Axonal transport of RNA during regeneration of the optic nerves of goldfish.

The distribution of radioactive RNA and RNA precursors in the goldfish optic tecta following intraocular injection of 3H-uridine has been studied during various stages of optic nerve regeneration. 3H-uridine was injected into the posterior chamber of the right eye 17, 30, or 60 days after both optic nerves were crushed. Five were sacrificed at time intervals ranging from 0.5 to 21 days after injection. One day prior to sacrificing, 14C-proline was also injected into the right eye as a marked of fast axonal protein transport. Seventeen to 23 days after crushing, the approximate time of nerve reconnection, the amount of radioactive RNA appearing in the left optic tectum was increased by more than ten times control values. Approximately 30 days after crushing the nerve, when the reconnected nerve is maturing, RNA values were still elevated, but significantly decreased from the earlier stage. By 60 days after crushing the optic nerve, the amounts of RNA in the left tectum was close to normal. Evidence suggesting that, at least, some of the radioactive RNA in the tectum originated from RNA transported along optic axons rather than from RNA synthesized locally in the tectum was provided by autoradiographic experiments. Autoradiograms of paraffin sections taken from the goldfish optic tecta after the intraocular injection of 3H-uridine showed a distribution of grains in a linear pattern, suggesting a distribution over the incoming fibers during the reconnection stage of regeneration. Electron microsocpic autoradiography of glutaraldehyde fixed epoxy sections confirmed that a significant number of grains (shown to be 3H-RNA) were, in fact, over regenerating optic axons. Intracranial injection of 3H-uridine, during the same stage of regeneration, on the other hand, resulted in a distribution of grains, specifically over cell perikaprya. These experiments suggest that during the reconnection phase of nerve regeneration, large amounts of RNA may be carried within regenerating optic axons as they enter the optic tectum.     

THE EFFECT OF CORDYCEPIN ON THE APPEARANCE OF [3H]RNA IN THE GOLDFISH OPTIC TECTUM FOLLOWING INTRAOCULAR INJECTION OF [3H]URIDINE

Abstract— Although biochemical and electron microscopic evidence has shown that RNA molecules may be found within axons, the origin of this RNA is not known. In order to determine if the RNA found in axons is synthesized in the nerve cell body and axonally transported, we have studied the effect of the RNA inhibitor cordycepin (3′-deoxyadenosine) on the retinal synthesis and axonal migration of radioactive RNA. Ten μg of cordycepin was injected into the right eye of 11 fish and 3 h later [³H]uridine was injected into the same eye. Twelve control fish were injected with [³H]uridine only and all fish were sacrificed 6 days later. Results of RNA extraction of retina and tecta showed that cordycepin decreased retinal RNA synthesis by approx 24%, while inhibiting the amount of [³H]RNA appearing in the contralateral tectum by 74%. Since the transport of RNA precursors was depressed by only 50%, (significantly different from the effect on RNA, P < 0.01) it seems unlikely that the action of cordycepin in decreasing tectal [³H]RNA levels was due solely to a decrease in the availability of labeled precursors for tectal RNA synthesis. For the purpose of blocking tectal RNA synthesis, 200 μg of cordycepin was injected intracranially several days after the intraocular injection of [³H]uridine. This route of cordycepin administration failed to significantly block the appearance of [³H]RNA in the tectum, suggesting that at least some of the [³H]RNA in the tectum was synthesized before arrival in the tectum itself. To be sure that cordycepin itself was not being transported, we injected cordycepin into the right eye of fish and 5 days later, injected fish intracranially with [³H]uridine. Autoradiograms were prepared and grains were counted over the fiber layers of left (experimental) and right (control) tecta. No significant difference was observed in the number of grains of left vs right tecta indicating that cordycepin itself is not axonally transported. These experiments support earlier findings from our laboratory which suggest that RNA may be axonally transported in goldfish optic fibers.     

