INTRACELLULAR ACCUMULATION OF PROTOCOLLAGEN AND EXTRUSION OF COLLAGEN BY EMBRYONIC CARTILAGE CELLS

The synthesis of collagen can be interrupted, after the assembly of proline-rich and lysine-rich polypeptide chains called protocollagen, by incubating connective tissues anaerobically. Under these conditions the proline and lysine residues in protocollagen are not hydroxylated to hydroxyproline and hydroxylysine, and protocollagen molecules accumulate intracellularly. Chemical data and radioautographs at the level of the light and electron microscopes indicated that in tissues labeled with proline-3,4-³H under nitrogen, there appeared to be an accumulation of radioactivity over the ground cytoplasm. When the inhibition of protocollagen hydroxylase was reversed by exposing the tissue to oxygen, the accumulated protocollagen-³H was converted to collagen-³H and there was a rapid transfer of label from the ground cytoplasm to the extracellular matrix. There was no significant change in distribution of label over either the Golgi vacuoles or the cisternae of the endoplasmic reticulum. The failure to find a significant change in distribution of label over the Golgi vacuoles or the cisternae does not completely exclude the possibility that these two compartments are involved in the extrusion, but the data are consistent with the simpler notion that the completed collagen molecules pass directly from the ground cytoplasm to the extracellular matrix.     

Axonal transport of glycerophospholipids following intracerebral injection of glycerol into substantia nigra or lateral geniculate body

[2-³H]Glycerol was injected into one substantia nigra of adult rats. Incorporation of radioactivity into lipids at the injection site was maximal by 2 hr, after which it declined. Rapidly transported³H-labeled lipids were just beginning to accumulate in the primary projection site, the ipsilateral corpus striatum by 2 hr, as evidenced by 20-fold higher levels of lipid radioactivity in the projection site relative to control regions. However, the bulk of labeled lipid arrived between 6 hr and 3 days postinjection, suggesting either a prolonged period of release of rapidly transported lipids from the nerve cell bodies or a slow rate of transport for the later arriving lipids. Colchicine applied locally to the fibers of this tract blocked the axonal transport of lipids to the striatum almost completely. Choline and ethanolamine phosphoglycerides were the major transported lipids, accounting for approximately 60% and 25%, respectively, of the total. Similar results were obtained in studies of [2-³H]glycerol-labeled lipids synthesized in the lateral geniculate body and transported to the visual cortex. The rapid axonal transport of lipids labeled with [³²P]phosphate (injected simultaneously with [2-³H]glycerol) could also be demonstrated in both tracts. However, in contrast to [2-³H]glycerol, considerable amounts of³²P soluble label were present in the projection sites, and colchicine only partially blocked the accumulation of³²P-labeled lipid. These results demonstrate the relative utility of [2-³H]glycerol as a lipid precursor for examination of axonal transport in intrabrain tracts. Characteristics of lipid axonal transport in these two intrabrain tracts are similar to each other and are also similar to those previously described for retinal ganglion cells, indicating a common requirement for the axonal transport of these membrane constituents to axons and nerve endings in widely divergent CNS tracts.Presented in part at the 11th meeting of the American Society for Neurochemistry, Houston, Texas, March 1980.     

Axonal transport of phospholipids in rat visual system.

