EFFECT OF HAEMORRHAGE ON THE RAPID AXONAL TRANSPORT OF NEUROHYPOPHYSIAL PROTEINS OF THE RAT

Following injection of [³⁵S]cysteine into the region of the supraoptic nucleus male rats were subjected to haemorrhage and the radioactivity of the supraoptic nucleus and neurohypophysial proteins was measured at various time intervals after injection. Following haemorrhage the incorporation of [³⁵S]cysteine into supraoptic nucleus proteins increased. Evidence was obtained for a lag period of 1 to 2 h for the supraoptic nucleus proteins to become available for axonal transport. As judged from the time of arrival of labelled material in the neurohypophysis, haemorrhage did not change the rapid rate of axonal transport (190 mm/day). At 15 min following bleeding, the radioactivity in fraction A (a neurophysin) of the neurohypophysis was reduced, which indicated a release of this rapidly transported protein. During the following 15 min an increase in the protein-bound radioactivity of the neural lobe occurred which exceeded that in controls. This is taken as evidence for increased axonal transport in response to haemorrhage.     

TRANSPORT AND TURNOVER OF NEUROHYPOPHYSIAL PROTEINS OF THE RAT

Axonal transport and turnover rate of proteins in the supraoptico-neurohypo-physial tract were studied after injection of ³⁵S cysteine into the region of the supraoptic nucleus. The proximo-distal migration of labelled proteins from the nerve cell bodies to the axon terminals in the neurohypophysis was followed by measuring the radioactivity of neurohypophysial proteins at various time intervals (4 h to 30 days) after isotope injection. A rapidly transported phase of proteins with a minimal transport rate of approximately 60 mm/day was demonstrated. An accumulation of protein-bound radioactivity was also observed in the neural lobe at 9 days after isotope injection, representing slowly transported proteins (0-5 mm/day). In addition, an intermediate phase of axonal transport (1-5 mm/day) was found. Fractionation of neurohypophysial proteins by polyacrylamide gel disc electrophoresis revealed that a predominating portion of the radioactivity was recovered in a single protein component (fraction A) at 4 h as well as at 30 days after isotope injection. This protein component was shown to be a constituent both of the rapid and the slow phase of axonal transport. With time an increasing amount of radioactivity was found in another protein component (fraction B), which reached a maximum at 14 days after injection and then remained fairly constant up to 30 days. When the turnover rates of neurohypophysial proteins were estimated, a half-life of 1-2 days and 8 days was calculated for the rapidly and slowly transported proteins, respectively.     

Biosynthesis and axonal transport of rat neurohypophysial proteins and peptides

35S-cysteine injected adjacent to the supraoptic nucleus (SON) of the rat is rapidly incorporated into proteins. These 35S-cysteine-labeled proteins in the SON (1-24 h after injection) were separated by polyacrylamide gel electrophoresis, and the distribution of radioactive proteins on the gels was analyzed. 1 h after injection, about 73% of the radioactivity appeared in two peaks (both about 20,000 mol wt). With time, these peaks (putative precursors of neurophysin) decreased, as a 12,000 mol wt peak (containing two distinct neurophysins) increased in radioactivity. Both the 20,000- and 12,000-mol wt proteins are transported into the axonal (median eminence) and nerve terminal (posterior pituitary) regions of the rat hypothalamo-neurohypophysial system. Conversion of the larger precursor protein to the smaller neurophysin appears to occur, in large part, intra-axonally during axonal transport. Six distinct 35S-cysteine-labeled peptides (less than 2500 mol wt), in addition to arginine vasopressin and oxytocin, are also synthesized in the SON and transported to the posterior pituitary where they are released together with labeled neurophysin by potassium depolarization in the presence of extracellular calcium. These data provide support for the hypothesis that the neurohypophysial peptides (vasopressin and oxytocin) and neurophysins are derived from the post- translational clevage of protein precursors synthesized in the SON, and that the conversion process can occur in the neurosecretory granule during axonal transport.     

