Bidirectional axonal transport of 16S acetylcholinesterase in rat sciatic nerve

Axonal transport of the 16S Molecular form of acetylcholinesterase (16S-AChE) in doubly ligated rat sciatic nerves was studied by means of velocity sedimentation analysis on sucrose gradients. This form of AChE was selectively confined to motor, and not to sensory, fibers in the sciatic nerve, where it represented 3--4% of total AChE. Its activity increased linearly with time (4--20 hr) in nerve segments (7 mm) proximal to the central ligature (4.5 mU/24hr) and distal to the peripheral ligature (2.0 mU/24 hr). From the linear rates of accumulation of 16S-AChE, we conclude that the enzyme is conveyed by anterograde and retrograde axonal transport at velocities close to those previously defined for the movement of total AChE (410 mm/day, anterograde; 220 mm/day, retrograde). The transport of AChE molecular forms, other than the 16S form, could not be resolved presumably due to their presence in blood as well as at extraaxonal sites. The present findings are consistent with the view that in rat sciatic nerve most, if not all, of the small portion of total AChE (approximately 3%) which is transported may be accounted for by 16S-AChE.     

Acetylcholinesterase Molecular Forms in Chick Ciliary Ganglion: Pre- and Postsynaptic Distribution Derived from Denervation, Axotomy, and Double Section

Abstract: Four main molecular forms of acetylcholinesterase (AChE) characterized by their sedimentation coefficients (5S, 7.5S, 11.5S, and 20S), are found in chick ciliary ganglion. After transection of the preganglionic nerve (denervation), total AChE activity in the ganglion dropped by 35% in 2 days. By then, 11.5s and 20s forms had diminished by 60 and 75% respectively, where as 7.5s remained practically unchanged. Since presynaptic structures disappeared 2 days after denervation, we inferred that at most 35% of total ganglion AChE was presynaptic: 11.5s and 20s might be mainly presynaptic and 7.5S, postsynaptic. At later time intervals. total AChE continued to decline up to day 5, possibly as a result of orthograde transynaptic regulation of the enzyme activity. After transection of postganglionic nerves (axotomy), total ganglion activity showed little change; 11.5s and 20s decreased by 40 and 6076, respectively, in 5 days, but these drops were compensated for by an early increase in 7 5S, which started the day after axotomy. After simultaneous transection of both pre- and postganglionic nerves (double section), total ganglion AChE dropped rapidly by 35% in 1 day and remained at that level up to 21 days. The 11.5S diminished rapidly by 60% in 1 day. The early increase of the 7.5s form induced by axotomy alone did not occur. Since the effect resulting from double section was not the equivalent of the cumulative effects observed after denervation and axotomy, respectively, the level of AChE forms in the ganglion may be regulated by reciprocal interaction of pre- and postsynaptic elements. After denervation and double section but not after axotomy alone, the contralateral non-operated ganglion exhibited a fall in the 20s form. This suggests that a transynaptic effect is exerted on AChE by the contralateral preganglionic neuron. Taken together, these results indicate that the various AChE molecular forms in chick ciliary ganglion are preferentially but not exclusively distributed as follows: the pre- and postganglionic axons contain mainly the 11.5S form, whereas nerve endings and synaptic structures are enriched in 20S, and ganglion cell bodies, in 7.5s.     