Abstract— Seventeen day old rats were injected intraocularly with a phospholipid precursor, [³²P]phosphate, and a glycoprotein precursor, [³H]fucose. Animals were killed between 1 h and 21 days later, and structures of the visual pathway (retina, optic nerve, optic tract, lateral geniculate body, and superior colliculus) were dissected. Radioactivity in phospholipids ([³²P] in solvent-extracted material) and in glycoproteins ([³H] in solvent-extracted residue) was determined. Incorporation of [³H]fucose into retinal glycoproteins peaked at 6–8 h. Labelled glycoproteins were present in superior colliculus by 2h after injection, indicating a rapid rate of transport; maximal labelling was at 8–10 h after injection. Incorporation of [³²P]phosphate into retinal phospholipids peaked at 1 day after injection. Phospholipids were also rapidly transported since label was present in the superior colliculus by 3 h after injection: however, maximal labelling did not occur until 5–6 days. These results indicate that newly synthesized phospholipids enter a preexisting pool, part of which is later committed to transport at a rapid rate. Transported phospholipids were catabolized at the nerve endings with a maximum half-life of several days; there was minimal recycling of precursor label. Lipids were fractionated by thin-layer chromatography, and radioactivity in individual phospholipid classes determined. Choline and ethanolamine phosphoglycerides were the major transported phospholipids, together accounting for approx 85% of the total transported lipid radioactivity. At early time points, the ratio of radioactivity in choline phosphoglycerides to that in ethanolamine phosphoglycerides increased in structures progressively removed from the site of synthesis (retina) but by 2 days approached a constant value. In each structure, choline phosphoglyceride-ethanolamine phosphoglyceride radioactivity ratios decreased with time, rapidly at first, but plateaued by 2 days. These results indicate that choline phosphoglycerides are committed to transport sooner than ethanolamine phosphoglycerides. Some experiments were also conducted using [2-³H]glycerol as a phospholipid precursor. Results concerning incorporation of this precursor into individual phospholipid classes and their subsequent axonal transport were comparable to those obtained using [³²P]phosphate, with the following exceptions: (a) incorporation of [2-³H]glycerol into retinal phospholipids was relatively rapid (near-maximal levels at 1 h after injection) although transport to the superior colliculus showed an extended time course very similar to [³²P]-labelled lipids; (b) [2-³H]glycerol was somewhat less efficient than [³²P]phosphate in labelling lipids committed to transport relative to labelling those which remained in the retina; and (c) [2-³H]glycerol did not label plasmalogens.     

The disposition of [24-3H]cerebrosterol in developing rat brain.

—The uptake into subcellular fractions of developing rat brain in vivo of intracerebrally injected [4-¹⁴C]cholesterol, [24-³H]cerebrosterol, and [24-³H]24-epicerebrosterol was measured for periods up to 30 days following administration. [4-¹⁴C]cholesterol was accumulated rapidly in nuclei, nerve endings, and microsomes, more slowly in myelin and mitochondria. [24-³H]cerebrosterol was accumulated rapidly in myelin, nerve endings, and microsomes, more slowly in nuclei and mitochondria. The uptake of [24-³H]24-epicerebrosterol was essentially the same as that of [24-³H]cerebrosterol. Ratios of radioactivities of [24-³H]cerebrosterol and [4-¹⁴C]cholesterol accentuated the early accumulation of [24-³H]cerebrosterol in myelin, nerve endings, and microsomes, and declining ³H:¹⁴C ratios disclosed the rapid elimination of [24-³H]cerebrosterol and [24-³H]24-epicerebrosterol relative to [4-¹⁴C]cholesterol in nerve endings and microsomes. The data suggest that the removal of [24-³H]cerebrosterol from brain results from an enzymic metabolism of the sterol, therefore that cerebrosterol exists in brain in a dynamic state of biosynthesis and catabolism.     

Dégradation d'acides aminés à l'interface eau-sédiment réconstitué d'une lagune méditerranéenne (Golfe du Lion)

Degradation of Amino Acids at a Simulated Water-sediment Interface of a Mediterranean Lagoon Environment, Golfe du Lion The degradation of two ¹⁴C and ³H labelled amino acids at the simulated water-sediment interface of a Mediterranean lagoon was studied. The four day experiments included the respiratory activity measurement and the study of incorporation processes of the radioactivity in specific organic fractions of the ¹⁴C arginine. After active mineralization occurred during the first day, the radioactivity in the acid-soluble fraction decreased and polycondensed products were progressively incorporated. The radioactivity of the ³H lysine was included mainly in the acid soluble fraction. The nature of the substrate, and the reducing conditions in the environment affect the radioactivity distribution in the organic fractions. The identification of amino acids in the acid-soluble and base soluble fractions shows that the labelled arginine and lysine and other amino acids in the acid soluble and base soluble fractions shows that the labelled arginine and lysine released from the initial compounds are important quantitatively.     

