INCORPORATION OF LIPIDS INTO SUBCELLULAR FRACTIONS OF BRAIN OF QUAKING MUTANT

The synthesis of lipids and their assembly into subcellular membrane fractions of the myelin deficient Quaking mutant and control brains was studied in 18-, 24- and 41-day-old animals using a double label methodology with¹⁴C and ³H acetate as precursors. As a general procedure, Quaking mutants were injected intracranially with 50 μCi [¹⁴C]acetate and their littermate controls with 300 μCi [³H]acetate. The animals were killed 3 h post-injection, their brains were pooled and subcellular fractions prepared from the common homogenate. An 80-90% decrease in the incorporation of acetate into eleven lipids of myelin in the Quaking mutant was found. This occurred in the face of apparent normal incorporation (relative to microsomes) into lipids of the other main subcellular fractions (nuclear. mitochondrial and synaptosomal) with the exception of decreased incorporation into the myelin-like fraction at 18 and 24 days. Cholesterol and cerebroside were less readily incorporated into Quaking myelin than the other lipids. Although the microsomal synthesis of cholesterol and cerebroside was depressed by about 30% in the Quaking mutant, the incorporation of cholesterol into nuclear, synaptosomal and mitochondrial fractions was unaffected in the mutant. This indicates that sufficient cholesterol is synthesized for the normal assembly of these organelles. In contrast the incorporation of acetate into cholesterol and cerebroside of Quaking myelin was decreased much more than microsomal synthesis. This latter result is consistent with a defect in the process of myclin membrane assembly     

Subcellular site and mechanism of synthesis of disaturated phosphatidylcholine in alveolar type II cell adenomas.

The site of synthesis of 1,2-disaturated-(diacyl)-sn-glycero-3-phosphocholine (Sat2PC) in mouse alveolar type II cell adenomas has been studied by conducting pulse-chase experiments. Isolation of microsomal and lamellar body fractions from adenomas after a 20-min pulse with [methyl-3H]choline demonstrates that Sat2PC first appears in the microsomal fraction, and after a short lag subsequently appears in the lamellar body fraction. The kinetics of labeling of Sat2PC are consistent with the microsomal membranes functioning as the subcellular site of synthesis for this pulmonary surfactant phospholipid. Short term labeling experiments with [9,10-3H]palmitate demonstrate that this fatty acid is incorporated into the sn-2 position of Sat2PC at a faster rate than its incorporation into the sn-1 position. This finding indicates that the synthesis of Sat2PC occurs by a deacylation-reacylation mechanism.     

Differential effect of L-thyroxine on phospholipid biosynthesis in mitochondria and microsomal fraction.

1. The action of L-thyroxine on the incorporation of radioactive choline or CDP-choline into phosphatidylcholine in vitro was explored in liver and brain microsomal fraction and mitochondria obtained from young adult rats. 2. In liver mitochondria isolated from animals treated with L-thyroxine (40 mg/kg body wt. during 6 days), the incorporation of both radioactive precursors into phosphatidylcholine was significantly decreased compared with normal controls, whereas in the total homogenate and in the microsomal fraction the incorporation was similar in the experimental and control groups. In subcellular fractions isolated from brain, the incorporation of precursors was similar in L-thyroxine-treated and normal animals. 3. Liver mitochondria isolated from normal animals incubated in vitro with CDP-choline, in the presence of different concentrations of L-thyroxine, showed also a marked decrease in the incorporation of label into phosphatidylcholine, whereas no significant changes were found in the total homogenate and in the microsomal fraction compared with control experiments. 4. The differential effect of L-thyroxine on the incorporation of radioactive precursors into phosphatidylcholine of isolated liver subcellular fractions gives further support to the hypothesis that liver mitochondria can independently synthesize part of their own phospholipids. 5. Possible mechanisms of the action of the hormone at the mitochondrial level are discussed.     

