Fast axonally transported proteins in regenerating goldfish optic axons

Fast axonal transport of protein was examined in regenerating goldfish optic axons after a lesion of either the optic tract or optic nerve, which revealed changes in the original intact optic axon segments or in the newly regenerated axon segments, respectively. In animals killed either 6 or 24 hr after injection of 3H-proline into the eye, labeling of total fast-transported protein in the original axon segments was increased by 2 d after the lesion, reached a peak of nearly 20 X normal at 2 weeks, and then declined to a level somewhat above normal at 12 weeks. When the labeling of individual transported proteins was examined by 2-dimensional gel electrophoresis, it was found that no new labeled proteins appeared during regeneration, but all proteins examined showed an increase in labeling. Among the various proteins, there was great variation in the magnitude and time course of the labeling increase. The largest increase, to nearly 200 X normal with 6 hr labeling, was seen in a protein with a molecular weight of 45 kDa and a pl of about 4.5, resembling a protein that has previously been designated a “growth-associated protein” (GAP-43; Skene and Willard, 1981a). The proteins showing increased labeling included a small fraction of cytoskeletal proteins (alpha-tubulin, beta-tubulin, and actin) that was apparently transported at a much faster rate than is usually expected of these constituents. In the new axon segments, the total protein labeling was increased by 1 week after the lesion, remained elevated at a nearly constant level of about 7 X normal from about 2 to 5 weeks, and then declined to levels somewhat above normal by 12 weeks. The 45 kDa protein again showed the largest increase, and became the single most prominently labeled constituent in the new axons. On the basis of the time course of labeling in both original and new axon segments during regeneration, the fast-transported proteins were tentatively separated into 5 classes that may represent groups of proteins that are coregulated during regeneration. They may conceivably correspond to different functional or structural entities within the neuron.

[1]  D. Larrivee,et al.  In Vivo Phosphorylation of Axonal Proteins in Goldfish Optic Nerve During Regeneration , 1987, Journal of neurochemistry.

[2]  J. Sparrow,et al.  Role of fast axonal transport in regeneration of goldfish optic axons. , 1987, Progress in brain research.

[3]  K. Kalil,et al.  Elevated synthesis of an axonally transported protein correlates with axon outgrowth in normal and injured pyramidal tracts , 1986, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[4]  E. Nedivi,et al.  A protein associated with axon growth, GAP-43, is widely distributed and developmentally regulated in rat CNS , 1986, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[5]  N. Ingoglia,et al.  Posttranslational Protein Modification by Amino Acid Addition in Regenerating Optic Nerves of Goldfish , 1986, Journal of neurochemistry.

[6]  B. Grafstein THE RETINA AS A REGENERATING ORGAN , 1986 .

[7]  K. Pfenninger,et al.  Nerve growth cones isolated from fetal rat brain. III. Calcium- dependent protein phosphorylation , 1985, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[8]  R. Rulli,et al.  Proteins in fast axonal transport are differentially transported in branches of sensory nerves , 1985, Brain Research.

[9]  I. Mcquarrie Stages of axonal regeneration following optic nerve crush in goldfish: contrasting effects of conditioning nerve lesions and intraocular acetoxycycloheximide injections , 1985, Brain Research.

[10]  B. Grafstein,et al.  Changes in Protein Content of Goldfish Optic Nerve During Degeneration and Regeneration Following Nerve Crush , 1985, Journal of neurochemistry.

[11]  E. Repasky,et al.  Rapid mobility of motile varicosities and inclusions containing alpha- spectrin, actin, and calmodulin in regenerating axons in vitro , 1985, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[12]  Michael P. Sheetz,et al.  Single microtubules from squid axoplasm support bidirectional movement of organelles , 1985, Cell.

[13]  R. Hunt,et al.  Specific changes in axonally transported proteins during regeneration of the frog (Xenopus laevis) optic nerve , 1985, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[14]  D. Lovinger,et al.  Selective increase in phosphorylation of a 47-kDa protein (F1) directly related to long-term potentiation. , 1985, Behavioral and neural biology.

[15]  J W Griffin,et al.  Control of axonal caliber by neurofilament transport , 1984, The Journal of cell biology.

[16]  J. Skene Growth-associated proteins and the curious dichotomies of nerve regeneration , 1984, Cell.

[17]  J. Aletta,et al.  Routing of transmitter and other changes in fast axonal transport after transection of one branch of the bifurcate axon of an identified neuron , 1984, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[18]  R. Hunt,et al.  Axonal transport of [35S]Methionine labeled proteins in Xenopus optic nerve: Phases of transport and the effects of nerve crush on protein patterns , 1984, Brain Research.

[19]  S. Easter,et al.  A comparison of the normal and regenerated retinotectal pathways of goldfish , 1984, The Journal of comparative neurology.

[20]  M. Bisby Retrograde Axonal Transport and Nerve Regeneration , 1984 .

[21]  L. Benowitz,et al.  Increased transport of 44,000- to 49,000-dalton acidic proteins during regeneration of the goldfish optic nerve: a two-dimensional gel analysis , 1983, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[22]  M. Whitnall,et al.  Changes in Perikaryal organelles during axonal regeneration in goldfish retinal ganglion cells: An analysis of protein synthesis and routing , 1983, Brain Research.

[23]  D. Aunis,et al.  Evidence for tubulin-binding sites on cellular membranes: plasma membranes, mitochondrial membranes, and secretory granule membranes , 1983, Journal of Cell Biology.

[24]  J. Schmidt,et al.  The re-establishment of synaptic transmission by regenerating optic axons in goldfish: Time course and effects of blocking activity by intraocular injection of tetrodotoxin , 1983, Brain Research.