PROVENANCE OF THE ACETYL GROUP OF ACETYLCHOLINE AND COMPARTMENTATION OF ACETYL-CoA AND KREBS CYCLE INTERMEDIATES IN THE BRAIN IN VIVO

—The origin of the acetyl group in acetyl-CoA which is used for the synthesis of ACh in the brain and the relationship of the cholinergic nerve endings to the biochemically defined cerebral compartments of the Krebs cycle intermediates and amino acids were studied by comparing the transfer of radioactivity from intracisternally injected labelled precursors into the acetyl moiety of ACh, glutamate, glutamine, ‘citrate’(= citrate +cis-aconitate + isocitrate), and lipids in the brain of rats. The substrates used for injections were [1-¹⁴C]acetate, [2-¹⁴C]acetate, [4-¹⁴C]acetoacetate, [1-¹⁴C]butyrate, [1, 5-¹⁴C]citrate, [2-¹⁴C]glucose, [5-¹⁴C]glutamate, 3-hydroxy[3-¹⁴C]butyrate, [2-¹⁴C]lactate, [U-¹⁴C]leucine, [2-¹⁴C]pyruvate and [³H]acetylaspartate. The highest specific radioactivity of the acetyl group of ACh was observed 4 min after the injection of [2-¹⁴C]pyruvate. The contribution of pyruvate, lactate and glucose to the biosynthesis of ACh is considerably higher than the contribution of acetoacetate, 3-hydroxybutyrate and acetate; that of citrate and leucine is very low. No incorporation of label from [5-¹⁴C]glutamate into ACh was observed. Pyruvate appears to be the most important precursor of the acetyl group of ACh. The incorporation of label from [1, 5-¹⁴C]citrate into ACh was very low although citrate did enter the cells, was metabolized rapidly, did not interfere with the metabolism of ACh and the distribution of radioactivity from it in subcellular fractions of the brain was exactly the same as from [2-¹⁴C]pyruvate. It appears unlikely that citrate, glutamate or acetate act as transporters of intramitochondrially generated acetyl groups for the biosynthesis of ACh. Carnitine increased the incorporation of label from [1-¹⁴C]acetate into brain lipids and lowered its incorporation into ACh. Differences in the degree of labelling which various radioactive precursors produce in brain glutamine as compared to glutamate, previously described after intravenous, intra-arterial, or intraperitoneal administration, were confirmed using direct administration into the cerebrospinal fluid. Specific radioactivities of brain glutamine were higher than those of glutamate after injections of [1-¹⁴C]acetate, [2-¹⁴C]acetate, [1-¹⁴C]butyrate, [1,5-¹⁴C]citrate, [³H]acetylaspartate, [U-¹⁴C]leucine, and also after [2-¹⁴C]pyruvate and [4-¹⁴C]acetoacetate. The intracisternal route possibly favours the entry of substrates into the glutamine-synthesizing (‘small’) compartment. Increasing the amount of injected [2-¹⁴C]pyruvate lowered the glutamine/glutamate specific radioactivity ratio. The incorporation of ¹⁴C from [1-¹⁴C]acetate into brain lipids was several times higher than that from other compounds. By the extent of incorporation into brain lipids the substrates formed four groups: acetate > butyrate, acetoacetate, 3-hydroxybutyrate, citrate > pyruvate, lactate, acetylaspartate > glucose, glutamate. The ratios of specific radioactivity of ‘citrate’ over that of ACh and of glutamine over that of ACh were significantly higher after the administration of [1-¹⁴C]acetate than after [2-¹⁴C]pyruvate. The results indicate that the [1-¹⁴C]acetyl-CoA arising from [1-¹⁴C]acetate does not enter the same pool as the [1-¹⁴C]acetyl-CoA arising from [2-¹⁴C]pyruvate, and that the cholinergic nerve endings do not form a part of the acetate-utilizing and glutamine-synthesizing (‘small’) metabolic compartment in the brain. The distribution of radioactivity in subcellular fractions of the brain after the injection of [1-¹⁴C]acetate was different from that after [1, 5-¹⁴C]citrate. This suggests that [1-¹⁴C]acetate and [1, 5-¹⁴C]citrate are utilized in different subdivisions of the ‘;small’ compartment.     

