Action of brefeldin A on amphibian neurons: passage of newly synthesized proteins through the Golgi complex is not required for continued fast organelle transport in axons.

The relation between the availability of newly synthesized protein and lipid and the axonal transport of optically detectable organelles was examined in peripheral nerve preparations of amphibia (Rana catesbeiana and Xenopus laevis) in which intracellular traffic from the endoplasmic reticulum to the Golgi complex was inhibited with brefeldin A (BFA). Accumulation of fast-transported radio-labeled protein or phospholipid proximal to a sciatic nerve ligature was monitored in vitro in preparations of dorsal root ganglia and sciatic nerve. Organelle transport was examined by computer-enhanced video microscopy of single myelinated axons. BFA reduced the amount of radiolabeled protein and lipid entering the fast-transport system of the axon without affecting either the synthesis or the transport rate of these molecules. The time course of the effect of BFA on axonal transport is consistent with an action at an early step in the intrasomal pathway, and with its action being related to the observed rapid (< 1 h) disassembly of the Golgi complex. At a concentration of BFA that reduced fast-transported protein by > 95%, no effect was observed on the flux or velocity of anterograde or retrograde organelle transport in axons for at least 20 h. Bidirectional axonal transport of organelles was similarly unaffected following suppression of protein synthesis by > 99%. The findings suggest that the anterograde flux of transport organelles is not critically dependent on a supply of newly synthesized membrane precursors. The possibilities are considered that anterograde organelles normally arise from membrane components supplied from a post-Golgi storage pool, as well as from recycled retrograde organelles.

Does nerve impulse activity modulate fast axonal transport?

The possibility that the amount of newly synthesized material made available for fast axonal transport is regulated by nerve impulse activity was examined in an in vitro preparation of bullfrog dorsal root ganglia (DRG) and sciatic nerve. Under conditions that precluded effects of impulse activity on either uptake or incorporation of precursor, patterned stimulation of the sciatic nerve (1 out of every 2 s) produced a frequency- and time-dependent decrease in the amount of radiolabeled protein accumulating at a nerve ligature. The response to patterned stimulation was significantly greater than that to continuous stimulation when the same number of stimuli were delivered. In unligated nerve preparations, patterned stimulation decreased the amplitude of the transport profile with no concomitant change in the wave front distance. Nerve stimulation produced no observable ultrastructural alterations within neuronal cell bodies of the DRG. We propose that the physiological significance of these results is not that nerve impulse activity decreases fast axonal transport, but that the amount of transport increases during periods of electrical quiescence. According to this hypothesis, activity-dependent macromolecules of the axolemma and nerve terminals are replenished during periods when the neuron is firing less frequently. These findings are discussed in light of reports that chronic in vivo stimulation increases the amount of fast-transported, radiolabeled protein (Chan et al., 1989) and that TTX-blockade of neuronal activity has no effect on protein transport (Edwards and Grafstein, 1984; Riccio and Matthews, 1985).

Complex compartmentation of tyrosine sulfate-containing proteins undergoing fast axonal transport.

The compartmentation of fast-transported proteins that possess sulfated tyrosine residues--sulfoproteins--has been examined for further resolution of the possible significance of sulfated tyrosine in routing and delivery of fast-transported proteins. In vitro fast axonal transport of [35S]methionine- or 35SO4-labeled proteins was measured in dorsal root ganglion neurons for analysis of protein compartmentation en route and in synaptic regions. When membrane fractions were exposed to Na2CO3 for separation of "lumenal" and peripheral membrane proteins from integral components of the membrane, approximately 20% of the [35S]methionine incorporated into fast-transported proteins was present in a carbonate-releasable form in the axon, whereas 53% of the incorporated 35SO4 was released by carbonate. Eighty percent of the 35SO4 in this releasable fraction was acid labile, typical of sulfate ester-linked to tyrosine. Sulfoproteins were also detected in synaptosomes and were released into the extracellular medium in a calcium-dependent fashion, an observation suggesting that fast-transported sulfoproteins are secreted. Of the remaining 47% of the fast-transported 35SO4-labeled proteins resistant to carbonate treatment (the integral membrane protein fraction), nearly 60% of the 35SO4 was acid labile. Other membrane stripping agents, such as 0.1 M NaOH, 0.5 M NaCl, or mild trypsin treatment, failed to remove acid-labile 35SO4-labeled species from carbonate-treated membrane. Quantitative comparisons of several of the most abundant sulfoproteins resolved via two-dimensional gel electrophoresis confirmed that approximately 7% of each of the species remained associated with carbonate-treated membranes, presumably as integral membrane components.(ABSTRACT TRUNCATED AT 250 WORDS)

Fast axonal transport of tyrosine sulfate-containing proteins: preferential routing of sulfoproteins toward nerve terminals.