AXOPLASMIC TRANSPORT IN THE OPTIC NERVE AND TRACT OF THE RABBIT

The axonal transport of labelled proteins was studied in the optic system of adult rabbits after an intraocular injection of [³H]Ieucine. It was demonstrated that the precursor was incorporated into protein, which was transported along the axons of the retinal ganglion cells. Intraocularly injected puromycin inhibited protein synthesis in the retina and markedly inhibited the appearance of labelled protein in the optic nerve and tract. It was further demonstrated by intracisternal injection of [³H]leucine that an intraocular injection of puromycin did not affect the local protein synthesis in the optic nerve and tract. Cell fractionation studies of the optic nerve and tract showed that the rapidly migrating component, previously described as moving at an average rate of 110-150 mm/day, was largely associated with the microsomal fraction. About 40 per cent of the total protein-bound radioactivity in this component was found in the microsomal fraction and about 15 per cent was recovered in the soluble protein fraction. Most of the labelled material moving at a rate of 1-5-2 mm/day was soluble protein. The specific radioactivity of this component was about ten times greater than that of the fast one. In the slow component about 50 per cent of the radioactivity was found in the soluble protein fraction and about 10 per cent of the radioactivity was recovered in the microsomal fraction. Radioautography demonstrated incorporated label in the neuropil structures in the lateral geniculate body as early as 4-8 hr after intraocular injection. The labelling of the neuropil increased markedly during the first week, and could be observed after 3 weeks.     

AXONAL TRANSPORT OF [35S] SULPHATE IN RETINAL GANGLION CELLS OF THE RABBIT

A rapid axonal transport of ³⁵SO₄ in axons of retinal ganglion cells of the rabbit was demonstrated after intraocular administration of the isotope. Transported radioactivity accumulated in the nerve terminals up to 2 days following isotope injection. No evidence for a slow transport of labelled material was found. A considerable part of transported radioactivity had solubility characteristics of glycosaminoglycans, primarily chondroitin sulphate.     

Isolation and characterization of neurosecretory granules of the rat posterior pituitary gland

Summary Neurosecretory granules (NSG) of rat posterior pituitary glands were prepared by differential centrifugation techniques mainly according to the procedure as described by Barer, Heller and Lederis (1963). As revealed by electron microscopy, the recovery of neurophysin and the contents of enzymes, purified NSG were obtained in a pellet at 30 000 g/60 min (0.44 M sucrose). Eighteen h after injection of (³⁵S) cysteine into the supraoptic nucleus 60% of the recovered radioactivity in the neural lobe was found in the NSG, whereas 20% was found in the final supernatant (100 000 g/120 min). Sixteen days after injection the NSG and the final supernatant fraction contained fairly equal amount of (³⁵S) cysteine (approximately 40%). It is suggested that after a period of intragranular maturation neurophysin is extruded into an extragranular pool of neurosecretory material.With the use of conventional polyacrylamide-gel electrophoresis it was shown that the predominating proportion of radioactivity in the NSG after a hypothalamic injection of (³⁵S) cysteine was located within the neurophysin fraction A and in fraction B. Fraction B is suggested to be partly bound to the NSG membranes. When the NSG soluble and NSG insoluble proteins, obtained after lysis of NSG, were separated on polyacrylamide gels in the presence of sodium dodecylsulphate, the highly radioactive soluble protein was shown to consist of two components with average molecular weights of 12 300 and 14 600. Most of the proteins in the lysate were found in the NSG membranes, though less radioactive. A component with a mol.wt. of 37 000 was enriched in the membrane fraction. At longer times after isotope injection the high mol.wt. proteins, particularly those of the NSG membranes, contained increased amounts of radioactivity.Abbreviations NSG neurosecretory granule - NSM neurosecretory material - SON supraoptic nucleus The present investigation was supported by grants from Svenska Livförsäkringsbolags nämnd för medicinsk forskning from Svenska Sällskapet för Medicinsk forskning, from the Medical Faculty, University of Göteborg, and from the Swedish Medical Research Council (B 72-12X-2543-04A).We are indebted to Mrs. Marie-Louise Eskilsson, Mrs. Wally Holmberg and Mrs. Ulla Svedin for technical assistance, and to Miss Gull Grönstedt for careful secreterial work.     