Fatty Acid Incorporation in Normal and Degenerating Rat Sciatic Nerve In Vivo

Abstract: Labeled palmitic acid ([16-¹⁴C]palmitate) (0).5 μCi) was injected into rat sciatic nerves in vivo to characterize thc incorporation of this fatty acid into complex peripheral nerve lipids after time lapses of 1 min to 2 weeks. For the first 30 min after intraneural injection, the label was concentrated in nerve diglycerides. Thereafter, the relative diglyccride label declined rapidly, and phospholipid radioactivity rose steadily. After 120 min, phospholipids contained over 70% of the total lipid radioactivity. Among the phospholipids, phosphatidylcholine had the largest percentage of total phospholipid label, and acylation of lysophosphatidylcholine accounted for approximately 75% of this label. With time, there was conversion of [16-¹⁴C]palmitate to other long-chain fatty acids by elongation and desaturation. Phosphatidic acid was labeled also, suggesting the operation of the de novo biosynthetic mechanism. However, the specific radioactivity of 1,2-diacylglycerol was much higher than that of phosphatidic acid, suggesting phosphorylation of diglycerides by diglyceride kinase. After nerve section and survival of 2 h to 50 days, the injection of [16-¹⁴C]palmitate into the degenerating distal segment revealed an overall decline of phospholipid labeling and a commensurate increase of triglyceride radioactivity. Phosphatidylcholine in degenerating nerve contained a larger percentage of the fatty acid label than that in normal nerve. Almost all of the labeling was due to acylation of lysophosphatidylcholine, implying a much smaller contribution of the de novo pathway. Phosphatidylethanolamine and phosphatidylserine showed a relative loss of radioactivity. The changes were apparent at 1 day, but not at 2 h, suggesting loss of homeostatic control, presumably by interruption of axonal flow. An incidental observation was the stimulation of phosphatidylcholine biosynthesis by acylation of lysophosphatidylcholine in the contralateral unoperated sciatic nerve.     

Diffusion of intracerebrally injected [1-14C]arachidonic acid and [2-3H]Glycerol in the mouse brain

[2-³H]Glycerol and [1-¹⁴C]arachidonic acid were injected into the region of the frontal horn of the left ventricle of mice and were distributed rapidly throughout the brain. After 10 sec, most of the radioactive fatty acid was found in the hemisphere near the injection site; after 10 min, it was recovered in similar proportions in the cerebellum and brain stem. [2-³H]Glycerol showed a heterogeneous distribution, with most of the label remaining in the left hemisphere even after 10 min. On a fresh weight basis, cerebrum, cerebellum, and brain stem were found to contain similar amounts of labeled glycerol. However, the amount of [1-¹⁴C]arachidonate in cerebrum was only 50% of that recovered from cerebellum or brain stem. Brain ischemia or a single electroconvulsive shock reduced the spread of the label, producing an accumulation of radioactivity in the injected hemisphere, except for an increase in [2-³H]glycerol in the brain stem during ischemia. Despite the significant decrease in available precursor in the cerebellum and brain stem after electroshock, the amount of label incorporated into lipids was not altered in these areas and only slightly diminished in the cerebrum.     

Axonal transport of the mitochondria-specific lipid, diphosphatidylglycerol, in the rat visual system

Rats 24 d old were injected intraocularly with [2-3H]glycerol and [35S]methionine and killed 1 h-60 d later. 35S label in protein and 3H label in total phospholipid and a mitochondria-specific lipid, diphosphatidylglycerol(DPG), were determined in optic pathway structures (retinas, optic nerves, optic tracts, lateral geniculate bodies, and superior colliculi). Incorporation of label into retinal protein and phospholipid was nearly maximal 1 h postinjection, after which the label appeared in successive optic pathway structures. Based on the time difference between the arrival of label in the optic tract and superior colliculus, it was calculated that protein and phospholipid were transported at a rate of about 400 mm/d, and DPG at about half this rate. Transported labeled phospholipid and DPG, which initially comprised 3-5% of the lipid label, continued to accumulate in the visual structures for 6-8 d postinjection. The distribution of transported material among the optic pathway structures as a function of time differed markedly for different labeled macromolecules. Rapidly transported proteins distributed preferentially to the nerve endings (superior colliculus and lateral geniculate). Total phospholipid quickly established a pattern of comparable labeling of axon (optic nerve and tract) and nerve endings. In contrast, the distribution of transported labeled DPG gradually shifted toward the nerve ending and stabilized by 2-4 d. A model is proposed in which apparent "transport" of mitochondria is actually the result of random bidirectional saltatory movements of individual mitochondria which equilibrate them among cell body, axon, and nerve ending pools.     

