Slow axonal transport mechanisms move neurofilaments relentlessly in mouse optic axons

doi:10.1083/jcb.117.3.607

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Slow axonal transport mechanisms move neurofilaments relentlessly in mouse optic axons

RJ Lasek, P Paggi and MJ Katz
Bio-architectonics Center, School of Medicine, Case Western Reserve University, Cleveland, Ohio 44106.

Pulse-labeling studies of slow axonal transport in many kinds of axons (spinal motor, sensory ganglion, oculomotor, hypoglossal, and olfactory) have led to the inference that axonal transport mechanisms move neurofilaments (NFs) unidirectionally as a single continuous kinetic population with a diversity of individual transport rates. One study in mouse optic axons (Nixon, R. A., and K. B. Logvinenko. 1986. J. Cell Biol. 102:647-659) has given rise to the different suggestion that a significant and distinct population of NFs may be entirely stationary within axons. In mouse optic axons, there are relatively few NFs and the NF proteins are more lightly labeled than other slowly transported slow component b (SCb) proteins (which, however, move faster than the NFs); thus, in mouse optic axons, the radiolabel of some of these faster-moving SCb proteins may confuse NF protein analyses that use one dimensional (1-D) SDS-PAGE, which separates proteins by size only. To test this possibility, we used a 2-mm "window" (at 3-5 mm from the posterior of the eye) to compare NF kinetics obtained by 1-D SDS-PAGE and by the higher resolution two- dimensional (2-D) isoelectric focusing/SDS-PAGE, which separates proteins both by their net charge and by their size. We found that 1-D SDS-PAGE is insufficient for definitive NF kinetics in the mouse optic system. By contrast, 2-D SDS-PAGE provides essentially pure NF kinetics, and these indicate that in the NF-poor mouse optic axons, most NFs advance as they do in other, NF-rich axons. In mice, greater than 97% of the radiolabeled NFs were distributed in a unimodal wave that moved at a continuum of rates, between 3.0 and 0.3 mm/d, and less than 0.1% of the NF population traveled at the very slowest rates of less than 0.005 mm/d. These results are inconsistent with the proposal (Nixon and Logvinenko, 1986) that 32% of the transported NFs remain within optic axons in an entirely stationary state. As has been found in other axons, the axonal transport system of mouse optic axons moves NFs and other cytoskeletal elements relentlessly from the cell body to the axon tip.
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Ackerley, S., Grierson, A. J., Brownlees, J., Thornhill, P., Anderton, B. H., Leigh, P. N., Shaw, C. E., Miller, C. C.J. (2000). Glutamate Slows Axonal Transport of Neurofilaments in Transfected Neurons. JCB 150: 165-176 [Abstract] [Full Text]
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Koehnle, T. J., Brown, A. (1999). Slow Axonal Transport of Neurofilament Protein in Cultured Neurons. JCB 144: 447-458 [Abstract] [Full Text]
Yabe, J., Pimenta, A, Shea, T. (1999). Kinesin-mediated transport of neurofilament protein oligomers in growing axons. J. Cell Sci. 112: 3799-3814 [Abstract]
Williamson, T.L., Marszalek, J.R., Vechio, J.D., Bruijn, L.I., Lee, M.K., Xu, Z., Brown, R.H. Jr., Cleveland, D.W. (1996). Neurofilaments, Radial Growth of Axons, and Mechanisms of Motor Neuron Disease. Cold Spring Harb Symp Quant Biol 61: 709-723 [Abstract]
Hoffman, P. N. (1995). Review : The Synthesis, Axonal Transport, and Phosphorylation of Neurofilaments Determine Axonal Caliber in Myelinated Nerve Fibers. Neuroscientist 1: 76-83 [Abstract]
Roobol, A, Holmes, F., Hayes, N., Baines, A., Carden, M. (1995). Cytoplasmic chaperonin complexes enter neurites developing in vitro and differ in subunit composition within single cells. J. Cell Sci. 108: 1477-1488 [Abstract]