total removal from the circulation of some of the plasma glycoproteins. (3) Injection of non-entrapped neuraminidase also led to the partial desialylation of erythrocytes the life span of which was diminished and their uptake by the liver and spleen augmented. (4) Entrapment of neuraminidase in liposomes before its injection prevented the enzyme from acting on its substrate in plasma or on the erythrocyte surface, and values obtained for plasma glycoproteins and erythrocyte survival were similar to those observed in control rats. (5) Entrapment in liposomes of therapeutic hydrolases intended for the degradation of substances stored within the tissue lysosomes of patients with storage diseases could prevent the potentially hazardous enzymic action of hydrolases in blood and at the same time direct the enzymes to the intracellular sites where they are needed.     

Peroxidase-catalyzed bromination of tyrosine, thyroglobulin, and bovine serum albumin: comparison of thyroid peroxidase and lactoperoxidase

A recent paper (Buchberger, W., 1988, J. Chromatogr. 432, 57) on lactoperoxidase-catalyzed bromination of tyrosine and thyroglobulin stated, without evidence, that thyroid peroxidase (TPO) is able to use bromide as a substrate. This was in disagreement with unpublished experiments previously performed in this laboratory, and we undertook, therefore, to examine this subject further. Highly purified porcine TPO was compared with lactoperoxidase (LPO) and chloroperoxidase (CPO) for ability to catalyze bromination of tyrosine, thyroglobulin, and bovine serum albumin (BSA). The incubation mixture contained 50-100 nM peroxidase, 10-500 microM 82Br-, tyrosine (150 microM), thyroglobulin (0.3 or 1 microM), or BSA (7.5 microM), and a source of H2O2. The latter was either generated by glucose (1 mg/ml)-glucose oxidase (0.5 or 1 micrograms/ml), or added initially as a bolus (100 microM). With TPO, formation of organically bound 82Br was undetectable under all conditions in the pH range 5.4-7.0. Lactoperoxidase and CPO, on the other hand, displayed considerable brominating activity. Lactoperoxidase was much more active at pH 5.4 than at pH 7.0 and was more active with BSA as acceptor than with tyrosine or thyroglobulin. The distribution of 82Br among the various amino acids in LPO-brominated thyroglobulin and BSA was determined by HPLC. As expected, monobromotyrosine and dibromotyrosine together comprised the greatest part of the bound 82Br. However, a surprisingly high percentage (20-25%) was present as monobromohistidine. Evidence was also obtained for the presence of a small percentage of the bound 82Br as tetrabromothyronine. Peroxidase-catalyzed bromination probably depends on the oxidation of Br- to Br+ by the Compound I form of the enzyme. Since oxidation of Br- to Br+ requires a stronger oxidant than oxidation of I- to I+, our results suggest that Compound I of LPO and of CPO has a higher oxidation potential than Compound I of TPO. In vivo experiments with rats on a low iodine diet injected with 82Br- showed that even under conditions of high stimulation by thyrotropic hormone, there is negligible formation of organic bromine in the thyroid. Measurements of thyroid:serum concentration ratios for 82Br- in similar rats provided no evidence that Br- is a substrate for the iodide transport system of the thyroid.     

Boron uptake in normal melanocytes and melanoma cells and boron biodistribution study in mice bearing B16F10 melanoma for boron neutron capture therapy

Information on (10)B distribution in normal tissues is crucial to any further development of boron neutron capture therapy (BNCT). The goal of this study was to investigate the in vitro and in vivo boron biodistribution in B16F10 murine melanoma and normal tissues as a model for human melanoma treatment by a simple and rapid colorimetric method, which was validated by HR-ICP-MS. The B16F10 melanoma cell line showed higher melanin content than human melanocytes, demonstrating a greater potential for boronophenylalanine uptake. The melanocytes showed a moderate viability decrease in the first few minutes after BNCT application, stabilizing after 75 min, whereas the B16F10 melanoma showed the greatest intracellular boron concentration at 150 min after application, indicating a different boron uptake of melanoma cells compared to normal melanocytes. Moreover, at this time, the increase in boron uptake in melanoma cells was approximately 1.6 times higher than that in normal melanocytes. The (10)B concentration in the blood of mice bearing B16F10 melanoma increased until 90 min after BNCT application and then decreased after 120 min, and remained low until the 240th minute. On the other hand, the (10)B concentration in tumors was increased from 90 min and maximal at 150 min after application, thus confirming the in vitro results. Therefore, the present in vitro and in vivo study of (10)B uptake in normal and tumor cells revealed important data that could enable BNCT to be possibly used as a treatment for melanoma, a chemoresistant cancer associated with high mortality.     