INCORPORATION OF AXONALLY TRANSPORTED SUBSTANCES INTO MYELIN LIPIDS

Abstract— The possibility that axonally transported lipids and/or proteins might undergo transaxonal migration and become incorporated into surrounding myelin lamellae was studied by isolating myelin from optic tracts of myelinating rabbits at various times following intraocular injection of [3-¹⁴C]-serine and [2-³H]glycerol. Myelin isolated by a procedure employing ethylene glycol-bis(β-aminoethyl ether)-.N,N'-tetraacetic acid had relatively constant specific radioactivity with respect to both isotopes over a 21 day period. Myelin lipids showed a gradual increase in ¹⁴C specific radioactivity, attributed to reutilization of [¹⁴C]serine from the axon by a compartment of the oligodendrocyte. Free serine is postulated to arise in the axon from catabolism of axonally transported proteins (and possibly lipids) and to migrate transaxonally into the neighboring oligodendroglia. This reutilization mechanism resulted in synthesis of myelin cerebrosides, sphingomyelin, ethanolamine phosphoglycerides and possibly sulfatides, but not gangliosides or serine phosphoglycerides. The data for choline- and inositol-phosphoglycerides are inconclusive. [³H]Glycerol-labeled myelin lipids decreased slowly in ³H specific radioactivity with time, indicating either that [2-³H]glycerol does not participate in the reutilization pathway or that the label is lost in the process. Evidence is presented that ³H- and ¹⁴C-labeled lipids are true myelin constituents. Lipids from the myelin, axolemma- and axon-enriched fractions tended to converge in specific radioactivity over the 21 days, especially the former two fractions. These results together with isotope ratio changes point to an equilibration process whereby lipids are able to transfer. (or exchange) between the 3 compartments. Protein radioactivity in isolated myelin was suggested to arise from residual axon/axolemma contamination, and no evidence was found for transaxonal migration of protein into myelin. The 2 mechanisms elucidated here are believed to account for a quantitatively small portion of myelin lipid and are considered to represent a form of axon-glia interaction.     

FINE STRUCTURAL LOCALIZATION OF CHOLESTEROL-1,2-3H IN DEGENERATING AND REGENERATING MOUSE SCIATIC NERVE

The localization of ³H-labeled cholesterol in nerves undergoing degeneration and regeneration was studied by radioautography at the electron microscope level. Two types of experiments were carried out: (a) Cholesterol-1,2-³H was injected intraperitoneally into suckling mice. 5 wk later, Wallerian degeneration was induced in the middle branch of the sciatic nerve, carefully preserving the collateral branches. The animals were then sacrificed at various times after the operation. During degeneration, radioactivity was found over myelin debris and fat droplets. In early stages of regeneration, radioactivity was found in myelin debris and regenerating myelin sheaths. Afterwards, radioactivity was found predominantly over the regenerated myelin sheaths. Radioactivity was also associated with the myelin sheaths of the unaltered fibers, (b) Wallerian degeneration was induced in the middle branch of the sciatic nerves of an adult mouse, preserving the collateral branches. Cholesterol-1,2-³H was injected 24 and 48 hr after the operation and the animal was sacrificed 6 wk later. Radioactivity was found in the myelin sheaths of the regenerated and unaltered fibers. The results from these experiments indicate that: (a) exogenous cholesterol incorporated into peripheral nerve during myelination remains within the nerve when it undergoes degeneration. Such cholesterol is kept in the myelin debris as an exchangeable pool from which it is reutilized for the formation of the newly regenerating fibers, especially myelin. (b) exogenous cholesterol incorporated into the nerves at the time that degeneration is beginning is also used in the formation of new myelin sheaths during regeneration, (c) mature myelin maintains its ability to incorporate cholesterol.     