AXONAL TRANSPORT OF RADIOACTIVITY IN THE GOLDFISH OPTIC SYSTEM FOLLOWING INTRAOCULAR INJECTION OF LABELLED RNA PRECURSORS

After injection of the tritiated RNA precursors [³H]guanosine, [³H]uridine or [³H]orotic acid into the eye of goldfish, labelled TCA-soluble material and RNA appeared to be axonally transported to the contralateral optic tectum. From the time courses of arrival in the tectum,‘average’rates of transport of 6 mm/day for the soluble material and 1·7 mm/day for the RNA were calculated. If the optic nerve was cut after the transported material had arrived in the tectum, about 60 per cent of the TCA-soluble material disappeared by 7 days after the cut, but almost none of the RNA. After a further 8- to 13-day period, the TCA-soluble material had declined by a further 50 per cent from the 7-day value, but the RNA by only 20 per cent. Thus, relatively little RNA was lost when the optic axons degenerated, an observation which suggested that the RNA might be extra-axonal. However, if the optic nerve was crushed before the arrival of the transported material, RNA did not appear in the tectum until the regenerating optic nerve fibres arrived. Therefore, the presence of RNA must be dependent on intact nerve fibres. Moreover, in the earliest stages of regeneration the proportion of transported RNA to TCA-soluble material was considerably higher than normal, suggesting that the regenerating fibres arrived in the tectum already carrying RNA. This implies that the RNA itself was transported in the optic fibres.     

Axonal transport of 4S RNA in the chick optic system

The axonal transport of tRNA has been investigated in the chick optic system. Chicks were injected with [³H]uridine intraocularly or intracranially and the RNA of the retina, nerve complex, and tecta separated by polyacrylamide gel electrophoresis and then counted. The ratio of TRNA to rRNA specific activities increased with time in both the nerve complex and contralateral tectum. The ratio increased more rapidly in the nerve complex than the tectum. However, no increase was observed in the case of intracranially injected animals. This is consistent with the axonal flow of tRNA. When [methyl-³H]methionine was used as precursor, the preferential labeling of 4S RNA to rRNA which resulted more clearly showed a transport of 4S RNA from the retinal cells to the tectum. In conclusion, it was found that about 40% of the radioactive RNA observed within the optic tectum 4 days after an intraocular injection of [³H]uridine was accounted for by 4S RNA which had flowed from the retina. However, the migration of a methylated RNA molecule of size 4S, but unrelated to tRNA, cannot be entirely eliminated.     

THE EFFECT OF INTRAOCULAR INJECTION OF CORDYCEPIN ON RETINAL RNA SYNTHESIS AND ON RNA AXONALLY TRANSPORTED DURING REGENERATION OF THE OPTIC NERVES OF GOLDFISH

Abstract— The presence of relatively large amounts of RNA has been demonstrated in regenerating axons of the goldfish optic nerve. Previous experiments have suggested that this R NA may be composed of only small molecular weight 4S RNA. The present experiments were performed in order to see if inhibiting RNA transport by intraocular injections of cordycepin causes a selective depletion of 4S RNA arriving in the contralateral optic tectum, and thus add further evidence that 4S RNA is axonally transported. Optic nerves were crushed in a group of goldfish and 18 days later 10.0 /tg of cordycepin was injected into the right eye followed 3 h later by injections of [³H]uridine into the same eye. Six days later the amount of axonally transported [³H]RNA was decreased by 89% compared with non-cordycepin treated controls. The effect of cordycepin on retinal RNA synthesis was shown by autoradiography to be primarily on retinal ganglion cell RNA synthesis with lesser effects on other cellular elements of the retina. SDS polyacrylamide gel electrophoresis at both 1 and 6 days after intraocular injections of cordycepin and [³H]uridine, showed that cordycepin blocks the retinal synthesis of ribosomal RNAs but appeared to have little effect on the synthesis of 4S RNA. When transported RNA in the tectum was fractionated by gel electrophoresis 6 days after injection, it was found that the amount of ribosomal RNA was decreased by approx 70% as a result of cordycepin pretreatment. This correlated well with the effect of cordycepin on the transport of available RNA precursors (also decreased by approx 70%) and is consistent with the contention that in these experiments ribosomal RNA is synthesized in the tectum itself and is not axonal. The amount of [³H] 4S RNA arriving in the tectum, however, was decreased by greater than 90% suggesting that its presence in the tectum was not entirely dependent on the availability of ³H precursors for local synthesis in the tectum. These results are consistent with data suggesting that 4S RNA is the predominant, if not the only, RNA species axonally transported during regeneration of goldfish optic nerves.     