[25]  G. Perry,et al.  Protein Synthesis and Rapid Axonal Transport During Regrowth of Dorsal Root Axons , 1983, Journal of neurochemistry.

[26]  G. Stone,et al.  Fast‐Transported Glycoproteins and Nonglycosylated Proteins Contain Sulfate , 1983, Journal of neurochemistry.

[27]  G. Stone,et al.  Glycosylation as a Criterion for Defining Subpopulations of Fast‐Transported Proteins , 1983, Journal of neurochemistry.

[28]  B. Grafstein CHROMATOLYSIS RECONSIDERED: A NEW VIEW OF THE REACTION OF THE NERVE CELL BODY TO AXON INJURY , 1983 .

[29]  Bernice Grafstein,et al.  Protein synthesis and axonal transport in goldfish retinal ganglion cells during regeneration accelerated by a conditioning lesion , 1982, Brain Research.

[30]  M. Murray,et al.  A quantitative study of the reinnervation of the goldfish optic tectum following optic nerve crush , 1982, The Journal of comparative neurology.

[31]  M. Murray A quantitative study of regenerative sprouting by optic axons in goldfish , 1982, The Journal of comparative neurology.

[32]  M. Whitnall,et al.  Perikaryal routing of newly synthesized proteins in regenerating neurons: Quantitative electron microscopic autoradiography , 1982, Brain Research.

[33]  I. Mcquarrie,et al.  Protein synthesis and fast axonal transport in regenerating goldfish retinal ganglion cells , 1982, Brain Research.

[34]  M. Whitnall,et al.  Bidirectional axonal transport of glycoproteins in goldfish optic nerve , 1982, Experimental Neurology.

[35]  J. Skene,et al.  Molecular Events in Axonal Regeneration , 1982 .

[36]  David L. Wilson,et al.  Protein Synthesis and Axonal Transport During Nerve Regeneration , 1981, Journal of neurochemistry.

[37]  M. Whitnall,et al.  The relationship between extracellular amino acids and protein synthesis is altered during axonal regeneration , 1981, Brain Research.

[38]  I. Mcquarrie,et al.  Effect of a conditioning lesion on optic nerve regeneration in goldfish , 1981, Brain Research.

[39]  J. Skene,et al.  Electrophoretic Analysis of Axonally Transported Proteins in Toad Retinal Ganglion Cells , 1981, Journal of neurochemistry.

[40]  J. Skene,et al.  Characteristics of growth-associated polypeptides in regenerating toad retinal ganglion cell axons , 1981, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[41]  J. Freeman,et al.  Changes in axonally transported proteins during axon regeneration in toad retinal ganglion cells , 1981, The Journal of cell biology.

[42]  W. Gispen,et al.  Immunohistochemical localization of a phosphoprotein (B-50) isolated from rat brain synaptosomal plasma membranes , 1981, Brain Research Bulletin.

[43]  B. Grafstein,et al.  Intracellular transport in neurons. , 1980, Physiological reviews.

[44]  B. Grafstein,et al.  Effect of a conditioning lesion on regeneration of goldfish optic axons: ultrastructural evidence of enhanced outgrowth and pinocytosis , 1980, Brain Research.

[45]  D. Cowburn,et al.  Biosynthesis and intra-axonal transport of proteins during neuronal regeneration. , 1980, The Journal of biological chemistry.

[46]  W. Gispen,et al.  Purification and Some Characteristics of an ACTH‐Sensitive Protein Kinase and Its Substrate Protein in Rat Brain Membranes , 1980, Journal of neurochemistry.

[47]  N. Zisapel,et al.  Tubulin: An Integral Protein of Mammalian Synaptic Vesicle Membranes , 1980, Journal of neurochemistry.

[48]  P. Gambetti,et al.  Distribution of [3H]RNA in goldfish optic tectum following intraocular or intracranial injection of [3H]uridine. Evidence of axonal migration of RNA in regenerating optic fibers , 1978, Brain Research.

[49]  G. Stone,et al.  Two-dimensional gel electrophoresis of proteins in rapid axoplasmic transport , 1978, Brain Research.

[50]  M. Willard,et al.  Subcellular fractionation of intra-axonally transport polypeptides in the rabbit visual system. , 1978, Proceedings of the National Academy of Sciences of the United States of America.

[51]  B. Grafstein,et al.  Axonal transport and transneuronal transfer in mouse visual system following injection of [3H]fucose into the eye , 1977, Experimental Neurology.

[52]  M. Murray Regeneration of retinal axons into the goldfish optic tectum , 1976, The Journal of comparative neurology.

[53]  R. Lasek,et al.  The slow component of axonal transport. Identification of major structural polypeptides of the axon and their generality among mammalian neurons , 1975, The Journal of cell biology.

[54]  P. O’Farrell High resolution two-dimensional electrophoresis of proteins. , 1975, The Journal of biological chemistry.

[55]  W. Bonner,et al.  A film detection method for tritium-labelled proteins and nucleic acids in polyacrylamide gels. , 1974, European journal of biochemistry.

[56]  M. Murray,et al.  Transport of protein in goldfish optic nerve during regeneration. , 1969, Experimental neurology.

[57]  M. Murray,et al.  Changes in the morphology and amino acid incorporation of regenerating goldfish optic neurons. , 1969, Experimental neurology.

[58]  B. McEwen,et al.  FAST AND SLOW COMPONENTS IN AXONAL TRANSPORT OF PROTEIN , 1968, The Journal of cell biology.