FAST AXOPLASMIC TRANSPORT OF ACETYLCHOLINESTERASE IN MAMMALIAN NERVE FIBRES

Abstract— Acetylcholinesterase (acetylcholine acetyl-hydrolase, EC 3.1.1.7) is carried down mammalian nerve fibres by the fast axoplasmic transport system. This conclusion was derived from experiments involving the ligation of cat sciatic nerves at two sites placed 83.5 mm apart. The enzyme accumulated in segments of nerve proximal to the upper ligation in a linear fashion over a period of at least 20 h. At approximately 5 h the accumulation of enzyme ceased in the nerve segment proximal to the distal ligation within the isolated length of nerve, an observation indicating that the portion of AChE free to move within the isolated nerve had been depleted during this period of time. The freely moving fraction of AChE was estimated to be 15% of the total enzyme activity present in the nerve (10% in the proximo-distal direction and 5% in the retrograde direction). The rate of AChE downflow (as estimated from the intercept of the curve plotting accumulation with the line denoting when depletion started) was 431 mm/day within a 95% confidence interval of 357–543 mm/day. In view of the variability, our results demonstrated that AChE was being carried by the fast axoplasmic transport system, which in earlier studies was estimated to have a characteristic rate close to 410 mm/day.
An accumulation of AChE was also found on the distal side of the ligations that represented a movement of AChE in the distal-proximal direction in the fibres. This retrograde transport was smaller in amount (about one-half) than the proximo-distal rate of transport, or close to 220 mm/day. The rate of AChE transport was discussed in relation to the 'transport filament' hypothesis of fast axoplasmic transport.     

The kinematics of turnaround and retrograde axonal transport

Rapid axonal transport of a pulse of 35S-methionine-labelled material was studied in vitro in the sensory neurons of amphibian sciatic nerve using a position-sensitive detector. For 10 nerves studied at 23.0 +/- 0.2 degrees C it was found that a pulse moved in the anterograde direction characterized by front edge, peak, and trailing edge transport rates of (mm/d) 180.8 +/- 2.2 (+/- SEM), 176.6 +/- 2.3, and 153.7 +/- 3.0, respectively. Following its arrival at a distal ligature, a smaller pulse was observed to move in the retrograde direction characterized by front edge and peak transport rates of 158.0 +/- 7.3 and 110.3 +/- 3.5, respectively, indicating that retrograde transport proceeds at a rate of 0.88 +/- 0.04 that of anterograde. The retrograde pulse was observed to disperse at a rate greater than the anterograde. Reversal of radiolabel at the distal ligature began 1.49 +/- 0.15 h following arrival of the first radiolabel. Considerable variation was seen between preparations in the way radiolabel accumulated in the end (ligature) regions of the nerve. Although a retrograde pulse was seen in all preparations, in 7 of 10 preparations there was no evidence of this pulse accumulating within less than 2-3 mm of a proximal ligature; however, accumulation was observed within less than 5 mm in all preparations.     

Axonal Transport Reversal of Acetylcholinesterase Molecular Forms in Transected Nerve

Reversal of anterograde rapid axonal transport of four molecular forms of acetylcholinesterase (AChE) was studied in chick sciatic nerve during the 24-h period following a nerve transection. Reversal of AChE activity started ～1 h after nerve transection, and all the forms of the enzyme, except the monomeric ones, showed reversal of transport. The quantity of enzyme activity reversed 24 h after transection was twofold greater than that normally conveyed by retrograde transport. We observed no leakage of the enzyme at the site of the nerve transection and no reversal of AChE activity transport in the distal segment of the severed nerve, a result indicating that the material carried by retrograde axonal transport cannot be reversed by axotomy. Thus, a nerve transection induces both quantitative and qualitative changes in the retrograde axonal transport, which could serve as a signal of distal injury to the cell body. The velocity of reverse transport, measured within 6 h after transection, was found to be 213 mm/day, a value close to that of retrograde transport (200 mm/day). This suggests that the reversal taking place in severed sciatic nerve is similar to the anterograde-to-retrograde conversion process normally occurring at the nerve endings.     

Loss of material from the retrograde axonal transport system in frog sciatic nerve