Regulation by cytidine nucleotides of the acylation of sn-[14C]glycerol 3-phosphate. Regional and subcellular distribution of the enzymes responsible for phosphatidic acid synthesis de novo in the central nervous system of the rat

1. The regional and subcellular distribution of the incorporation of sn-[(14)C]glycerol 3-phosphate into rat brain lipids in vitro was investigated and compared with the relative specific activity of various chemical and enzyme markers. The similarity between the subcellular distribution of this incorporation and of NADPH-cytochrome c reductase activity indicated that the synthesis of phosphatidic acid via this route correlated with the presence of endoplasmic reticulum. 2. Experiments in which various amounts of the microsomal fraction were added to fixed amounts of nuclear, myelin, nerve-ending and mitochondrial preparations clearly demonstrated that the endoplasmic-reticulum contamination of these fractions was entirely responsible for the incorporation of sn-[(14)C]glycerol 3-phosphate. 3. The presence of CMP or CTP inhibited the incorporation of sn-[(14)C]glycerol 3-phosphate into the whole homogenate. Similar effects were observed with individual fractions, except for the mitochondria. With the mitochondrial fraction the effect of these cytidine nucleotides varied with the preparation, stimulating in some preparations and inhibiting with other preparations. The presence of CDP-choline stimulated the incorporation into the whole homogenate and to a lesser extent into the subcellular fractions. 4. These results indicate that the various organelles of the central nervous system are more dependent on endoplasmic reticulum for the production of glycerolipids de novo than has previously been appreciated.     

Biosynthesis and compartmentalization of Po,apolipoprotein A-I,and lipids in the myelinating chick sciatic nerve

Myelin deposition in developing chick sciatic nerve is associated with rapid synthesis of lipids, the major myelin protein Po and apo A-I, a major constituent of plasma lipoproteins. In order to understand possible roles of apo A-I in myelin assembly the synthesis and appearance of Po, apo A-I and lipids was studied in an intracellular fraction, an intralamellar fraction thought to be related to, or derived from, myelin and compact myelin from rapidly myelinating sciatic nerve of 1 day chicks. Incorporation with methionine or pulse-chase experiments indicated that initial synthesis of Po occurs in the intracellular fraction followed by movement to the intralamellar fraction and myelin. Incorporation of labelled oleate into phospholipids suggested that initial synthesis occurs in the intracellular and intralamellar fractions with slow movement to myelin. Incorporation of labelled galactose into cerebrosides suggested that initial synthesis occurs partially in myelin with slow loss from this fraction to the intralamellar fraction. However, incorporation of methionine into apo A-I indicated that initial synthesis occurred in the intracellular fraction with some transfer to the intralamellar fraction and secretion of a major portion into the incubation medium. It is concluded that the subcellular distribution of nascent apo A-I is not well coordinated with the distribution of other nascent constitutents of the myelin membrane. The accumulation of nascent Po, phospholipids and cerebrosides in the intralamellar fraction compared to compact myelin suggests that this fraction may play a role as a precursor membrane or as a storage site for assembly of myelin constituents into compact myelin.Abbreviations PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulphate - apo apolipoprotein - PC phosphatidylcholine - PE phosphatidylethanolamine     

Na+,K+-ATPase activity of the subcellular fractions of the rat brain in aging

The Na+, K+-ATPase activity in the homogenate and in subcellular fractions of different parts of the brain of adult and old rats was studied in comparison. The content of cholesterol in the above fractions was also determined. In old age the Na+, K+-ATPase activity in the homogenate and microsomal fraction of the cerebral hemispheres' cortex decreases, while the Mg2+-ATPase activity in the cortex microsomal fraction increases. The age-related Na+, K+- and Mg2+-ATPase activity in the myelin of the stem in the synaptic plasma membranes of hemispheres and the brain stem remains unchanged whereas in the myelin fraction of hemispheres it grows. The content of cholesterol in the brain of old rats as compared with adult ones increases in the microsomal fraction and remains unchanged in synaptic membranes. The possible role of age-related modification of lipid component of plasma membranes in the above changes of Na+, K+-ATPase activity is discussed.     

Protein determinants of myelination in different regions of developing rat central nervous system.