In vivo metabolism of 3-ketoceramide in rat brain

Eight hours after intracerebral injection of a double-labeled 3-ketoceramide⁴, [1-¹⁴C]lignoceroyl 3-keto [1-³H]sphingosine, various brain sphingolipids were isolated. Free ceramide and the ceramide portions of nonhydroxy cerebroside and sphingomyelin were further fractionated into subgroups containing longer-chain or shorter-chain fatty acids. Nonhydroxy ceramide, nonhydroxy cerebroside and sphingomyelin containing longer-chain fatty acids had significant quantities of radioactivity with ³H/¹⁴C ratios similar to each other but lower than that of the injected material. The sphingolipids containing shorter-chain fatty acids were also significantly labeled; however, the ³H/¹⁴C ratios were much higher than that of the injected material. Hydroxy-ceramide and sulfatides contained very little radioactivity. However, hydroxy-cerebroside contained an amount of radioactivity comparable to that of the longer-chain nonhydroxy cerebroside with a similar ³H/¹⁴C ratio. It is proposed that the injected 3-ketoceramide was converted into ceramide, cerebroside, and sphingomyelin and that the fatty acids of these lipids were partly replaced by other fatty acids during the metabolic conversions.     

Radioactive labeling of the Golgi apparatus by micro-injection of individual amebae

Individual amebae were injected with a solution of ³H-mannose or ³H-galactose. In electron microscope radioautographs prepared at intervals between 30 min and 2 h after the injection, silver grains were heavily concentrated over the Golgi apparatus. The results show that it is feasible to label amebae with radioactive precursors by micro-injection of single cells. These results also suggest that the Golgi apparatus plays a role in assembly of a carbohydrate-rich substance, possibly part of the ameba surface coat.     

Synthesis,pharmacokinetics, and metabolism of the <Emphasis Type="Italic">C</Emphasis>-terminal tripeptide of dermorphin and its diastereomer

A tritium-labeled C-terminal fragment of dermorphin (H-Tyr-[3,4-³H]Pro-Ser-NH₂) and its isomer (H-Tyr-D-[3,4-³H]Pro-Ser-NH₂) with molar radioactivity of 35 Ci/mmol were synthesized, and their pharmacokinetics and metabolism in rat organs were studied after their intramuscular injections. The tripeptides were detected in the blood only for 5 min after the injection, and maximum contents of both compounds (approximately 5% of the total amount of the injected label) were registered in the kidneys after 20 min. Both stereomers were shown to penetrate into the brain. We failed to detect any radioactive metabolite, except proline, due to rapid proteolytic degradation of these peptides.     

DISTRIBUTION OF LEUCINE-3H DURING AXOPLASMIC TRANSPORT WITHIN REGENERATING NEURONS AS DETERMINED BY ELECTRON-MICROSCOPE RADIOAUTOGRAPHY

The distribution of leucine-³H in neurons was determined by electron-microscope radioautography after infusion of label into the spinal cord or sensory ganglia of regenerating newts. In the nerve cell bodies 3 days after infusion, the highest concentration of label per unit area occurred over the rough-surfaced endoplasmic reticulum. In the large brachial nerves, the silver grains were not distributed uniformly in the axoplasm, indicating that the labeled materials are restricted in their movement to certain regions of the axon. Almost all of the radioautographic grains observed in myelinated nerves could be accounted for by the presence of a uniformly labeled band occupying the area 1500–9000 A inside the axolemma. This region of the axon was rich in microtubules and organelles while the unlabeled central core of the axon contained mainly neurofilaments. This observation supports the hypothesis that microtubules are related to axonal transport. In small, vesicle-filled nerve terminals in the blastema, labeled material was restricted to a thin zone a short distance beneath the plasma membrane while the central region of the terminal was largely unlabeled. The peripheral pattern of labeling in the nerve endings is consistent with successive addition of newly synthesized proteins at the periphery of the growth cone and release of substances such as trophic factors at the nerve terminal.     