Rapid axonal transport was studied in sciatic nerve preparations of the amphibian Xenopus laevis maintained in vitro at 23.0 +/- 0.2 degrees C. A pulse of [35S]methionine-labeled material was allowed to move in the anterograde direction until encountering a lesion, at which a portion of the pulse reversed directions and moved in the retrograde direction. By constricting the nerve during the course of the experiment, it was possible to prevent continuous return of label from the lesion, thus creating a retrogradely moving pulse that contained a defined quantity of radiolabel. Movement of both the anterograde and the retrograde pulse were monitored continuously for up to 24 h using a position-sensitive detector of ionizing radiation. The front and the back edge of the anterograde pulse were found to move at the rates of (mm/day) 179.9 +/- 3.9 (+/- SEM) and 149.9 +/- 5.9, respectively, and the front and the back edge of the retrograde pulse moved at the rates of 155.8 +/- 11.3 and 84.6 +/- 2.9, respectively. By comparison of the quantity of label lost to the stationary phase to the quantity of label calculated to have been present in the anterograde pulse, it was determined that 0.068 +/- 0.009 of the anterograde pulse is lost to each 3.18-mm region of nerve. Comparison of the quantity of label calculated to have been present in the retrograde pulse to that in the anterograde pulse revealed that 0.057 +/- 0.014 of the retrograde pulse is lost to each 3.18-mm region of nerve. It is concluded that protein originating in the cell body and which reverses its direction of transport at a lesion can be lost from the retrograde axonal transport system.     

Retrograde Effect of Muscle on Forms of Acetylcholinesterase in Peripheral Nerves

In the peripheral nerves of birds and mammals, acetylcholinesterase (AChE) exists in four main molecular forms (G1, G2, G4, and A12). The two heaviest forms (G4 and A12) are carried by rapid axoplasmic transport, whereas the two lightest forms (G1 and G2) are probably much more slowly transported. Here we report that nerves innervating fast-twitch (F nerves) and slow-twitch (S nerves) muscles of the rabbit differ both in their AChE molecular form patterns and in their anterograde and retrograde axonal transport parameters. Since we had previously shown a selective regulation of this enzyme in fast and slow parts of rabbit semimembranosus muscle, we wondered whether the differences observed in the nerve could be affected by the twitch properties of muscle. The results reported here show that in F nerves that reinnervate slow-twitch muscles, both the AChE molecular form patterns and axonal transport parameters turn into those of the S nerve. These data suggest the existence of a retrograde specific effect exerted by the muscles on their respective motoneurons.     

AXONAL TRANSPORT OF SELECTED PARTICLE-SPECIFIC ENZYMES IN RAT SCIATIC NERVE IN VIVO AND ITS RESPONSE TO INJURY

Abstract— Orthograde and retrograde axoplasmic transport of selected axonal organelles were examined by monitoring accumulation of enzyme activities residing in various types of particles proximal and distal to a ligature placed on rat sciatic nerve as a function of time after tying. Proximal to the tie, activity of acetylcholinesterase (AChE, EC 3.1.1.7; probably in small endoplasmic reticulum-like particles) accumulated for 2 days; then, during the next 5 days, the accumulation disappeared. Activities of glutamic dehydrogenase (GDH, EC 1.4.1.3) and monoamine oxidase (MAO, EC 1.4.3.4) (both located in mitochondria) accumulated steadily for 7 days. Accumulation of monoamine oxidase activity was more rapid than that of glutamic dehydrogenase during the first day or two. Acid phosphatase (acid P'tase, EC 3.1.3.2; in lysosomes) activity also accumulated throughout the week of observation. Accumulation of all four enzyme activities proximal to the ligature was blocked by nerve crush or subepineurial vinblastine injection 1 cm or more proximal to the site of the tie. Distal to the ligature, AChE activity accumulated early (14 h), and then gradually disappeared in the course of the week. MAO activity also accumulated, with a maximum at 2 days, and no further change thereafter. GDH activity, on the other hand, showed little accumulation during the first 2 days, but did appear in modest amounts at the end of the week. Distal accumulation of acid P'tase kept pace with proximal accumulation for the first day, and continued more slowly for another day, after which there was no further change. This system has been used to study the effects of axonal crush injury upon anterograde and retrograde axoplasmic transport. A tie applied at various times after injury, proximal to the site of injury, was used to show that orthograde transport of AChE was maintained for 1 day after tying, but at 2 days had fallen 50% or more, and within a week was down to 20–25% of control. At 3 days after injury retrograde transport of AChE activity was not different from the control. Orthograde transport of acid P'tase activity was depressed 35% by injury. Retrograde transport of acid P'tase was inhibited more than 50% both at 3 and at 7 days after injury. Transport of the mitochondrial enzymes was not measurably affected.     

