In vivo incorporation of l-[14C]serine into phospholipids and proteins of the subcellular fractions of developing rat brain

A study was conducted on the in vivo incorporation of l -[¹⁴C]-serine into the lipids and proteins of the various subcellular fractions of the developing rat brain before and during the stage of active myelination. The total radioactivity in the various fractions at 12 days of age was higher than that at 3 days, while the radioactive specific activity was reversed. The specific activities of the proteins and lipids were higher at 3 days of age with the exception of the subcellular fraction containing myelin. At both ages the lipids of the various cellular fractions had similar specific activities, a finding that suggests a common source for lipid biosynthesis. Incorporation of radioactivity into the various phospholipids was in the following order: phosphatidyl serine > phosphatidyl ethanolamine > phosphatidal serine > sphingomyelin and phosphatidyl choline. Of all the phospholipids, the plasmalogens increased most in total radioactivity during the period when meylination was most active. Serine-containing phospholipids appear to be most tightly bound to proteins. The brain mitochrondrial fraction contained most of the phosphatidyl serine decarboxylase activity with some activity in the nuclei. Biosynthesis of phosphatdyil ethanolamine through decarboxylation of phosphatidyl serine could take place in rat brain. Four unidentified radioactive metabolites were found in the acid-soluble fraction in addition to l -[¹⁴C]serine.     

Incorporation of [32P]phosphate, [14C]acetate,and [3H]glycerol into phospholipids of Ceratitis capitata larvae. Turnover of labelled phospholipids during metamorphosis

Biosynthesis of phospholipids during metamorphosis of Ceratitis capitata has been investigated using disodium [³²P]orthophosphate, sodium [¹⁴C]acetate, and [³H]glycerol as labelled precursors. Specific activities were determined in phosphatidylcholine, phosphatidylethanolamine, their lysoderivatives, and phosphatidylserine, obtained from the developmental stages of larva, larval-pupal apolysis, pharate adult, and emerged adult. The isotope incorporation into phospholipids of larvae exhibits the highest specific activities in phosphatidylserine and phosphatidylcholine. However, a clear tendency to equalize the values of the three main phospholipids is shown during metamorphosis of the insect, which might suggest the existence of reactions of base conversions.     

Studies on the preferential incorporation of [3H]glycerol over [32P]phosphate into major phospholipids of human platelets

It is well known that platelets readily incorporate radioactive glycerol, but not radioactive phosphate into phosphatidylcholine (PC) and phosphatidylethanolamine (PE) in vitro, thus not in accordance with de novo synthesis according to the Kennedy pathway. In attempts to understand the reason for the discrepancy, gel-filtered platelets were incubated simultaneously with [32P]Pi and [3H]glycerol, and the specific and relative radioactivities of products and intermediates were determined. Both precursors were incorporated into phosphatidylinositol (PI) with a 32P/3H ratio similar to that in glycerol 3-phosphate (in accordance with the Kennedy pathway). However, PC and PE obtained a much lower ratio. The specific 32P radioactivity in phosphorylcholine was similar to that of the gamma-phosphoryl of ATP and 650-times higher than that of PC. The specific 32P radioactivity of phosphorylethanolamine was 20-times less than that of phosphorylcholine. Both mass and 32P labelling of CDP-choline were below the detection limits. It is concluded that the incorporation of [32P]Pi into PC via phosphorylcholine is insignificant while the preferential incorporation of [3H]glycerol could be explained by exchange of diacyl[3H]glycerol in the reversible choline phosphotransferase (CDP-choline: 1,2-diacylglycerol cholinephosphotransferase) reaction. The same mechanism would explain the preferential incorporation of 3H over 32P into PE, although dilution of 32P at the phosphorylethanolamine stage would account for part of the feeble 32P incorporation. Although other mechanisms are also possible, our results clearly show that the appearance of [3H]glycerol in PC and PE is not a reliable method of monitoring de novo synthesis of these phospholipids.     

Metabolism of [1-14C]glyoxylate, [1-14C]-glycollate, [1-14C]glycine and [2-14C]-glycine by homogenates of kidney and liver tissue from hyperoxaluric and control subjects

1. The metabolism of [1-(14)C]glyoxylate to carbon dioxide, glycine, oxalate, serine, formate and glycollate was investigated in hyperoxaluric and control subjects' kidney and liver tissue in vitro. 2. Only glycine and carbon dioxide became significantly labelled with (14)C, and this was less in the hyperoxaluric patients' kidney tissue than in the control tissue. 3. Liver did not show this difference. 4. The metabolism of [1-(14)C]glycollate was also studied in the liver tissue; glyoxylate formation was demonstrated and the formation of (14)CO(2) from this substrate was likewise unimpaired in the hyperoxaluric patients' liver tissue in these experiments. 5. Glycine was not metabolized by human kidney, liver or blood cells under the conditions used. 6. These observations show that glyoxylate metabolism by the kidney is impaired in primary hyperoxaluria.     

[14C]Formate and [8-14C]Adenine incorporation into purine nucleotides of ischaemic rat liver after re-establishment of blood flow

• 1.1. After restoration of blood flow the incorporation rate of [¹⁴C]formate and [8-¹⁴C]adenine into purine nucleotides of ischaemic rat liver was investigated.
• 2.2. The incorporation rate of [¹⁴C]formate into adenine nucleotides was nearly 5-fold greater in post-ischaemic livers than in controls at 120 min point following blood restoration.
• 3.3. No difference in the rate of [8-¹⁴C]adenine incorporation into adenine nucleotides of post-ischaemic and control rat liver lobes was found.
• 4.4. After re-establishment of blood circulation a predominant contribution of the de novo biosynthetic pathway in the recovery of purine nucleotides of the ischaemic rat liver is emphasized.