Electrophoretic and immunological charactorization of rat neurophysin

1. The electrophoretic properties of rat posterior pituitary proteins have been compared on starch gel with those of bovine and porcine neurophysins. 2. [(35)S]-Cysteine was injected into the supraoptic nucleus of male rats and 16-24h later the distribution of labelled neural-lobe protein in starch and polyacrylamide gels was determined. In both systems a single major protein component was found to contain more than 80% of the total recovered radioactivity. Between 5 and 10% of the radioactivity was found in a minor component in polyacrylamide gel. 3. In agar, microimmuno-diffusion and -electrophoresis of the rat neural-lobe proteins gave a single arc with neurophysin antiserum, and after starch-gel electrophoresis this arc was shown to be due to the major labelled component. 4. The molecular weights of the rat neural-lobe proteins were estimated by polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate. The molecular weight of the major labelled component was found to be 12000. 5. It is concluded that the rat neurophysin consists of one major and possibly one minor component.     

ANALYSIS OF PROTEINS UNDERGOING AXONAL TRANSPORT IN NIGRO-STRIATAL NEURONS IN THE RAT

Abstract— An analysis of proteins undergoing axonal transport in nigro-striatal neurons, after the stereotaxic injection of [³H]leucine into the substantia nigra of rat brain was performed. As early as 6 h after the injection [³H]proteins appeared in the caudate-putamen. The maximum accumulation was at 5 days and there was still residual protein radioactivity present at 30 days. About 70 per cent of the total radioactive protein in the caudate-putamen was solubilized by homogenization in 0–5%, (v/v) Triton X-100 and remained in the supernatant on centrifuging for 1 h at 100,000 g. The supernatant fraction, when chroma-tographed on a DEAE-cellulose column, was resolved into four protein peaks (A, B. C and D) which were found to be labelled differently as a function of time after the injection of [³H]leucine. Peak A was substantially labelled in a first phase (6–24 h) and reached its maximum in a second phase (5 days). The proteins comprising this peak appeared to undergo both fast and slow axonal transport. Although some labelling in peak B was evident at 6 h, maximal activity did not occur until 5 days. No radioactivity could be detected in peaks C and D at 6 h. Maximal labelling of these two peaks also occurred at 5 days. These data suggest that the proteins of peaks B, C and D were transported primarily by slow axoplasmic flow. The radioactive protein peaks A and B from the second phase of the transport were excluded from a Sephadex G-200 column, pointing to their high molecular weights (13,000–200,000). Peak B. which had the highest specific radioactivity (c.p.m./mg protein) at 5 days, contained a significant level of tyrosine hydroxylase, an important component of dopaminergic neurons.     

Protein carboxymethylation: effects of 2% sodium chloride administration on protein carboxymethylase and its endogenous substrates in rat posterior pituitary

Protein carboxymethylase and methyl acceptor proteins have been studied in the posterior pituitary of control and NaCl treated rats. Salt loading stimulates the hypothalamo-neurohypophysial axis causing the secretion of neurohypophysial peptides. Under these conditions there was a progressive decrease of methyl acceptor proteins with the greatest fall occurring between 1 and 2 days after salt loading. Electrophoretic analysis of the methyl acceptor proteins showed a single major peak of methylated proteins accounting for up to 80% of the total radioactivity. The molecular weight (11,000) and the disappearance of this peak after salt loading suggested that this methyl acceptor protein is neurophysin. After prolonged stimulation of the hypothalamo-neurohypophysial axis there was a progressive increase in protein carboxymethylase specific activity.     