Reversal of Axonal Transport: Similarity of Proteins Transported in Anterograde and Retrograde Directions

Reversal of axonal transport of endogenous labeled protein was studied in intact and injured nerve axons. Nerve crushes were used to collect labeled protein transported in anterograde and retrograde directions in rat sciatic nerve motoneuron axons after administration of L-[35S]methionine to the vicinity of the cell bodies. The collected proteins were characterized by sodium dodecyl sulfate polyacrylamide gel electrophoresis and subsequent fluorography. In injured nerves, where the nerves were ligated distally at the time of precursor injection, the polypeptide composition of proteins moving in anterograde and retrograde directions, 9-11 h after precursor injection, was identical, indicating that reversal at a ligature is a nonselective process. In intact nerves, protein moving in the anterograde direction 22-24 h after injection was different from that found 9-11 h after injection, and was also different from protein moving in the retrograde direction 22-24 h after injection. However, protein moving in the retrograde direction 22-24 h after injection was similar to protein moving in the anterograde direction 9-11 h after injection. Thus it appears that the same group of proteins originally transported into the axon are later returned toward the cell body. In intact axons, also, reversal was nonselective, except that one major labeled polypeptide was reduced in amount in the protein moving in the retrograde direction.     

Turnover of the Molecular Forms of Acetylcholinesterase in the Rat Diaphragm

Abstract: The turnover of acetylcholinesterase (AChE) and its molecular forms was measured by following the loss of enzyme activity in the right hemidiaphragms of Sprague-Dawley rats treated with cycloheximide, 20 mg/kg, every 4 h. This treatment inhibited 96% of the incorporation of [³H]leucine into muscle protein. After 8 h of treatment, the total AChE activity of the diaphragm decreased by 17% ( P < 0.01). Assuming first-order exponential kinetics, a half-life of 30 h and an hourly turnover of 180 units were calculated. The measured accumulation of AChE activity at a ligature on the phrenic nerve indicated that axonal transport contributed trivially to this turnover. Sucrose density gradient experiments showed that the cycloheximide-induced loss of AChE activity was restricted to the 4S enzyme, which had an apparent half-life of 6.2 h.     

STUDIES ON AXOPLASMIC TRANSPORT OF INDIVIDUAL PROTEINS: 1–ACETYLCHOLINESTERASE (AChE) IN ACRYLAMIDE NEUROPATHY

Abstract— The axoplasmic transport rate and distribution of acetylcholinesterase (AChe, EC 3.1.1.7) was studied in the sciatic nerves of normal rats and those with a neuropathy due to acrylamide, by measuring the accumulation of the enzyme proximal to single and double ligatures. The single ligature experiments showed that the apparent transport rate of AChE was decreased in acrylamide neuropathy. The double ligature experiments indicated that only 8.1% of AChE was mobile in normal rat sciatic nerve. The mobility of the enzyme in acrylamide-treated rat sciatic nerves was altered to 11.8%. The absolute transport rate of AChE in normal rat sciatic nerve was 567 mm/24 h, and in acrylamide neuropathy it was decreased to 287 mm/24 h.
The amount of AChE activity transported in normal rat sciatic nerve was 2.64 μmol/24 h. The rats with acrylamide neuropathy showed a decrease in the amount of AChE activity moving in the orthograde direction (2.03 μmol/24 h).
The colchicine-binding properties of tubulin protein from sciatic nerves of normal and acrylamide-treated rats were studied. In rats with acrylamide neuropathy, a marked decrease of 75% in tubulin-colchicine binding was observed.     