Modulation of taurine uptake in the goldfish retina and axonal transport to the tectum¶Effect of crushing the optic nerve or axotomy

Summary. Although there are a great number of studies concerning the uptake of taurine in several tissues, the regulation of taurine transport has not been studied in the retina after lesioning the optic nerve. In the present study, isolated retinal cells of the goldfish retina were used either immediatly after cell suspension or in culture. The high-affinity transport system of [³H]taurine in these cells was sodium-, temperature- and energy-dependent, and was inhibited by hypotaurine and β-alanine, but not by γ-aminobutyric acid. There was a decrease in the maximal velocity (V_max) without modifications in the substrate affinity (K_m) after optic axotomy. These changes were mantained for up to 15 days after the lesion. The results might be the summation of mechanisms for providing extracellular taurine to be taken up by other retinal cells or eye structures, or regulation by the substrate taurine, which increases after lesioning the optic nerve. The in vivo accumulation of [³H]taurine in the retina after intraocular injection of [³H]taurine was affected by crushing the optic nerve or by axotomy. A progressive retinal decrease in taurine transport was observed after crushing the optic nerve, starting at 7 hours after surgery on the nerve. The uptake of [³H]taurine by the tectum was compensated in the animals that were subjected to crushing of the optic nerve, since the concentration of [³H]taurine was only different from the control value 24 hours after the lesion, indicating an efficient transport by the remaining axons. On the contrary, the low levels of [³H]taurine in the tectum after axotomy might be an index of the non-axonal origin of taurine in the tectum. Axonal transport was illustrated by the differential presence of [³H]taurine in the intact or crushed optic nerve. The uptake of [³H]taurine into retinal cells in culture in the absence or in the presence of taurine might indicate the existence of an adaptive regulation of taurine transport in this tissue, however taurine transport probably differentially occurs in specific populations of retinal cells. The use of a purified preparation of cells might be useful for future studies on the modulation of taurine transport by taurine in the retina and its role during regeneration. Received June 11, 1999/Accepted August 31, 1999     

Xefiltin,a Xenopus laevis neuronal intermediate filament protein,is expressed in actively growing optic axons during development and regeneration

Neurofilaments are an important structural component of the axonal cytoskeleton and are made of neuronal intermediate filament (nIF) proteins. During axonal development, neurofilaments undergo progressive changes in molecular composition. In mammals, for example, highly phosphorylated forms of the middle- and high-molecular-weight neurofilament proteins (NF-M and NF-H, respectively) are characteristic of mature axons, whereas nIF proteins such as α-internexin are typical of young axons. Such changes have been proposed to help growing axons accommodate varying demands for plasticity and stability by modulating the structure of the axonal cytoskeleton. Xefiltin is a recently discovered nIF protein of the frog Xenopus laevis, whose nervous system has a large capacity for regeneration and plasticity. By amino acid identity, xefiltin is closely related to two other nIF proteins, α-internexin and gefiltin. α-Internexin is found principally in embryonic axons of the mammalian brain, and gefiltin is expressed primarily in goldfish retinal ganglion cells and has been associated with the ability of the goldfish optic nerve to regenerate. Like gefiltin in goldfish, xefiltin in Xenopus is the most abundantly expressed nIF protein of mature retinal ganglion cells. In the present study, we used immunocytochemistry to study the distribution of xefiltin during optic nerve development and regeneration. During development, xefiltin was found in optic axons at stage 35/36, before they reach the tectum at stage 37/38. Similarly, after an orbital crush injury, xefiltin first reemerged in optic axons after the front of regeneration reached the optic chiasm, but before it reached the tectum. Thus, during both development and regeneration, xefiltin was present within actively growing optic axons. In addition, aberrantly projecting retinoretinal axons expressed less xefiltin than those entering the optic tract, suggesting that xefiltin expression is influenced by interactions between regenerating axons and cells encountered along the visual pathway. These results support the idea that changes in xefiltin expression, along with those of other nIF proteins, modulate the structure and stability of actively growing optic axons and that this stability is under the control of the pathway which growing axons follow. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 811–824, 1997     