METABOLIC RELATIONSHIPS BETWEEN MYELIN SUBFRACTIONS: ENTRY OF PROTEINS 1

Abstract— Partially purified myelin from brains of 17-day-old rats was separated into 4 subfractions on a discontinuous sucrose gradient by virtue of heterogeneity in density and particle size. The protein composition of each subfraction was determined by densitometry following separation of proteins on polyacrylamide gels in buffers containing sodium dodecyl sulphate. The major proteins studied included two basic proteins, proteolipid protein, the major high molecular weight protein (W) and a group of high molecular weight proteins. The percentage of high molecular weight proteins decreased sequentially from fraction D to A, that of the W protein remained constant, while relative amounts of the two basic proteins increased. Proteolipid protein concentration also increased as a percentage of the total protein from fraction D to B, but the uppermost fraction. A, had a markedly lower amount than fraction B. At 1 h after intracranial injection of [³H]leucine, the specific radioactivity of the basic and proteolipid proteins decreased from fraction D to B, with proteolipid protein in fraction A again anomalous (specific radioactivity higher than expected). These results are consistent with (but do not prove) a precursor-product relationship for individual proteins from denser to lighter subfractions, with the exception of myelin subfraction A. Experiments involving time staggered injections of a [¹⁴C] and later a [³H] labelled amino acid gave data which demonstrated that the W and basic proteins were added simultaneously (or with delays of much less than 20 min) to all of the subfractions, while proteolipid protein was added sequentially, from lower to upper fractions on the gradient. This double isotope technique also confirmed our previous observations that proteolipid protein shows a lag in entry into myelin compared to basic protein.     

PROTEIN SYNTHESIS IN THE BRAIN OF OCTOPUS VULGARIS, LAM

Abstract— The process of protein synthesis in the brain of Octopus vulgaris Lam has been examined after systemic administration of [³H]leucine and upon incubation of the tissue in sea water containing the radioactive precursor. After injection of [³H]leucine in the branchial heart, the radioactivity of the TCA-soluble fractions of the three main brain divisions reached a maximum in about 30 min and decreased thereafter, while incorporation into the protein fractions was complete in approx. 2 h. Per unit wet weight the radioactivity of brain proteins was higher than that of most other organs. In vitro the rate of incorporation of [³H]leucine in the protein fraction of the optic lobe remained low for more than 1 h, but increased several fold thereafter. Preincubation of the tissue in sea water abolished the lag period. Similar effects were observed in the vertical lobe as well as in the optic lobe of young and adult octopuses but not in the white body, a non-nervous organ. The process of protein synthesis in the optic lobe is markedly inhibited by puromycin, cycloheximide and chloramphenicol. Electrophoretic analysis on polyacrylamide gels indicated that the soluble proteins labelled in vitro and in vivo are similar.     

Effects of colchicine on axonal transport and ultrastructure of the hypothalamo-neurohypophyseal system of the rat

Summary The effect of colchicine on the transport of proteins in the hypothalamo-neurohypophyseal tract of the rat was studied after injection of (³⁵S) cysteine into the supraoptic nucleus (SON) region. Colchicine, dissolved in distilled water and administered subarachnoidally, inhibited the axonal transport of labelled proteins into the neurohypophysis: the radioactivity that was recovered in neurohypophyseal TCA precipitable material was markedly decreased and hardly any radioactivity was found in the neurohypophyseal proteins which were separated by polyacrylamide gel disc electrophoresis.As revealed by electron microscopy the SON cell bodies showed marked changes after treatment with colchicine: a deeply folded nucleolemma; a pronounced, granular nucleolus; a dispersed chromatin; a zonal distribution of cell organelles with mitochondria and lysosomes accumulated at the periphery, crowded ribosomes, often arranged as polyribosomes and richly branching short profiles of endoplasmic reticulum filled with filamentous material forming an inner perinuclear zone separated by enlarged Golgi complexes.The profiles of elongated Herring bodies in the infundibulum were increased. The axon terminals were filled with heavily osmiophilic neurosecretory granules. The neurofilaments were slightly or moderately increased in number. No apparent changes were observed with regard to the neurotubuli in the SON neurons. The glial cells of the supraopticoneurohypophyseal tract showed reactive changes with a proliferation of filamentous elements. The biochemical and ultrastructural findings are discussed especially with respect to the mechanisms of transport and release of neurosecretory granules.     