A selective radiobrominated cocaine analogue for imaging of dopamine uptake sites: pharmacological evaluation and PET experiments

(E)-N-(3-bromoprop-2-enyl)-2beta-carbomethoxy-3beta-4'-tolyl -nortropane or PE2Br, an analogue of cocaine was labelled with the positron emitter 76Br (T1/2=16 h) for pharmacological evaluation in the rat and PET investigation in the monkey. [76Br]PE2Br was obtained by electrophilic substitution from the tributylstannyl precursor with radiochemical yield of 80%. In vivo biodistribution studies of [76Br]PE2Br (20 MBq/nmol) in rats showed a high uptake in the striatum (2.2% ID/g tissue at 15 min p.i.). The striatum to cerebellum radioactivity ratio was 6 at 1 hour p.i. Striatal uptake of [76Br]PE2Br was almost completely prevented by pretreatment with GBR 12909, but citalopram and maprotiline had no effect, confirming the selectivity of the radioligand for the dopamine transporter. PET imaging of the biodistribution of [76Br]PE2Br in the baboon demonstrated rapid and high uptake in the brain (5% ID at 3 min p.i.). The striatal radioactivity concentration reached a plateau at 20 min p.i. (7% ID/100 mL). The uptake in the cortex and cerebellum was very low. A significantly higher uptake in the thalamus was observed. At 1h p.i., the striatum to cerebellum ratio and thalamus to cerebellum ratio were 8 and 1.9 respectively. In competition experiments the radioactivity in the striatum and the thalamus was displaced by 5 mg/kgof cocaine and 5 mg/kg of GBR 12909, but citalopram and maprotiline had no effect. These results showed that [76Br]PE2Br is in vivo a potent and selective radioligand suitable for PET imagingof the dopamine transporter.     

Asymmetry in the mechanism for anion exchange in human red blood cell membranes. Evidence for reciprocating sites that react with one transported anion at a time

The kinetics of chloride and bromide transport were examined in intact human red blood cells and resealed ghosts. Because the influx and efflux of halide ions are almost equal (less than 0.01% difference), the stimulation of the exchange flux by external halides could be determined by measuring 36Cl or 82Br efflux. When the external halide concentration was increased by replacement of isoionic, isotonic solutions of sucrose and the nontransported anion citrate, the stimulation of the exchange flux was hyperbolic and was maximum at 20 mM halide externally. The K 1/2-out, the external concentration of chloride or bromide which stimulated the efflux to half of its maximum value, was 3 and 1 mM respectively, 15-fold smaller than K 1/2-in which we found to be about equal to the K 1/2 of halide self-exchange with nearly equal internal and external concentrations. Thus, the transport mechanism behaves asymmetrically with respect to these transported halides. Bromide flux was two-fold greater in bromide-chloride heteroexchange than in bromide-bromide self-exchange but it was still much smaller than the chloride self-exchange flux. The maximum influx and efflux of bromide in exchange for chloride were roughly eqal. Thus, since the maximum transport rates in the two directions are nearly equal, the kinetics of bromide equilibrium exchange with equal concentrations on the two sides are controlled on the inside where K 1/2 is greatest. The K 1/2-out Cl was a hyperbolic function of internal chloride concentration and was proportional to the maximum flux at each internal chloride concentration. These results are evaluated in terms of two broad categories of models. We conclude that, in contrast to other ion transport systems which have been shown to have kinetics of a sequential mechanism, anion exchange is compatible with a ping-pong mechanism in which a single site reciprocates between inside- and outside-facing orientations with asymmetric K 1/2 values.     

Immunological demonstration of a calcium-unresponsive protein kinase C of the delta-type in different species and murine tissues. Predominance in epidermis

An antiserum raised against a delta-protein kinase C (delta-PKC)-specific peptide recognized the purified calcium-unresponsive 76-kDa protein kinase of porcine spleen in the native and the denatured form. This antiserum was used to demonstrate the delta-PKC-like enzyme in spleen of different species, in various cell types and in murine tissues by immunoblotting of the respective extracts. Due to species differences, delta-PKC-like kinases with slightly different molecular weights were observed. The enzyme was found to be present in primary murine keratinocytes, primary bovine endothelial cells, and many cell lines originating from human, rat, and murine tissues. It was present also in all murine tissues tested, predominantly in epidermis, uterus, placenta, lung, brain, spleen, and kidney. In contrast to the conventional alpha, beta, gamma-PKC, it was located almost exclusively in the particulate fraction. The delta-like PKC could be demonstrated in the epidermis and brain of newborn mice, and in both tissues its concentration increased dramatically between day 7 and 14 after birth. The delta-PKC-like kinase of mouse epidermis (p82-kinase) was down-regulated after topical application of 12-O-tetradecanoylphorbol-13-acetate (TPA) to mouse skin. The amount of the enzyme decreased to less than 20% of the controls within 16 h and recovered almost completely within 72 h after TPA. The existence of the delta-PKC-like kinase in mouse skin, papillomas, and carcinomas could also be demonstrated by immunocytochemical staining of the respective sections. The enzyme was observed predominantly in epithelial layers. A remarkable immunostaining of nuclei in skin sections disappeared after TPA treatment of the animals.     