Neurotrophic control of 16S acetylcholinesterase at the vertebrate neuromuscular junction

Endplate 16S acetylcholinesterase (16S-AChE) from rat anterior gracilis muscle was assessed, 6 hr to 10 days after denervation, by velocity sedimentation analysis on linear sucrose gradients. The innervating obturator nerve was transected either close (1-2 mm, short stump) or far (35-40 mm, long stump) from the muscle. In both instances, the activity of 16S-AChE gradually decreased and reached approximately the same level (10%-20% of control) by 6 days after denervation. However, enzymatic decay started considerably earlier in short stump (12-24 hr) as compared to long stump (4-5 days) preparations, i.e., the time of onset of 16S-AChE loss depended on the length of nerve that remained attached to the muscle. Whether this result extended to other AChE molecular forms (10S, 4S) in muscle endplates could not be determined because, in contrast to 16S-AChE, these forms were also detected in red blood cells (4S) and plasma (10S). Only small amounts of 16S-AChE were found in intact obturator nerves (1/100 of that in gracilis endplate regions). Thus a faster depletion of enzyme from shorter nerve stumps after axotomy could not entirely account for the substantial effect of nerve stump length on 16S-AChE. Since muscle contraction ceases immediately following nerve transection, regardless of nerve stump length, the results can be ascribed to the lack of some neural influence other than nerve-evoked muscle activity. The present findings are consistent with the view that maintenance of 16S-AChE at neuromuscular junctions primarily depends on regulatory substances which are conveyed by axonal transport and released from nerve terminals.     

Axoplasmic Transport and Turnaround of Neurotoxic Esterase in Hen Sciatic Nerve

We have recently found that there is a proximo-distal delay in the recovery of neurotoxic esterase (NTE) following inhibition along the sciatic nerve of the hen. To determine whether this delay could be due to a requirement for the transport of newly synthesized NTE from the cell body, we investigated the transport of NTE by measuring the rate of accumulation of activity at either one or two ligations. Although rapid turnaround of accumulated protein confounds calculation of the transport rate, it appeared that NTE is transported down the hen sciatic nerve at a rate close to 300 mm/day. Acetylcholinesterase (AChE) was found to be transported at a rate of about 500 mm/day, which is close to the expected rate of fast axoplasmic transport in the chicken. The relatively rapid turnaround of NTE compared with the retrograde transport rate precluded the estimation of a retrograde transport rate. A model is presented that accounts for turnaround as a result of exchange between mobile and stationary transport pools. Exchange of NTE between pools may account for the rapid turnaround of NTE described in this paper and for the proximo-distal delay in recovery as a dilution of newly synthesized NTE in the anterograde fast transport pool by inhibited protein as it travels down the nerve.     

Axonal transport of proteins. A new view using in vivo covalent labeling

The injection of [2,3-3H]N-succinimidyl propionate ([3H]N-SP) into the rat sciatic nerve was used to covalently label both intra- and extra- axonal proteins. While extra-axonal proteins (e.g., myelin proteins) remained in the injection site, the intra-axonal proteins were transported in both the anterograde and retrograde directions. The mobile labeled proteins appeared to move by normal axonal transport processes because: (a) autoradiographic studies showed that they were localized exclusively within the axon at considerable distances from the injection site, (b) specific and identifiable proteins (by SDS gel electrophoresis) moved at expected rates in the anterograde direction, and (c) an entirely different profile of proteins moved in the anterograde vs. retrograde direction. This novel experimental approach to axonal transport, which is independent of de novo protein synthesis, provided a unique view of slow anterograde transport, and particularly of retrograde transport of endogenous proteins. A large quantity of a 68,000 mol wt proteins, moving at approximately 3-6 mm/day, dominated the retograde transport profile. [3H]N-SP, therefore, represents a new and unique "vital stain" which may find many applications in cell biology.     

TRANSPORT, TURNOVER AND DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE AND ACETYLCHOLIN-ESTERASE IN THE VAGUS AND HYPOGLOSSAL NERVES OF THE RABBIT