THE INCORPORATION OF RADIOACTIVE AMINO ACIDS INTO BRAIN SUBCELLULAR PROTEINS DURING TRAINING

—Total proteins, free amino acids, tritiated water and subcellular proteins of mouse brain were examined for changes in radioactivity during operant conditioning after subcutaneous administration of labelled amino acids. The conditioning was based on appetitive learning, using sweetened milk as a reward. During training and incorporation for 20-30 min, both [³H]leucine and [1-¹⁴C]leucine underwent a significant increase in catabolism, resulting in a decreased radioactivity in the free amino acids. [2-²H]Methionine underwent a rapid loss of isotope, so that 90% of the radioactivity was in the form of tritiated water at the end of training, and this phenomenon masked any possible effect of training. The brain uptake of [³⁵S]methionine increased during the training, resulting in an increased radioactivity in the proteins. Uptake of [³H]lysine increased slightly during training only after 1 h incorporation and not after 20 or 30 min, as judged from a time course of radioactivity in the free amino acids. Incorporation into nuclear proteins increased selectively during 20 min, and into nuclear and cytosol proteins after 60 min incorporations. It is concluded that changes in the observed rate of incorporation of a precursor into brain subcellular proteins under the influence of behaviour might be the result of changes in precursor catabolism or uptake, or both, and that each amino acid behaves in a different way. Even the same amino acid gives different results depending on the isotope and its position in the amino acid.     

THE INCORPORATION AND FATE OF H3-TYROSINE IN THE HAIR CORTEX OF RATS OBSERVED BY RADIOAUTOGRAPHY

The incorporation of H³-tyrosine into the protein of the cells in the cortex of rat hair has been investigated by radioautography. In growing hairs, radioactivity is found in the matrix, the upper bulb, and the whole of the keratogenous zone up to the fully keratinized part of the shaft, 10 and 30 minutes after an injection of labelled tyrosine. This is unequivocal evidence of protein synthesis at these sites. There is a very precise relationship between the end of protein synthesis and the hardening of the cortical cells at the top of the keratogenous zone. The way in which the silver grains of the radioautographs are clustered indicates that at 30 minutes after the injection the isotope is distributed more evenly in the matrix and upper bulb than in the top of the keratogenous zone. Possibly this reflects a difference, at these sites, in the cell components engaged in protein synthesis, or in the proteins being synthesized. The fully keratinized and hardened part of the hair was not radioactive at 10 and 30 minutes after the injection of H³-tyrosine. The rate at which the radioactivity moves into this region shows that the hair of rats grows 0.9 mm/24 hours. Comparison of the degree of radioactivity along the growing hair in the 30-minute, 12-hour, and 36-hour materials shows conclusively that protein accumulates in the cortical cells during their keratinization. An injection of a labelled amino acid does not behave as an ideal pulse dose; consequently, the grain density over the hair cortex at 36 hours is 100 per cent larger than would be expected if an ideal pulse dose situation existed.     

Release in vitro of neurohypophysial proteins from neural lobe tissue slices and from isolated neurosecretory granules of the rat

Summary The release of neurophysin from neural lobe tissue slices and isolated neurosecretory granules of the rat was studied at various time intervals after injection of (³⁵S) cysteine into the supraoptic nucleus. For hours after isotope injection the release of radioactive neurophysin from neural lobe tissue was increased by depolarizing concentration of potassium in the presence of calcium ions. Fourteen and 30 days after isotope injection the release of radioactive neurophysin was relatively decreased in a medium of high potassium concentration which might be explained by the heterogeneity of the pool of neurophysin within the neural lobe. Four h after isotope injection the spontaneous release of neurophysin from neural lobe tissue was higher in dehydrated rats than in controls, and the neural lobes of these animals did not respond with an increased release of radioactive neurophysin when exposed to high potassium concentration.Eighteen h after isotope injection the predominating proportion of neurophysin-bound radioactivity was found in the neurosecretory granule fraction, whereas 14 days after injection a fairly equal amount of radioactivity was found in this fraction and in the soluble protein fraction. This indicates that with time an increasing amount of radioactive neurophysin passes from an intragranular to an extragranular pool.The spontaneous release of radioactive neurophysin from isolated neurosecretory granules was higher, and the increase of release upon exposure to an ATP-regenerating system was higher 14 days after isotope injection than 18 h after injection. This may imply that the neurosecretory material undergoes an intragranular maturation process to become more easily releasable. The release of radioactive neurophysin was inhibited in the presence of AMP and EDTA, which demonstrates the dependence of the release process of an ATPase and, probably, of calcium ions.Neurosecretory granules from dehydrated rats possessed a higher spontaneous release than those of control rats 18 h after injection, which may indicate an enhanced intragranular maturation process of the neurosecretory material due to osmotic stimulation.Abbreviations NSG neurosecretory granule - NSM neurosecretory material The present work was supported by grants from Carl-Bertel Nathhorsts vetenskapliga stiftelse, from Svenska Livförsäkrings bolags nämnd för medicinsk forskning, from Överläkare Albert Wallins fond and from the Medical Faculty of the University of Göteborg. I am most indebted to Miss Gull Grönstedt for careful secreterial work.     

