Kinetic properties of normal and perturbed axonal transport of serotonin in a single identified axon.

1. The axonal transport of pulses of [3H]serotonin was studied in an axon of the serotonergic giant cerebral neurone (GCN) of Aplysia californica. 2. [3H]serotonin was transported as a discrete peak which was followed by a relatively low, smooth trail. 3. The peak broadened as it moved along the axon, sometimes skewing in the proximal direction. 4. The velocity of the transport was highly dependent on temperature, but the rate of peak broadening was not. The velocity was 130 mm per day at 23 degrees C and 48 mm per day at 14 degrees C. The rate of broadening was 143 micrometer per mm transport at 23 degrees C and 156 micrometer per mm transport at 14 degrees C. 5. In another series of experiments, almost the entire length of the lip nerve, which contained the axon of GCN, was maintained at 1‐‐3 degrees C to block transport. The GCN's cell body and the proximal few millimetres of the nerve were maintained at 23 degrees C. As a result, the amount of [3H]serotonin in the proximal segment of the nerve increased manyfold during periods of up to 4 hr. The concentrated pulse of [3H]serotonin resulting from this treatment was transported more slowly than normal after the cooling was terminated. Sometimes, a minor peak split from the major peak of radioactivity and was transported a normal velocity. 6. Incubation of the cerebral ganglion and nerves for 16 hr in the presence of anisomycin, an inhibitor of protein synthesis, reduced by nearly fourfold the amount of [3H]serotonin subsequently exported into the axon of the GCN. The transport velocity at this reduced concentration was less than half the normal value. If the concentration of [3H]serotonin in the axon was restored to normal in the presence of anisomycin, the velocity of transport was also returned to normal. 7. We conclude that the velocity of transport of serotonergic vesicles in the axon of the GCN is positively dependent on the local concentration of vesicles, except at very high concentrations, where the dependence is negative. The results are interpreted in the context of a model for transport in which the serotonergic vesicle is translocated along the axon in an intermittent fashion, alternating between moving and stationary states. The local concentration of the vesicles along the axon would control the observed velocity of transport by altering the partitioning between the two states, that is, by changing the percentage of time vesicles spend in each state.

[1]  G. Siggins,et al.  Axonal transport of organelles visualized by light microscopy: Cinemicrographic and computer analysis , 1977, Brain Research.

[2]  G. Odell A new mathematical continuum theory of axoplasmic transport. , 1976, Journal of theoretical biology.

[3]  J. H. Schwartz,et al.  Alterations in amounts and rates of serotonin transported in an axon of the giant cerebral neurone of Aplysia californica. , 1976, The Journal of physiology.

[4]  S. Ochs Retention and redistribution of proteins in mammalian nerve fibres by axoplasmic transport. , 1975, The Journal of physiology.

[5]  J. H. Schwartz,et al.  Effect of inhibiting protein synthesis on axonal transport of membrane glycoproteins in an identified neuron ofAplysia , 1975, Brain Research.

[6]  S. Brimijoin Stop-flow: a new technique for measuring axonal transport, and its application to the transport of dopamine-beta-hydroxylase. , 1975, Journal of neurobiology.

[7]  G. Gross,et al.  A quantitative analysis of isotope concentration profiles and rapid transport velocities in the C-fibers of the garfish olfactory nerve. , 1975, Journal of neurobiology.

[8]  I Kupfermann,et al.  Behavior patterns of Aplysia californica in its natural environment. , 1974, Behavioral biology.

[9]  J. H. Schwartz,et al.  Cellular specificity of serotonin storage and axonal transport in identified neurones of Aplysia californica , 1974, The Journal of physiology.

[10]  J. H. Schwartz,et al.  AXONAL TRANSPORT OF NEWLY SYNTHESIZED GLYCOPROTEINS IN A SINGLE IDENTIFIED NEURON OF APLYSIA CALIFORNICA , 1974, The Journal of cell biology.

[11]  E. Kandel,et al.  Intrasomatic injection of radioactive precursors for studying transmitter synthesis in identified neurons of Aplysia californica. , 1973, Proceedings of the National Academy of Sciences of the United States of America.

[12]  A. Edström,et al.  Temperature effects on fast axonal transport of proteins in vitro in frog sciatic nerves. , 1973, Brain research.

[13]  G. Gross,et al.  The effect of temperature on the rapid axoplasmic transport in C-fibers. , 1973, Brain research.

[14]  J. E. Vaughn,et al.  CHEMICAL, ENZYMATIC AND ULTRASTRUCTURAL CHARACTERIZATION OF 5‐HYDROXYTRYPTAMINE‐CONTAINING NEURONS FROM THE GANGLIA OF APLYSIA CALIFORNICA AND TRITONIA DIOMEDIA , 1973, Journal of neurochemistry.

[15]  J. P. Heslop,et al.  TEMPERATURE AND INHIBITOR EFFECTS ON FAST AXONAL TRANSPORT IN A MOLLUSCAN NERVE , 1972, Journal of neurochemistry.

[16]  S Ochs,et al.  Fast transport of materials in mammalian nerve fibers. , 1972, Science.

[17]  J. H. Schwartz,et al.  Axonal transport of newly synthesized acetylcholine in an identified neuron of Aplysia. , 1972, Brain research.

[18]  E R Kandel,et al.  Functioning of identified neurons and synapses in abdominal ganglion of Aplysia in absence of protein synthesis. , 1971, Journal of neurophysiology.

[19]  F. O. Schmitt,et al.  Fibrous proteins--neuronal organelles. , 1968, Proceedings of the National Academy of Sciences of the United States of America.

[20]  J. H. Schwartz,et al.  Biosynthesis of the coat protein of coliphage f2 by E. coli extracts. , 1962, Proceedings of the National Academy of Sciences of the United States of America.

[21]  G. Gross The microstream concept of axoplasmic and dendritic transport. , 1975, Advances in neurology.

[22]  J. P. Heslop Axonal flow and fast transport in nerves. , 1975, Advances in comparative physiology and biochemistry.

[23]  R. Mccaman,et al.  Liquid cation exchange--a basis for sensitive radiometric assays for aromatic amino acid decarboxylases. , 1972, Analytical biochemistry.

[24]  H. Fernández,et al.  Studies on the mechanism of axoplasmic transport in the crayfish cord. , 1970, Journal of neurobiology.

[25]  S. Ochs,et al.  Characteristics of the fast transport system in mammalian nerve fibers. , 1969, Journal of neurobiology.