Investigations of slow axonal transport reveal variation in both protein composition and the rate of movement. However, these studies involve a variety of nerve preparations in different species, and most lack the resolution needed to determine the kinetics of identified proteins. We have compared the axonal transport of slow-transported proteins in retinal ganglion cells and spinal motor neurons of young rats. Nine proteins that contribute to axonal structures were examined: the neurofilament triplet (NFT), alpha and beta tubulin, actin, fodrin, calmodulin, and clathrin. Axonally transported proteins were pulse-labeled by intraocular or intracord injections of 35S-methionine. After allowing sufficient time for labeled slow-component proteins to enter the spinal or optic nerves, consecutive 2-3 mm nerve segments were subjected to SDS-PAGE. Fluorographs were used as templates for locating the gel regions containing the above polypeptides, and the radioactivity in these regions was measured by liquid-scintillation spectrometry. In retinal ganglion cells, the peak of tubulin labeling advanced at 0.36 mm/d in association with the NFT and fodrin. The cotransport of tubulin and the NFT identified this complex as the slower subcomponent of slow transport, termed slow component a (SCa) and representing the movement of the microtubule-neurofilament network. The peaks of actin and calmodulin labeling were cotransported at 2.3 mm/d in near-register with peaks of fodrin and clathrin labeling. These 4 proteins, moving ahead of the NFT, identified this complex as SCb--the faster subcomponent of slow transport, which represents the movement of the cytoplasmic matrix and microtrabecular lattice. Both subcomponents had the same composition and rate as that reported for the optic axons of guinea pigs and rabbits, establishing a basic mammalian pattern. In spinal motor axons, the SCa tubulin peak advanced at 1.3 mm/d, and the SCb actin and calmodulin peaks were cotransported at 3.1 mm/d. Unlike optic axons, SCa in motor axons was more heavily labeled than SCb, and included labeled peaks of actin, clathrin, and calmodulin moving in register with the SCa tubulin peak. Actin was the most heavily labeled of these SCb proteins moving with SCa, and it left a higher plateau of radioactivity behind the advancing SCa peak. The SDS-PAGE labeling pattern for SCb did not differ from that seen in optic axons, except that some tubulin was found to form a peak that advanced in register with the actin and calmodulin peaks.(ABSTRACT TRUNCATED AT 400 WORDS)
Many of the structural and functional differences between axons are thought to reflect underlying differences in the biochemical composition and dynamic aspects of the axonal cytoskeleton and cytomatrix. In this study we investigated how the composition of the 2 slow components of axonal transport, SCa and SCb, which convey the cytoskeleton and cytomatrix, differs in axons that are structurally and functionally distinct. For this comparison we analyzed axons of retinal ganglion cells in the optic nerve (ON), axons of dorsal root ganglion (DRG) cells, and axons of ventral motor neurons (VMN) in adult rats. 35S-Methionine-labeled proteins transported with the peak of SCa and SCb were analyzed using high-resolution 2-dimensional polyacrylamide gels (2D-PAGE) and fluorography, and the amounts of major SCa and SCb proteins were quantified. The polypeptide composition of both SCa and SCb was found to be largely similar in DRG and VMN axons, but major qualitative as well as quantitative differences between these axons and ON axons were found. Notable among these were higher ratios of neurofilament protein to tubulin in SCa in DRG and VMN axons compared to ON axons, and significantly larger amounts of 2 microtubule-associated proteins relative to tubulin in SCa of ON axons than in both VMN and DRG axons. Tubulin was the major SCb protein in VMN and DRG axons, but it was not present in SCb in ON axons. Additionally, relatively larger amounts of 2 metabolic enzymes, creatine phosphokinase and nerve-specific enolase, were present in SCb in ON axons than in DRG or VMN axons. The results indicate that significant biochemical heterogeneity among different types of axons can be identified by examining the slow components of axonal transport.
The thickness of the myelin sheath in normal myelinated nerve is proportional to the diameter of the axon. In the demyelinating mutant mouse, Trembler, not only is the thickness of the myelin sheath reduced, but the caliber of associated axons is smaller. This correlation suggests that the interaction between axons and Schwann cells may affect the shape and function of axons as well as properties of myelin.
Synapsin I, a neuron-specific, synaptic vesicle-associated phosphoprotein, is thought to play an important role in synaptic vesicle function. Recent microinjection studies have shown that synapsin I inhibits neurotransmitter release at the squid giant synapse and that the inhibitory effect is abolished by phosphorylation of the synapsin I molecule (Llinas et al., 1985). We have considered the possibility that synapsin I might modulate release by regulating the ability of synaptic vesicles to move to, or fuse with, the plasma membrane. Since it is not yet possible to examine these mechanisms in the intact nerve terminal, we have used video-enhanced microscopy to study synaptic vesicle mobility in axoplasm extruded from the squid giant axon. We report here that the dephosphorylated form of synapsin I inhibits organelle movement along microtubules within the interior of extruded axoplasm and that phosphorylation of synapsin I on sites 2 and 3 by calcium/calmodulin-dependent protein kinase II removes this inhibitory effect. Phosphorylation of synapsin I on site 1 by the catalytic subunit of cAMP-dependent protein kinase only partially reduces the inhibitory effect. In contrast to the inhibition of movement along microtubules seen within the interior of the axoplasm, movement along isolated microtubules protruding from the edges of the axoplasm is unaffected by dephospho-synapsin I, despite the fact that the synapsin I concentration is higher there. Thus, synapsin I does not appear to inhibit the fast axonal transport mechanism itself. Rather, these results are consistent with the possibility that dephospho-synapsin I acts by a crosslinking mechanism involving some component(s) of the cytoskeleton, such as F-actin, to create a dense network that restricts organelle movement. The relevance of the present observations to regulation of neurotransmitter release is discussed.
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