Radioautographic studies on the neurohypophysial projections of the supraoptic and paraventricular nuclei in the rat

Summary The distribution of labelled axonal pathways was studied after unilateral stereotaxic injection of ³H-leucine into either supraoptic (SON) or paraventricular nuclei (PVN). In addition to extrahypothalamic projections of both nuclei, the main efferents appeared to run towards the neurohypophysis, yet with a strikingly different pattern. At the neurohypophysial level, the SO-neurohypophysial tract crossed the inner layers of the median eminence (ME) before scattering in the neural lobe. The PV-neurohypophysial pathway, by contrast, provided an exclusive innervation to the external layer of the whole neurohypophysial organ, including the median eminence, infundibular stalk and neural lobe. The functional correlates of the clear-cut anatomical distinctness between the two magnocellular neurosecretory systems are discussed.     

AXONAL TRANSPORT OF PROTEIN IN THE OPTIC NERVE OF OCTOPUS VULGARIS, LAM.

Abstract— The presence of an axonal flow of proteins has been investigated in the optic nerve and lobe of Octopus vulgaris up to 5 days after the intraocular injection of [³H]leucine. In each of these regions and in the posterior half of the eye the content of radioactivity has been determined in the TCA-soluble fraction and in the saline-soluble and insoluble protein fractions.
After subtraction of the values of the control side, the concentration of radioactive proteins in the optic nerve and lobe of the injected side was found to increase according to a triphasic pattern. An initial phase of fast increase was followed by a period of essentially steady values and, eventually, by a second phase of less rapid but more prolonged increment. In both regions the per cent of radioactive soluble proteins increased after the completion of the first phase.     

Precursors in the biosynthesis of vasopressin and oxytocin in the rat. Characteristics of all the components in high-performance liquid chromatography.

A reverse-phase high performance liquid-chromatography (h.p.l.c.) protocol has been developed, whereby all the major known posterior-pituitary components that are derived from the processing of pro-oxytocin and pro-vasopressin can be separated one from another. Thus, in a single chromatographic step, it has been possible to separate vasopressin (VP), oxytocin (OT), oxytocin-neurophysin (rOT-Np), vasopressin-neurophysin (rVP-Np) and vasopressin-glycopeptide (rVP-GP) from acid extracts of the neurointermediate lobes of rat pituitary glands. All these peptides except rVP-GP were labelled in the neural lobe by 24h after a hypothalamic injection of [35S]cysteine, whereas all except VP were labelled by 24h after a similar injection of [3H]leucine. Three major labelled proteins were isolated from 20 min [35S]cysteine-injected rats when extracts of the supraoptic nucleus were subjected to Sephadex G-75 chromatography, h.p.l.c. and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Immunoprecipitation with antisera raised against rat neurophysins, VP and OT revealed 21000- and 19000-mol.wt. common precursors to VP and rVP-Np and a 15000-mol.wt. common precursor to OT and rOT-Np. Some immunoreactive rVP-Np could occasionally be detected in the Vo of Sephadex G-75 chromatograms of Wistar rat supraoptic-nucleus extracts, but no evidence of [35S]neurophysin in this fraction was obtained from h.p.l.c. fingerprinting of its S-carboxymethylated tryptic digests. Radioimmunoassay for rVP-Np and rOT-Np revealed that about 70-80% of the total recovered immunoreactive neurophysin (IR-Np) in the supraoptic nucleus eluted from Sephadex G-75 and h.p.l.c. in the positions of rVP-Np and rOT-Np. Evidence is presented for an approx. 20000-mol.wt. rOT-Np in both Wistar and Brattleboro rats and for an approx. 20000-mol.wt. component in the Brattleboro rat that is recognized by vasopressin-neurophysin antisera.     