Differential expression of calretinin in the developing and regenerating zebrafish visual system

Calretinin is a calcium-binding protein which participates in a variety of functions including calcium buffering and neuronal protection. It also serves as a developmental marker of retinal ganglion cells (RGCs). In order to study the role of calretinin in the development and regeneration of RGCs, we have studied its pattern of expression in the retina at different developmental stages, as well as during optic nerve regeneration by means of immunohistochemistry. During development, calretinin is found for the first time in RGCs when they connect with the optic tectum. Optic nerves from adult zebrafish were crushed and after different survival times, calretinin expression in the retina, optic nerve tract and optic tectum was studied. From the day of crushing to 10 days later, calretinin expression was found to be downregulated within RGCs and their axons, as was also observed during the early developmental stages of RGCs, when they are not committed to a definite cell phenotype. Moreover, 13 days after lesion, when the regenerating axons arrived at the optic tectum, a recovery of calretinin immunoreactivity within the RGCs was observed. These results indicate that calretinin may play an important role during optic nerve regeneration, Thus, the down-regulation of Calretinin during the growth of the RGC axons towards the target during development as well as during their regeneration after injury, indicates that an increase the availability of cytosolic calcium is integral to axon outgrowth thus recapitulating the pattern observed during development.     

Activity of choline acetyltransferase and acetylcholinesterase in the goldfish optic tectum after disconnection

Activities of choline acetyltransferase (CAT) and acetylcholinesterase (AChE) were investigated in the goldfish optic tectum after disconnection of the optic afferents. Permanent disconnection was achieved by eye removal, and optic nerve crush produced a temporary disconnection until regeneration. There was a rapid loss in total activity per tectum for both enzymes under the two disconnection conditions. At longer intervals after optic nerve crush the levels of total activity for both enzymes returned toward control levels, as regeneration of the nerve proceeded. Total activity for both enzymes remained depressed after eye removal, however. Variable results were obtained in specific activity data, expressed per unit protein, although ther was a 10% loss in specific activity of CAT at early intervals after eye removal. The data are interpreted as consistent with the possibility that at least a fraction of the axons in the retinotectal pathway of goldfish are cholinergic, and parallel our previous observations showing similar rapid losses of nicotinic-cholinergic receptor activity in this system.     

Changes in axonal transport of phospholipids in the regenerating goldfish optic system

Changes in axonally transported phospholipids of regenerating goldfish optic nerve were studied by intraocular injection of [2-³H]glycerol 9 days and 16 days after nerve crush at 30°C. The four major glycerophospholipids all showed substantial increases in transported radioactivity above non-regenerating controls at both time points, these being maximal (15- to 35-fold) in the optic nerve-tract at 9 days and about half as great at 16 days. In the contralateral optic tectum transported label increased 6- to 13-fold at 9 days and 10- to 25-fold at 16 days in the various glycerophospholipids. While all glycerophospholipids showed absolute increases in both tissues, PS and PI increased relatively more, especially in the tectum. The regeneration-associated increases in transported label of all glycerophospholipids were larger than those previously demonstrated for gangliosides and glycoproteins in the same system. Special Issue dedicated to Dr. Eugene Kreps.     

Axonal transport of lipid in goldfish optic axons

After injection of labeled glycerol, choline, or serine into the eye of goldfish, labeled lipids were axonally transported along the optic nerve to the optic tectum. although the different precursors were presumably incorporated into somewhat different lipid populations, all three were approximately equally effective in labeling the lipids transported to the tectum, but the amount of transported material remaining in the nerve was different, being highest with choline and lowest with serine. The labeled lipids appeared in the tectum within 6 hr of the injection, indicating a fast rate of transport, but continued to accumulate over a period of 1–2 weeks, which presumably reflects the time course of their release from the cell body. Since there was a gradual increase in the proportion of labeled lipid in the tectum during this period, some other process in addition to fast axonal transport may have affected the distribution of the lipids along the optic axons. When [³H]choline was used as precursor, the transported material included a small amount of TCA-soluble material, which was probably mainly phosphorylcholine, with labeled acetylcholine appearing in only insignificant amounts. With serine, which gave rise to a large amount of axonally transported protein in addition to lipid, a late increase in the amount of labeled lipid in the tectum was seen, accompanied by a decrease in labeling of the protein fraction.     