Transport of amino acids into the oestrogen-primed uterus. Enhancement of the uptake by a preliminary incubation

1. Preincubation of the immature rat uterus under physiological conditions was found to increase its subsequent ability to transport alpha-aminoisobutyric acid, l-proline, l-alanine and 1-aminocyclopentanecarboxylic acid. Uptakes of l-valine, l-phenylalanine and l-leucine were not affected. With alpha-aminoisobutyric acid, a doubling of the uptake could be obtained after a 3-5h preincubation period. Uteri from oestradiol-primed rats gave increases similar to those found in tissues from untreated animals. In both cases the preincubation increased the V(max.) of alpha-aminoisobutyric acid uptake but did not affect the K(m). 2. The conditions during the preincubation period determined the increase in subsequent uptake of alpha-aminoisobutyric acid. No increase in uptake was found if the preincubation was carried out at 1 degrees C, in the presence of cyanide or dinitrophenol, under anaerobiosis or with a concentration of puromycin that depressed incorporation of l-leucine into protein by 95%. The puromycin was also shown to prevent the increase in V(max.) normally found after the preincubation period. In addition, no increase was found if Na(+) was omitted from the preincubation medium. Other inorganic ions had smaller effects. 3. The uptake of alpha-aminoisobutyric acid by uteri before and after a preincubation period showed the same general patterns of sensitivity to competitive inhibitors, K(+), pH, temperature and 2,4-dinitrophenol. 4. The results suggest that the preincubation leads to an increase in a protein component of the ;A system' for amino acid transport in the uterus, and that metabolic energy is required for the reactions involved.     

Inter-organ relationships between glucose, lactate and amino acids in rats fed on high-carbohydrate or high-protein diets

1. Inter-organ relationships between glucose, lactate and amino acids were studied by determination of plasma concentrations in different blood vessels of anaesthetized rats fed on either a high-carbohydrate diet [13% (w/w) casein, 79% (w/w) starch] or a high-protein diet [50% (w/w) casein, 42% (w/w) starch]. The period of food intake was limited (09:00-17:00h), and blood was collected 4h after the start of this period (13:00h). 2. Glucose absorption was considerable only in rats fed on a high-carbohydrate diet. Portal-vein-artery differences in plasma lactate concentration were higher in rats fed on this diet, but not proportional to glucose absorption. Aspartate, glutamate and glutamine were apparently converted into alanine, but when dietary protein intake was high, a net absorption of glutamine occurred. 3. The liver removed glucose from the blood in rats fed on a high-carbohydrate diet, but glucose was released into the blood in rats fed on the high-protein diet, probably as a result of gluconeogenesis. Lactate uptake was very low when amino acid availability was high. 4. In rats on a high-protein diet, increased uptake of amino acids, except for ornithine, was associated with a rise in portal-vein plasma concentrations, and in many cases with a decrease in hepatic concentrations. 5. Hepatic concentrations of pyruvate and 2-oxo-glutarate decreased without a concomitant change in the concentrations of lactate and malate in rats fed on the high-protein diet, in spite of an increased supply of pyruvate precursors (e.g. alanine, serine, glycine), suggesting increased pyruvate transport into mitochondria. 6. High postprandial concentrations of plasma glucose and lactate resulted in high uptakes of these metabolites in peripheral tissues of rats on both diets. Glutamine was released peripherally in both cases, whereas alanine was taken up in rats fed on a high-carbohydrate diet, but released when the amino acid supply increased. 7. It is concluded that: the small intestine is the main site of lactate production, and the peripheral tissues are the main site for lactate utilization; during increased ureogenesis in fed rats, lactate is poorly utilized by the liver; the gut is the main site of alanine production in rats fed on a high-carbohydrate diet and the liver utilizes most of the alanine introduced into the portal-vein plasma in both cases.