RAPID AXONAL TRANSPORT IN VITRO IN THE SCIATIC SYSTEM OF THE FROG OF FUCOSE-, GLUCOSAMINE- AND SULPHATE-CONTAINING MATERIAL

—An in vitro system from the frog has been used to study fast axonal transport of glycoproteins. The migration of [³H]fucose-, [³H]glucosamine- and [³⁵S]sulphate-labelled material was followed from the dorsal ganglia, along the sciatic nerve towards the gastrocnemius muscle. The distribution in different subcellular fractions, effect of cycloheximide and transport kinetics did not differ very much between fucose- and glucosamine-incorporation into the nerve. Cycloheximide blocked the synthesis of TCA-insoluble radioactivity, which was transported at a rate of 60–90 mm per day at 18°C, more effectively than the synthesis of stationary proteins in the ganglia. About 10 per cent of the TCA-insoluble and transported radioactivity was extracted by chloroform-methanol (2:1, v/v) and might be glycolipids and the rest glycoproteins. Results suggest that TCA-soluble activity, which was recovered in the nerve, originated in part from labelled macromolecules consumed along the axons. The rapidly transported TCA-insoluble radioactivity was 85 per cent particulate and mainly associated with structures sedimenting in the microsomal fraction. [³⁵S]Sulphate-labelled TCA-insoluble material was resistant towards chloroform-methanol (2:1, v/v) extraction and rapidly transported from the ganglia into the nerve. The synthesis was inhibited by cycloheximide. The material, probably proteoglycans, represented a quantitatively minor part of transported glycoproteins.     

A COMPARISON OF THE AXONAL TRANSPORT OF TAURINE AND PROTEINS IN THE GOLDFISH VISUAL SYSTEM

Abstract— Radioactive cystathionine, a metabolic precursor of taurine, was injected into the right eye of goldfish. At various times after injection the retina and both optic tecta were extracted with trichloroacetic acid (TCA) and the amount and nature of the radioactivity was determined. Radioactive taurine and inorganic sulfate were present in the TCA-soluble extract of retina and radioactive taurine and a small amount of inorganic sulfate was found in the contralateral optic tectum. That taurine is migrating intraaxonally and is not diffusing in extraaxonal spaces is suggested from experiments in which the migration of taurine was compared with that of [¹⁴C]mannitol, used here as a marker of extracellular diffusion. In the time studied (up to 15 h) mannitol did not migrate to the tectum, whereas taurine was detectable in the tectum as early as 8 h after injection. Since intra-axonal diffusion of amino acids and other small molecules in this system has been ruled out, it is likely that taurine is being transported axonally. The axonal transport of taurine was found to be similar to the fast component of protein transport because: (1) their rates of transport are similar, (2) the transport of both is blocked by the protein synthesis inhibitor cycloheximide, (3) vinblastine, which disrupts neurotubules, appears to have similar effects on both protein and taurine transport, and (4) both rapidly transported proteins and taurine remain mostly intra-axonal once they have been transported to the tectum. Taurine and proteins differ in that rapidly transported proteins are primarily paniculate in nature and localized to a large extent in nerve endings, while taurine is primarily in a soluble fraction and is present in nerve endings only in trace amounts. We suggest that taurine may be loosely linked to a newly synthesized protein in the soma and is then transported along with that protein on a similar conveying mechanism in the axoplasm.