Measurements of several different protein determinants correlated with the time and rate of myelination in five areas of the central nervous system are presented. The deposition of protein in the subcellular fraction corresponding to the density of adult myelin, the appearance of basic protein characteristic myelin, the change in proportions of the individual myelin proteins, the appearance and distribution of the myelin marker 2':3'-cyclic nucleotide3'-phosphohydrolase, and the results of morphological studies of purified myelin are compared. According to these various criteria, and in agreement with the morphological observations of others, myelin appears earliest in the spinal cord, then in the brain stem, and latest in the cerebral hemispheres. Multilamellar myelin was observed in the rat brain stem and spinal cord as early as 5 days of age. The relative proportion of the individual myelin proteins changed with myelin maturation in all areas, with the larger basic protein decreasing reciprocally with increase of the smaller basic protein. The proportion of Wolfgram protein also decreased with maturation. Larger proportions of the enzyme 2':3'-cyclic nucleotide 3'-phosphohydrolase were located in the microsomal fraction at early ages. During development the enzyme activity gradually became associated more with a fraction of a density corresponding to adult myelin, suggesting the presence of precursor membrane fragments in microsomal fractions in the early stages of myelination before compact myelin formation. A significant proportion of the total nucleotide phosphohydrolase activity of the homogenate could not be recovered in subcellular fraction at early ages, but the recovers of the enzyme increased with maturation and the activity was found more in the myelin fraction.     

THE BIOSYNTHESIS OF CHOLESTEROL AND OTHER STEROLS BY BRAIN TISSUE

Abstract— The distribution of [¹⁴C]-labeIled material into subcellular fractions of 15-day-old rat brain was studied as a function of time after intracerebral injection of [2-¹⁴C]mevalonic acid. As previously shown for adult brain, the data indicated the microsomal fraction to be the site of sterol biosynthesis. The synaptosomal fraction exhibited a marked early uptake of [¹⁴C]-nonsaponifiable material. Total radioactivity in both myelin and myelin-like fractions remained low in comparison to that in the other subcellular fractions at all time periods examined. At 2 h after injection, labelled digitonin-precipitable material was demonstrable in all subcellular fractions. Examination of the [¹⁴C]-labelled nonsaponifiable material by thin-layer chromatography indicated the rapid appearance of labelled 4-desmethyl sterol in all subcellular fractions, with the most rapid appearance in the myelin fraction, followed in decreasing order by microsomal, synaptosomal, and mitochondrial fractions. Examination of [¹⁴C] digitonin-precipitable material from each fraction by the dibromide method demonstrated that although 4-desmethyl sterol appeared quickly, the formation of cholesterol was slow in all fractions, an effect that had been reported earlier for adult brain.     

Metabolism of cerebrosides and sulfatides in subcellular fractions of developing rat brain

Previous studies on myelinating rat brain indicated that microsomes, Golgi-enriched and cytosol fractions may process galactolipids destined for myelin. To extend these findings we labeled brain galactolipids in vivo and determined the specific radioactivity of cerebrosides and sulfatides in several subcellular fractions. 17-day-old rats were treated by intracranial injection with [14C]galactose 60 min prior to and [3H]galactose 15 min prior to killing. Subcellular fractions were prepared from brain stem, and concentrations of cerebrosides and sulfatides were determined, their radioactivity measured and the 3H/14C ratio compared. Our results showed that the heavier Golgi-enriched fraction (designated Fraction 2) is unique in its low galactolipid content and high specific radioactivities of cerebrosides and sulfatides. The low ratio of the specific activity of cerebroside to that of sulfatide in Fraction 2 compared to other fractions indicates that it may be the site of most rapid conversion of newly synthesized cerebrosides to sulfatides. The specific radioactivities of cerebrosides and sulfatides in cytosol are intermediate between those in Golgi-enriched Fraction 2 and microsomes and those in myelin, consistent with the role postulated for cytoplasmic elements in the transport of cerebrosides and sulfatides to myelin.     