d-β-HYDROXYBUTYRATE: A MAJOR PRECURSOR OF AMINO ACIDS IN DEVELOPING RAT BRAIN

Abstract— D-β-hydroxybutyrate (β-OHB) was compared to glucose as a precursor for brain amino acids during rat development. In the first study [3-¹⁴C]β-OHB or [2-¹⁴C]glucose was injected subcu-taneously (01 μCi/g body wt) into suckling rats shortly after birth and at 6. 11, 13, 15 and 21 days of age. Blood and brain tissue were obtained 20 min later after decapitation. The specific activity of the labelled precursor in the blood and in the brain tissue was essentially the same for each respective age suggesting that the labelled precursor had equilibrated between the blood and brain pools before decapitation. [3-¹⁴C]β-OHB rapidly labelled brain amino acids at all ages whereas [2-¹⁴C]glucose did not prior to 15 days of age. These observations are consistent with a maturational delay in the flux of metabolites through glycolysis and into the tricarboxylic acid cycle. Brain glutamate, glutamine, asparate and GABA were more heavily labelled by [3-¹⁴C]β-OHB from birth-15 days of age whereas brain alanine was more heavily labelled by [2-¹⁴C]glucose at all ages of development. The relative specific activity of brain glutamine/glutamate was less than one at all ages for both labelled precursors suggesting that β-OHB and glucose are entering the‘large’glutamate compartment throughout development. In a second study, 6 and 15 day old rats were decapitated at 5 min intervals after injection of the labelled precursors to evaluate the flux of the [¹⁴C]label into brain metabolites. At 6 days of age, most of the brain acid soluble radioactivity was recovered in the glucose fraction of the [2-^,4C]glucose injected rats with 72, 74, 65 and 63% after 5, 10, 15 and 20 min. In contrast, the 6 day old rats injected with [3-¹⁴C]β-OHB accumulated much of the brain acid soluble radioactivity in the amino acid fraction with 22, 47, 57 and 54% after 5, 10, 15 and 20 min. At 15 days of age the transfer of the [¹⁴C]label from [2-¹⁴C]glucose into the brain amino acid fraction was more rapid with 29, 40, 45, 61 and 73% of the brain acid soluble radioactivity recovered in the amino acid fraction after 5, 10, 15, 20 and 30 min. There was almost quantitative transfer of [¹⁴C]label into the brain amino acids of the 15-day-old [3-¹⁴C]β-OHB injected rats with 66, 89, 89, 89 and 90% of the brain acid soluble radioactivity recovered in the amino acid fraction after 5, 10, 15, 20 and 30 min. The calculated half life for /?-OHB at 6 days was 19 8 min and at 15 days was 12-2 min. Surprisingly, the relative specific activity of brain GABA/glutamate was lower at 15 days of age in the [3-¹⁴C]β-OHB injected rats compared to the [2-¹⁴C]glucose injected rats despite a heavier labelling of brain glutamate in the [3-¹⁴C]β-OHB injected group. We interpreted these data to mean that β-OHB is a less effective precursor for the brain glutamate ‘subcompartment’ which is involved in the synthesis of GABA.     

Uptake of serotonin, 5-hydroxytryptophan and tryptophan by giant serotonin-containing neurones and other neurones in the central nervous system of the snail (Helix pomatia)

Summary Following exposure to tritiated 5-HTP, silver grains were observed over the perikarya of the GSCs (Giant serotonin cells) of Helix pomatia and other known serotonin-containing neurones in light and electron microscope autoradiograms. There was no indication that the 5-HTP was taken up by nerve endings or by non-nervous structures. The distribution of radioactivity was completely different in autoradiograms of tissue exposed to tritiated serotonin. Silver grains, often in very high concentrations, were observed only over certain fine axon branches and processes thought to be nerve endings. Electron microscope autoradiography showed that these processes contained small dense-cored vesicles, morphologically identical to those thought to sequester serotonin in the perikarya of the GSCs. The accumulation of tritiated tryptophan was less specific; all the neurone perikarya showed an accumulation of radioactivity after exposure to this substance.We are grateful to Professor J. F. Lamb for the use of the Scintillation Spectrometer.     

