Radiolabelled Choline Research Articles

Renotrophic factors in urine

Our previous observations of increased renal protein synthesis in rats subjected to the constant intravenous reinfusion of half their urine output has suggested that the circulatory retention of renotrophic factors in urine is capable of stimulating renal growth. In the present studies, using this same model of "half-urine-reinfusion," which is designed to produce a selective halving of renal excretory function, we have demonstrated significant increases in total DNA content and the incorporation of tritiated thymidine in renal DNA. In addition, a bioassay method was developed in which an assay rat, given an intravenous infusion of urine from another rat, exhibited increases in the incorporation of thymidine into renal DNA and the incorporation of radiolabelled choline into renal phospholipid. This renotrophic activity in the urine was only minimally decreased by heating to 100 degrees C for 30 min and was confined to ultrafiltration fractions retained on a membrane with a nominal 10,000-dalton solute rejection. Removal of one kidney from the rats from which the urine was obtained led to only a modest and transient reduction in the excretion of renotrophic activity, suggesting that the urinary renotrophic factors are of circulatory, not renal, origin. Isolated renal cortical fragments incubated with an ultrafiltration retentate of urine displayed a dose-dependent increase in choline incorporation into phospholipid, suggesting a direct action of the factors on kidney tissue. Finally, no evidence of stimulation of either DNA or phospholipid synthesis could be seen in hepatic tissue.(ABSTRACT TRUNCATED AT 250 WORDS)

Sodium-dependent choline binding in rat hippocampal synaptosomes

The binding of radiolabelled choline to lysed rat hippocampal synaptosomes was investigated. A portion of the binding sites was (a) detectable only when sodium ions were present, (b) sensitive to low concentrations of hemicholinium-3 (K D ⩽ 70 nM), and (c) significantly reduced following electrolytic lesion of the septum. The similarity between this component of choline binding and the requirements of the sodium-dependent high affinity choline uptake process suggests that these binding sites are related to the choline transport system.

Carrier mediated blood-brain barrier transport of choline and certain choline analogs.

Abstract—Blood‐brain barrier (BBB) transport of choline and certain choline analogs was studied in adult and suckling rats, and additionally compared in the paleocortex and neocortex of adult rats. Saturable uptake was characterized by a single kinetic system in all cases examined, and in adult rat forebrains we determined a Km= 442 ± 60 μM and Vmax= 10.0 ± 0.6 nmol min‐1 g‐1. In 14–15‐day‐old suckling forebrains a similar Km (= 404 ± 88 μM) but higher Vmax (= 12.5 ± 1.5 nmol min‐1 g‐1) was determined. When choline uptake was compared in two regions of the forebrain, similar Michaelis‐Menten constants were determined but a higher uptake velocity was found in the neocortex (i.e. neocortex Km= 310 ± 103 μM and Vmax= 12.6 ± 2.8 nmol min‐1g‐1; paleocortex Km= 217 ± 76 μM and Vmax= 7.2 ± 1.5 nmol min‐1 g‐1).Administration of radiolabelled choline at low (5 μM) and high (100 μM) concentrations, followed by microwave fixation 60 s later and chloroform‐methanol‐water separations of the homogenized brain did not suggest a relationship between concentration and the appearance of label in lipid or aqueous fractions as observed in another in‐vitro study elaborating two‐component kinetics of choline uptake. It was observed that 60s after carotid injection 12–14% of the radiolabel in the ipsilateral cortex was found in the chloroform‐soluble fraction.Hemicholinium‐3 (Ki= 111 μM), dimethylaminoethanol (Ki= 42 μM), tetraethyl ammonium chloride, tetramethyl ammonium chloride, 2‐hydroxyethyl triethylammonium iodide, carnitine, normal rat serum, and to a lesser extent lithium and spermidine all inhibited choline uptake in the BBB. Unsubstituted ammonium chloride and imipramine did not inhibit choline uptake.No difference was observed in blood‐brain barrier choline uptake of unanesthetised, carotid artery‐catheterized animals, and comparable sodium pentobarbital‐anesthetized controls.