Entry of Newly Synthesized Gangliosides into Myelin

Ganglioside synthesis and transport to myelin was studied in brainstem slices prepared from 19-21-day-old rats. The slices were incubated for up to 2 h in the presence of [3H]glucosamine to label primarily the hexosamine portion of complex gangliosides. The amount of radioactivity incorporated into gangliosides during slice incubations was only 10-15% of the amount of the label incorporated during in vivo labeling of brainstem gangliosides using equivalent amounts of [3H]glucosamine. Among individual gangliosides this inhibition was greater for the more complex gangliosides. When labeled gangliosides were isolated from homogenate and myelin fractions prepared from brain slices, the complex total gangliosides of both fractions showed a lag in labeling kinetics but with a lower specific radioactivity for the myelin fraction, reflecting the larger pool size and slower turnover rate exhibited by myelin components. Chase experiments showed that more complex gangliosides in homogenate exhibited almost no effect of chase after 30 min. Addition of the Golgi-disrupting agent monensin to slice incubations inhibited the labeling of all gangliosides except GM3, GM2, and GD3, and transport to myelin of all complex gangliosides except GM2. These results show that a monensin-sensitive mode of transport is responsible for the translocation of most newly synthesized gangliosides into myelin.     

Labeling of RNA in young and adult rat brain: Evidence for different RNA processing

The labeling of RNA in young and adult rat brain has been studied by measuring in vitro (tissue slices incubation) the incorporation of labeled uridine into RNA of total tissue and of the various subcellular fractions purified from cerebral hemispheres of 1- and 10-month-old rats. Gel electrophoretic analysis of the newly synthesized nuclear and microsomal RNA was also accomplished. An active metabolism of RNA in adult animals was found; moreover, distinct differences in ribosomal RNA processing in cerebral hemispheres of 1- and 10-month-old rats, with a more rapid processing in the brain of adult animals, were obtained.     

Preferential In Vivo Incorporation of [3H]Arachidonic Acid from Blood into Rat Brain Synaptosomal Fractions Before and After Cholinergic Stimulation

Abstract: Awake adult male rats were infused intravenously with [³H]arachidonic acid for 5 min, with or without prior administration of an M1 cholinergic agonist, arecoline (15 mg/kg i.p.). Methylatropine was also administered (4 mg/kg s.c.) to control and arecoline-treated animals. At 15 min postinfusion, the animals were killed, brains were removed and frozen, and subcellular fractions were obtained from homogenates of whole brain. Total radioactivity and radioactivity in various lipid classes were determined for each fraction following normalization for exposure by use of a unidirectional incorporation coefficient, k ^⋆_brain. In control animals, incorporation was greatest in synaptosomal and microsomal fractions, accounting for 50 and 30% of total label incorporated into membrane lipids, respectively. Arecoline increased incorporation in these two fractions by up to 400% but did not increase incorporation into the myelin, mitochondrial, or cytosolic fractions. Of the incorporated radioactivity, 50–80% was in phospholipid in microsomal and synaptosomal fractions, indicating that phospholipid is the major lipid affected by cholinergic stimulation. These results demonstrate that plasma [³H]arachidonic acid is preferentially incorporated into phospholipids of synaptosomal and microsomal fractions of rat brain. Cholinergic stimulation increases incorporation into these fractions, likely by activation of phospholipase A₂ and/or C in association with acyltransferase activity. Thus, intravenously infused radiolabeled arachidonic acid can be used to examine synapse-mediated changes in brain phospholipid metabolism in vivo.     

Synthesis and Transport of Cerebrosides and Sulfatides in Rat Brain During Development

Synthesis and transport of nonhydroxy fatty acid (NFA)- and hydroxy fatty acid (HFA)-containing ceramides, cerebrosides, and sulfatides were studied in vivo in rat brain during development. After an intracerebral injection of [3H]serine, incorporation into these lipids of microsomal and myelin membranes was analyzed after HPLC. Distribution of amounts and incorporation of radioactivity were also determined in individual molecular species of these lipids. The results showed that HFA-ceramides and long-chain NFA-ceramides have small pool sizes and rapid turnover rates in the microsomal membranes and are preferentially utilized for the synthesis of long-chain (greater than or equal to 20:0) HFA- and NFA-galactocerebrosides of both microsomal and myelin membranes. Glucocerebrosides are not expressed in myelin and their synthesis in microsomal membranes is predominant before the onset of myelination. With development, synthesis and accumulation of HFA-cerebrosides increase over NFA-cerebrosides in both microsomal and myelin membranes. In myelin, incorporation of radioactivity into HFA-cerebrosides is even higher than that expected by transport alone from microsomal membranes and it is possible that part of the HFA-cerebrosides in myelin could be due to de novo synthesis by myelin itself. The amount of NFA- and HFA-sulfatides is about equal, both in myelin and microsomal membranes, and this relative proportion does not change with development. Similar relative rates of incorporation of radioactivity into sulfatides of microsomal and myelin membranes are consistent with the notion that both NFA and HFA sulfatides are synthesized in the microsomal (Golgi) membranes and are transported to myelin.(ABSTRACT TRUNCATED AT 250 WORDS)     