The presence of a subset of fast-transported proteins containing sulfate while lacking carbohydrate residues [Stone et al. (1983). J. Neurochem. 41:1085-1089] was confirmed by two-dimensional gel electrophoretic analysis of individual fast-transported proteins double-labeled with 35SO4 and [3H]mannose. Analysis by high-pressure liquid chromatography revealed that the sulfate moieties of these "sulfoproteins" are linked to tyrosine residues. Separation of fast-transported 35SO4-labeled proteins delivered to local regions of axon from proteins en route toward terminal regions demonstrated, on the basis of acid lability of tyrosine-bound sulfate, that the sulfoproteins were localized preferentially in the wavefront of fast-transported proteins. Analysis of individual sulfoproteins confirmed differential transport in that sulfoproteins were present at threefold greater amount in the wavefront than in material off-loaded to local regions of the axon. By contrast, nonsulfated species of molecular weights similar to those of the sulfoproteins were detected in nearly equal amounts in both regions of the transport profile. Treatment of nerve segments containing total 35SO4-labeled fast-transported proteins with sodium carbonate led to solubilization of half the protein-bound sulfate. Exposure of the solubilized proteins to mild acid resulted in the release of approximately 80% of the 35SO4 associated with this fraction. Two-dimensional gel patterns displaying carbonate releasable or nonreleasable fractions are consistent with the most abundantly labeled sulfoproteins being transported within membrane-bound organelles. In terms of apparent destination and subcellular compartmentalization, the sulfoproteins meet critical requirements for consideration as secretable fast-transported proteins.

Involvement of coated vesicles in the initiation of fast axonal transport.

The present study examines whether coated vesicles play a role in the intrasomal transit of newly synthesized fast-transported proteins. Coated vesicles isolated from bullfrog brain were shown to have a protein composition and ultrastructure similar to purified bovine brain coated vesicles. Bullfrog brain was then used as unlabeled carrier for the isolation of coated vesicles from dorsal root ganglia labeled with [3H]leucine. Fast-transported [35S]methionine-labeled proteins were generated in separate preparations from sciatic nerve, and co-electrophoresed on two-dimensional gels with [3H]proteins of the coated vesicle fraction. The [35S]Met fluorographic X-ray film pattern was used as a guide to remove gel regions which were tested for the presence of 3H. By this means, 45 of 67 individual fast-transported proteins examined were found to contain significant levels of 3H. The fact that these proteins have similar net charge and molecular weight characteristics to the mature fast-transported proteins with which they co-migrated, suggests that such species have already undergone post-translational modifications prior to becoming associated with coated vesicles. Since most modifications of this type occur in the Golgi apparatus, it appears that the majority of fast-transported proteins are isolated in association with a population of post-Golgi coated vesicles. The role of coated vesicles is incorporated into a model describing the pathway taken by fast-transported proteins during the initiation of fast axonal transport.

Fast-transported glycoproteins and nonglycosylated proteins contain sulfate.

35SO4-labeled fast-transported proteins of bullfrog dorsal root ganglion neurons were separated by two-dimensional gel electrophoresis, and their mobilities were compared to similar species labeled with [3H]mannose or [3H]fucose. Fluorography revealed regions of poorly resolved, high molecular weight material, likely to represent sulfated proteoglycans, as well as many well resolved spots that corresponded in mobility to individual [35S]methionine-labeled fast-transported proteins. The majority of these well resolved spots appeared as "families," previously identified as glycoproteins based on their labeling with sugars. Thus, sulfate can be a contributor to the carbohydrate side-chain charge that underlies microheterogeneity. The most heavily 35SO4-labeled species, however, corresponded to fast-transported proteins that were not labeled by either sugar. The relative acid labilities of 35SO4 associated with individual species cut from the gel confirmed the assignments of these spots as glycoproteins or nonglycoproteins. A group of spots intermediate in their acid lability was also detected, suggesting that some proteins may contain sulfate linked to carbohydrate as well as to amino acid residues.

Ca2+- or Mg2+-stimulated ATPase activity in bullfrog spinal nerve: relation to Ca2+ requirements for fast axonal transport.

Adenosine triphosphatase (ATPase) activity stimulated by Ca2+ or Mg2+ was characterized in spinal nerve and spinal sensory ganglion of bullfrog. Enzyme activity of homogenates from both sources reached a maximum at a 1-2 mM concentration of either cation, although the level of maximal activity in nerve trunks was approximately twice that in ganglia. Enzyme activation was not observed with 2 mM-Sr2+ or Ba2+. Co2+ or Mn2+, at 2 mM, depressed Ca2+ activation of the enzyme by 50-60% in nerve but had no inhibitory effect on ganglia activity. In intact spinal ganglion/spinal nerve preparations, incubated for 20 h in medium containing 0.2 mM-Co2+, no effect was detected on Ca2+/Mg2+ ATPase activity in ganglia or nerve trunks whereas fast axonal transport was inhibited by 80%. Incubation in medium containing 0.02 mM-Hg2+ depressed enzyme activity in ganglia by 64% and in nerve trunks by 44%, whereas fast transport was again inhibited by 80%. When only nerve trunks were exposed to these ions, Hg2+ but not Co2+ was observed to slow the rate of fast axonal transport. The divalent cation specificity of the Ca2+/Mg2+ ATPase activity is distinct from the ion specificities, determined in previous work, of the Ca2+ requirement during initiation of fast axonal transport in the soma, and of the Ca2+ requirement during translocation in the axon. Thus, previous observations of Ca2+-dependent events in fast axonal transport cannot be taken per se to suggest the involvement of Ca2+/Mg+ ATPase in the transport process.