Components of fast and slow axonal transport in the goldfish optic nerve

The composition of the fast and slow components of axonal transport in the goldfish optic nerve was investigated, using specific radioactive precursors injected into the eye. Tritiated glucosamine and fucose label macromolecules, presumably glycoproteins, which are rapidly transported from the eye to the optic tectum. Material labeled with these precursors is not evident in the slowly transported component. Glucosamine and fucose incorporation are blocked when a protein synthesis inhibitor, acetoxycycloheximide, is injected into the eye concurrently with the precursors. As well as labeling macromolecules, ³H-glucosamine and ³H-N-acetylmannosamine ( a precursor of sialic acids) also label rapidly-transported chloroform-methanol-extractable material which may contain transported glycolipids. Two procedures were used to show that the slow component of axonal transport contains tubulin, a protein characteristic of the microtubules:

• (a) Tracer doses of tritiated colchicine injected into the eye label a wave of radioactivity which moves 0.5 mm/day, the rate of slow axonal transport in the goldfish optic nerve. We believe this wave represents the movement of colchicine which is bound to colchicine-binding protein moving in the slow component of axonal transport.
• (b) Tritiated proline labels a slowly transported protein which is precipitated by vinblastine and has a mobility on polyacrylamide gels comparable to authentic tubulin. These results indicate that the fast and slow components of axonal transport each provide specific chemical substances to the nerve endings.

     

Metabolism of pyridoxine in the liver of vitamin B-6-deficient rats

The metabolism of [6-³H]pyridoxine · HCl was investigated in the liver of vitamin B-6-deficient rats. Rats were made vitamin B-6 deficient by feeding adlititum for 42 days a diet lacking pyridoxine but otherwise optimal. Animals were each injected intraperitoneally with 33 μCi of [6-³H]pyridoxine · HCl and killed at different time intervals afterwards up to 7 days. Radioactively labeled hepatic B-6 compounds were extracted with acid and chromatographically separated on Dowex-X8 (H⁺) columns and the percent radioactivity for each vitamin compound was then calculated. Maximal uptake in control and deficient animals was observed 30 and 60 min, respectively, after administration of label. Radioactivity was not retained by the control animals but decreased steadily in a linear fashion after 30 min, reaching a low level after 3 h. On the other hand, vitamin deficient animals accumulated almost twice as much radioactivity in their liver as the controls and retained it through 7 days.In vitamin B-6-deficient animals 93% of the injected radioactivity was metabolized within 2 min at which time pyridoxine 5′-P and pyridoxal 5′-P reached 36 and 44% levels, respectively. Pyridoxine 5′-P dropped to minimal values (3%) within 15 min and remained unchanged for 7 days while pyridoxal 5′-P reached a peak (79%) level at 15 min and then began to drop linearly reaching a plateau (29%) at 5 days. Further, as the level of pyridoxal 5′-P was falling, pyridoxamine 5′-P was linearly synthesized reaching a plateau level (62%) in 5 days which also remained unchaged through 7 days. Some pyridoxal was also formed (7% at 1 h) which by 12 h had dropped to a plateau low level (3%). The specific activity level of pyridoxal kinase decreased 3.2 times and that of pyridoxine 5′-phosphate oxidase increased 1.5 times in the state of deficiency. The results presented show that metabolism of [³H]pyridoxine in deficiency is characterized by (a) a delayed, two-fold increase in label uptake as well as an extended label retention period, (b) a rapid pyridoxal 5′-P synthesis, and (c) a continuouus synthesis (and accumulation) of pyridoxamine 5′-P which is not utilized or further metabolized.     

AXONAL TRANSPORT OF SULFATED GLYCOPROTEINS AND MUCOPOLYSACCHARIDES IN THE GARFISH OLFACTORY NERVE

—Application of ³⁵SO₄ to the olfactory mucosa of the long-nosed garfish is found to label sulfated macromolecules which are transported down the olfactory nerve. The transported molecules pass along the nerve as a discrete peak whose leading edge has a transport velocity of 206 ± 6 mm/day. A large portion of the radioactivity from the peak is deposited along the axon. At 2 days after isotope application 83% of the total nerve radioactivity is in the axons and the remaining 17% has accumulated at the terminals in the olfactory bulb. Characterization of sulfated material in the migrating peak indicates that both sulfated glycoproteins (isolated as glycopeptides) and mucopolysaccharides, including chondroitin sulfate and heparan sulfate, are undergoing transport.