THE EFFECTS OF CARBAMYLCHOLINE ON INCORPORATION IN VIVO OF [1-14C]ARACHIDONIC ACID INTO GLYCEROLIPIDS OF MOUSE BRAIN

Abstract— The effects of carbamylcholine on incorporation of [1-¹⁴C]arachidonate into the glycerolipids in mouse brain synaptosome-rich and microsomal fractions were examined at 1, 3 and 10 min after intracerebral injection of the labeled precursor. When carbamylcholine was included with the labeled arachidonate, there was a decrease in the proportion of labeled fatty acid incorporated into the phospholipids. Among the phospholipids in the synaptosome-rich fraction, a decrease in incorporation of radioactivity into diacyl-glycerophosphoinositols and diacyl-glycerophosphocholines was observed at 1 and 3 min after injection. A decrease in labeling of diacyl-glycerophosphoethanolamines and diacyl-glycerophosphocholines in the microsomal fraction was observed at 3 and 10 min after injection. The decrease in phospholipid labeling was marked by an increase in labeling of diacylglycerols which was observed initially in the synaptosome-rich fraction, but also in the microsomal fraction at later time periods. Other lipid changes included an increase in triacylglycerol labeling which was found in the synaptosome-rich fraction and an increase in phosphatidic acid labeling which was found in the microsomal fraction. Results of the in vivo study have demonstrated changes in brain lipid metabolism during carbamylcholine stimulation. Furthermore, these changes appear to be initiated mainly in the synaptosome-rich fraction.     

Intracellular Translocation of Myelin Proteolipid Protein

Brainstem slices prepared from 22-day-old rats were employed to study the intracellular translocation of radioactively labeled myelin proteolipid protein (PLP). Double-isotope and short pulse-chase procedures allowed us to demonstrate the flux of PLP through nine different subcellular membrane fractions that were isolated on the basis of their particle size and buoyant density. Tagged PLP was rapidly depleted from microsomes, showed transient passage through a number of presumably intermediate membranous pools, and accumulated in myelin. On the basis of the kinetics of PLP labeling and isotope ratios, the membranes can be arranged as they participate in the intracellular translocation of PLP and consistently show a pattern indicating possible precursor-product relationships.     

INCORPORATION OF [1-14C]OLEIC ACID AND [1-14C]ARACHIDONIC ACID INTO LIPIDS IN THE SUBCELLULAR FRACTIONS OF MOUSE BRAIN

Abstract— The distribution of radioactivity among lipids of subcellular membrane fractions was examined after intracerebral injections of [1-¹⁴C]oleic and [1-¹⁴C]arachidonic acids. Labelled free fatty acids were distributed among the synaptosomal-rich, microsomal, myelin and cytosol fractions at 1 min after injection. However, incorporation of the fatty acids into phospholipids and trïacylglycerols after pulse labelling occurred mainly in the microsomal and synaptosomal-rich fractions. With both types of labelled precursors, there was a higher percentage of radioactivity of diacyl-glycerophosphoryl-inositols in the synaptosomal-rich fraction as compared to the microsomal fraction. Radioactivity of [1-¹⁴C]oleic acid was effectively incorporated into the triacylglycerols in the microsomal fraction whereas radioactivity of the [1-¹⁴C]arachidonic acid was preferentially incorporated into the diacyl-glycerophosphorylinositols in the synaptosomal-rich fraction. Result of the study indicates that synaptosomal-rich fraction in brain is able to metabolize long chain free fatty acids in vivo and to incorporate these precursors into the membrane phosphoglycerides.     