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.     

EFFECT OF ACTINOMYCIN-D ON LABELLED MATERIAL IN THE RETINA AND OPTIC TECTUM OF GOLDFISH AFTER INTRAOCULAR INJECTION OF TRITIATED RNA PRECURSORS

—After injection of [³H]guanosine or [³H]uridine into the eye of goldfish, labelled acid-soluble radioactivity and RNA appeared in the contralateral optic tectum. When 0·1 μg actinomycin-D was injected into the eye 4 h before the precursor, the labelled RNA in the retina by 18 h after the injection was only 23 per cent of normal, but the acid-soluble radioactivity in the retina and the small amount of labelled acid-soluble material conveyed to the tectum were not significantly affected; by 15–20 days after the injection the acid-soluble radioactivity in the retina was reduced and the amount of labelled material conveyed to the tectum, including both RNA and acid-soluble fractions, was less than normal. When the actinomycin was injected at various times before or after the precursor and measurements were made 6 days later, it was found that the amount of labelled RNA conveyed to the tectum was maximally decreased if the inhibitor was given simultaneously with or up to 4 h before the precursor, whereas the amount of RNA was normal if the incorporation of the precursor had been allowed to proceed for 12 h before the inhibitor was given. This result would be consistent with the view that much of the RNA conveyed to the tectum had been synthesized in the retina within 12 h of the injection of the precursor, and had then presumably been axonally transported in the optic nerve to the tectum. However, since the acid-soluble material conveyed to the tectum was also reduced as a result of the actinomycin treatment, the results of these experiments with actinomycin do not unequivocally rule out the possibility that the RNA appearing in the tectum had been locally synthesized from the axonally transported acid-soluble material. In the retina, both the labelled RNA and acid-soluble fractions were reduced, to about 15 and 60 per cent of normal, respectively, without any relationship to the time between the injection of inhibitor and precursor. The discrepancy between the effects of the labelling of the retina and the labelling of material conveyed to the tectum could be correlated with the fact that the actinomycin caused severe damage to the retinal receptor cells, while leaving the ganglion cells relatively intact. The more pronounced effect of actinomycin on the receptor cells could in turn be correlated with the fact that these cells had a higher rate of RNA synthesis than the ganglion cells. This was demonstrated autoradiographically by the higher rate of incorporation of [³H]uridine into the receptor cells. Intracranial injection of actinomycin did not affect significantly the amount of labelled RNA conveyed to the tectum, which would argue against the local synthesis of this RNA. It is not certain, however, that the actinomycin penetrated deeply enough into the tectum to be effective.     

Structural analysis of glycosaminoglycans derived from axonally transported proteoglycans in regenerating goldfish optic nerve

Structural characteristics of glycosaminoglycans (GAGs) derived from axonally transported proteoglycans (PGs) were compared in 21 day regenerating and intact goldfish optic tracts. Twenty one days following unilateral optic nerve crushes, fish received intraocular injections of³⁵SO₄. Eight hours post injection, tracts were removed and the³⁵SO₄-labeled GAGs, chondroitin sulfate (CS) and heparan sulfate (HS), isolated. The HS from regenerating optic tracts had a DEAE elution profile indicative of decreased charge density, while heparitinase treatment of HS followed by Sephadex G50 analysis of the resulting fragments showed a change in the elution pattern, suggesting reduced overall sulfation. HPLC analysis of HS disaccharides revealed a difference in the sulfation pattern of regenerating tract HS, characterized by the reduced presence of tri-sulfated disaccharides. Other structural features, such as the sizes of CS and HS, and the sulfation of CS, showed no changes during regeneration. These results indicate that changes in the structure of axonally transported HS accompany regeneration of goldfish optic axons.     

Rapid transport of protein in the optic system of the goldfish

Abstract— Several amino acids, particularly [³H]proline and [³H]asparagine specifically and efficiently labelled rapidly transported proteins in the goldfish optic nerve and tectum after intraocular injection. Studies with these amino acids showed that the rapidly transported proteins moved as a discrete band at a rate which was temperature-dependent, and was equal to 70-100 mm per day at 20°C. Transported protein in the optic tectum was 80 per cent particulate and was found in synaptosomal, mitochondrial, and myelin fractions, but not in purified nuclei or ribosomes.     

Axoplasmic transport of RNA

The transport of RNA from the ganglion cell bodies within the retina to the contralateral optic tectum has been studied in the chick following intraocular injection of radioactive uridine. By tracing the appearance of labeled RNA at the proximal end of the optic nerve as it leaves the eyeball and comparing this to the time of arrival of RNA within the optic tectum, the migratory velocity of axonal RNA has been calculated to be around 12 mm per day. The continuation of RNA migration to the optic tectum in the presence of intracerebrally injected actinomycin-D but not in the presence of the intraocularly injected drug, suggests a retinal site of synthesis of the excess RNA found in the tectum innervated by the injected eye. A study of the rate of disppearance of radioactivity of the transported RNA in the optic lobes, suggested that this RNA turns over more rapidly than the bulk of tectal RNA. The destination of migrating RNA within the optic tectum has been autoradiographically examined. Most radioactive RNA is found in the outer tectal layers in which are found the afferent fibers of the optic tract and most of their synaptic terminations. Label is not confined to these areas however but is also present in the deeper layers of the optic tectum which are not known to contain any primary synapses of the axons from retinal ganglion cells.     

Protein phosphorylation: Localization in regenerating optic axons

A number of axonal proteins display changes in phosphorylation during goldfish optic nerve regeneration (Larrivee and Grafstein, 1989). (1) To determine whether the phosphorylation of these proteins was closely linked to their synthesis in the retinal ganglion cell body, cycloheximide was injected intraocularly into goldfish whose optic nerves had been regenerating for 3 weeks. Cycloheximide reduced the incorporation of [³H]proline and³²P orthophosphate into total nerve protein by 84% and 46%, respectively. Of the 20 individual proteins examined, 17 contained less than 15% of the [³H]proline label measured in corresponding controls, whereas 18 proteins contained 50% or more of the³²P label, suggesting that phosphorylation was largely independent of synthesis. (2) To deterine whether the proteins were phosphorylated in the ganglion cell axons, axonal transport of proteins was blocked by intraocular injection of vincristine. Vincristine reduced [³H]proline labeling of total protein by 88% and³²P labeling by 49%. Among the individual proteins [³H]proline labeling was reduced by 90% or more in 18 cases but³²P labeling was reduced only by 50% or less. (3) When³²P was injected into the cranial cavity near the ends of the optic axons, all of the phosphoproteins were labeled more intensely in the optic tract than in the optic nerve. These results suggest that most of the major phosphoproteins that undergo changes in phosphorylation in the course of regeneration are phosphorylated in the optic axons.Abbreviations SDS sodium lauryl sulfate - GAP growth associated protein - TCA trichloracetic acid - kD kilodalton     

THE DIRECT MEASUREMENT OF THE AXOPLASMIC TRANSPORT OF INDIVIDUAL RNA SPECIES: TRANSFER BUT NOT RIBOSOMAL RNA IS TRANSPORTED

Analysis of chick retinal and tectal RNA revealed that in addition to the major cytoplasmic RNAs (rRNA and tRNA), a number of the small mol wt nuclear RNAs (snRNAs) can also be detected. Subfractionation data indicated that one of these molecules, DD′, is of at least 95% nuclear location within the retina. Thus, very little, if any, of the retinal DD′ is available for axoplasmic transport from the retina into the optic nerve and tectum. Following intraocular injection of [³H]uridine, considerable incorporation of isotope into DD′ was observed within the optic tectum after 4, 8 and 16 days. This result indicates the presence of considerable local (i.e. tectal) synthesis. The specific activities of 29S, 18S and 5S rRNA and 4s tRNA relative to that of DD′ were measured in the optic tectum 8 and 16 days after the intraocular introduction of [³H]uridine. The same measurements were also made in intracranially injected animals. While the 29S/DD′, 18S/DD′ and 5S/DD′ specific activity ratios obtained were independent of the injection route, the 4S/DD′ ratio obtained from intraocularly injected animals was significantly greater (at least 2-fold) than that obtained from intracranially injected animals. Similar analysis was also performed with the optic nerve complex at 16 days post-injection with identical results. These results demonstrate that tRNA, but not rRNA, is transported from the retina into the optic nerve and tectum in the 2-day-old chicken.     