Incorporation of [3H]thymidine into DNA and of [35S]sulfate into sulfatides of oligodendroglial cells during development: Effect of malnutrition

Incorporation of [³H]thymidine into DNA and of [³⁵S]sulfate into sulfatides of oligodendroglial cells isolated from brain slices incubated with the radioactive precursor was studied in normal and malnourished rats at different ages. The pattern and the values of incorporation of [³H]thymidine into DNA were similar in both groups of animals. The maximum value of incorporation was observed at 7 days of age decreasing rapidly thereafter and leveling off between 18–21 days. In both groups of animals labeling of sulfatides attained a maximum at 18 days of age, showing similar values of incorporation up to that age. However, at 21 days of age; the values corresponding to malnourished rats were found to be 40% lower in comparison to controls. The results suggest that (a) proliferation of oligodendroglial cells stops at similar ages in normal and malnourished rats, (b) expression of sulfatide synthesis by oligodendroglial cells is similar in both groups of animals up to 18 days, and (c) the starved rats seem to be unable to maintain normal synthesis of these galactolipids throughout the entire period of active myelinogenesis.     

Synthesis and incorporation of myelin polypeptides into CNS myelin

The distribution of newly synthesized proteolipid protein (PLP, 23 kdaltons) and myelin basic proteins (MBPs, 14-21.5 kdaltons) was determined in microsomal and myelin fractions prepared from the brainstems o1 10-30 d-old rats sacrificed at different times after an intracranial injection of 35S-methionine. Labeled MBPs were found in the myelin fraction 2 min after the injection, whereas PLP appeared first in the rough microsomal fraction and only after a lag of 30 min in the myelin fraction. Cell-free translation experiments using purified mRNAs demonstrated that PLP and MBPs are synthesized in bound and free polysomes, respectively. A mechanism involving the cotranslational insertion into the ER membrane and subsequent passage of the polypeptides through the Golgi apparatus is consistent with the lag observed in the appearance of the in vivo-labeled PLP in the myelin membrane. Newly synthesized PLP and MBPs are not proteolytically processed, because the primary translation products synthesized in vitro had the same electrophoretic mobility and N-terminal amino acid sequence as the mature PLP and MBP polypeptides. It was found that crude myelin fractions are highly enriched in mRNAs coding for the MBPs but not in mRNA coding for PLP. This suggests that whereas the bound polysomes synthesizing PLP are largely confined to the cell body, free polysomes synthesizing MBPs are concentrated in oligodendrocyte processes involved in myelination, which explains the immediate incorporation of MBPs into the developing myelin sheath.     

Pattern of labeling of rabbit cerebral cortex soluble proteins 24 hours after a single electroconvulsive shock

The labeling of proteins in the particulate subcellular fractions and in the cell sap was studied in the cerebral cortex of rabbits 24 hours after a single electroconvulsive shock (ECS). To this end the animals were injected with [³H]valine subarachnoidally and sacrificed 30 minutes later. The incorporation of the labeled aminoacid into proteins was slightly increased in all subcellular fractions but the increase was significant only for soluble proteins.Referring to the type of soluble polypeptides found in the cortex at this post ECS phase, no modification was found in the SDS electrophoresis pattern of steady state proteins. The fractionation pattern of labeled soluble proteins showed in one third (3 out of 9) of the experiments a remarkable stimulation of the synthesis of two polypeptides (25,000 and 54,000 Dalton MW), which were not labeled in the controls.     

Effect of hypoxia on nucleic acid and protein synthesis in different brain regions

The incorporation of [methyl-³H]thymidine into DNA, of [5-³H]uridine into RNA, and of [1-¹⁴C]leucine into proteins of cerebral hemispheres, cerebellum, and brainstem of guinea pigs after 80 hr of hypoxic treatment was measured. Both in vivo (intraventricular administration of labeled precursors) and in vitro (tissue slices incubation) experiments were performed. The labeling of macromolecules extracted from the various subcellular fractions of the above-mentioned brain regions was also determined. After hypoxic treatment the incorporation of the labeled precursors into DNA, RNA, and proteins was impaired to a different extent in the three brain regions and in the various subcellular fractions examined; DNA and RNA labeling in cerebellar mitochondria and protein labeling in microsomes of the three brain regions examined were particularly affected.