Restoration of retino-tectal connections in frogs during regeneration of the optic nerve

At various times after unilateral division of the optic nerve in the frogRana temporaria L. evoked potentials in response to electrical stimulation of the optic nerve were investigated in a segment distal to the site of operation, spike activity was recorded from endings of regenerating and intertectal axons when stimuli of different shapes were placed in the field of vision, and the distribution of axonal bulbs of growth by depth in the tectum mesencephal was studied electron-microscopically. During regeneration of the axons the responses of the retinal ganglionic cells to visual stimuli retained most of their individual features. Myelinated axons of the retinal ganglionic cells regenerate first (starting on the 21st day after operation). Myelination of these fibers lags significantly behind their growth and is complete more than 100 days after the operation. Unmyelinated axons of the retinal ganglionic cells grow up toward the tectum mesencephali after myelinated axons (80 or more days after the operation). Axonal bulbs of growth in the initial periods after the operation are located close to the pial surface and the level of spread of the myelinated axons of the retinal ganglionic cells differs significantly from their normal level of localization. Intertectal connections persist after division of the nerve and are activated by visual stimuli during regeneration of the axons of the retinal ganglionic cells. Connections were found mainly between intertectal fibers terminating superficially and retinal ganglionic cells belonging to class 1 and 2 detectors. Axons of the retinal ganglionic cells grow up toward the caudal region of the tectum mesencephali later than toward the rostral region.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 5, No. 6, pp. 611–620, November–December, 1973.     

Taurine trophic modulation of goldfish retinal outgrowth and its interaction with the optic tectum

Summary. Goldfish retinal explant outgrowth in the presence of fetal calf serum is stimulated by taurine. In the absence of it, but with glucose in the medium, length of neurites is still elevated by the amino acid. Using the medium in the presence of glucose, but in the absence of fetal calf serum, we explored the effect of optic tectum medium from cultures of them coming from goldfish without crush of the optic nerve or 3, 5, 10, 14 and 20 days after crush. Retinal explants, intact or from goldfish with crush of the optic nerve 10 days prior to starting the culture, were employed in order to measure the possible effect of optic tectum media and the inter action with taurine. In other type of experiments the optic nerve was crushed 1, 2, 4, 7 and 10 days before dissection of the optic tectum, and then co-cultured with intact or 10 days post-crush retinal explants. Optic tectum media produced a time-dependent effect on outgrowth in lesioned retinas with a maximum effect around 5 days after the lesion for the corresponding optic tectum. Taurine, 4 mM, did not further affect the outgrowth in the presence of optic tectum media, but did significantly increase length of neurites either in intact or in post-lesion retinas. Co-culture of optic tectum at different days post-lesion and retinas at 10 days post-lesion increased the outgrowth around 4 days post-lesion, in a preparation resulting in mutual effects of both types of tissues. The addition of taurine in these conditions did not further increase outgrowth, rather inhibited it according to the time after lesion of optic nerve corresponding to the co-cultured optic tectum. The effect of taurine was concentration-dependent, since 0.2 mM was more effective than 2 or 4 mM in the presence of optic tectum with lesion of 2 days. These results demonstrate the time-course of the regeneration processes in the visual system of goldfish, indicating the crucial periods after crush in which the tectum could produce stimulation and later decrease or no effect on outgrowth from the retina. In addition, they are evidences of the interaction between taurine and optic tectum production of time-produced specific agents. The mechanisms underlying these effects are closely related to calcium, as it was demonstrated by the addition of extracellular or intracellular chelators to the medium, which inhibited the effects of the optic tectum and the trophic properties of taurine in this system. The inhibitor of taurine transport, guanidoethylsulfonate, also decreased the stimulatory effects of the optic tectum and of taurine, indicating an interaction of substances produced by the tectum with taurine, and an effect of taurine mediated through its entrance to the cells. Overall, retinal explants outgrowth in the absence of fetal calf serum, the interaction of agents of the optic tectum and taurine modulates outgrowth from the retina, and these effects are mediated by calcium levels and by the levels of intracellular taurine.