Abstract— The transport, distribution and turnover of choline O -acetyltransferase (ChAc, EC 2.3.1.6) and acetylcholinesterase (AChE, EC 3.1.1.7) in the vagus and hypoglossal nerves were studied in adult rabbits. The enzymes accumulated proximally and distally to single and double ligatures on both nerves and thus indicated both a proximo-distal and retrograde flow of the enzymes. Double ligature experiments indicated that only 5–20 per cent of the enzymes were mobile in the axon. The rate of accumulation of both enzymes above a single ligature corresponded to the slow rate of axonal flow provided that all the enzymes were mobile, but to an intermediate or fast flow if only a small part of the enzymes was transported. The distribution of ChAc along the hypoglossal neurons was studied and only 2 per cent of ChAc was confined to cell bodies, 42 per cent was localized to the main hypoglossal nerve trunks and 56 per cent to the preterminal axons and axon terminals in the tongue. The ratio of AChE to ChAc was about 3 in the hypoglossal nerve and 32 in the vagus nerve.
Transection of the hypoglossal nerve was followed by a decrease in the activity of ChAc in the hypoglossal nucleus and nerve and in the axons and their terminals in the tongue. The activity of AChE decreased in the hypoglossal nucleus and nerve but not in the tongue. The half-life of ChAc in preterminal axons and terminals of the hypoglossal nerve was estimated to be 16-21 days from the results obtained on transport, axotomy and distribution of the enzyme. Intracisternal injection of colchicine inhibited the cellulifugal transport of both enzymes and led to an increase in enzyme activity in the hypoglossal nucleus.     

Retrograde Axonal Transport of Gangliosides and Glycoproteins in the Motoneurons of Rat Sciatic Nerve

Axonal transport of glycoconjugates was studied in the motoneurons of rat sciatic nerve following injection of [3H]glucosamine into the lumbosacral spinal cord. After varying time intervals, the sciatic nerve was exposed, and two ligatures were tied for collection of materials undergoing anterograde and retrograde transport. Gangliosides and glycoproteins were found to undergo fast anterograde transport, estimated at 284-446 mm/day. Both classes underwent retrograde transport as well, with labeled glycoproteins returning slightly ahead of labeled gangliosides. Only minor quantities of labeled proteoglycans were detected. Purified gangliosides extracted from nerve segments were fractionated according to sialic acid number on diethylaminoethyl-Sephadex; the distributional pattern tended to resemble that of brain gangliosides. The similarity between anterograde and retrograde patterns suggested absence of metabolic changes in gangliosides entering and leaving the axon-nerve terminal structures.     

Atypical Distribution of Asymmetric Acetylcholinesterase in Mutant PC12 Pheochromocytoma Cells Lacking a Cell Surface Heparan Sulfate Proteoglycan

We studied the distribution of the molecular forms of acetylcholinesterase (AChE) in a stable variant (F3) of the rat pheochromocytoma cell line, PC12, that lacks a heparan sulfate proteoglycan on the cell surface. After treatment with nerve growth factor F3 cells synthesize less 4S enzyme, and more 10S and 16S enzyme than normal PC12 cells. This distribution is similar to that seen in normal cells after incubation with beta-D-xylosides, molecules that interfere with proteoglycan assembly. Using collagenase treatment and membrane-permeable and -impermeable inhibitors of AChE, we determined the cellular location of the AChE forms. Although in normal cells greater than 90% of the 16S AChE is on the cell surface, approximately 60% is present in an internal pool in the variant. Following irreversible inhibition of all forms of AChE in the variant, the newly synthesized 16S AChE appears in the internal pool after a 1-h lag, but is not detected on the cell surface until after 2.5 h. Our results thus show that 16S AChE is assembled internally within neuronal cells and that alterations in the synthesis and distribution of proteoglycans affect the total amount and cellular localization of the 16S AChE form.     

Difference in the ability of neonatal and adult denervated muscle to accumulate acetylcholinesterase at the old sites of innervation

In adult rat sternocleidomastoid muscle, AChE is concentrated in the region rich in motor end-plates (MEP). All major AChE forms, "16 S," "10 S," and "4 S," are accumulated at high levels, and not only "16 S" AChE. After denervation, muscle AChE decreases; 2 weeks after denervation, low levels (20-40% of control) are reached for all forms. During the following weeks, a slow but steady increase in "10 S" and "16 S" AChE occurs in the denervated muscle. At this stage, all forms are again observed to be highly concentrated in the region containing the old sites of innervation. Thus, in adult rat muscle the structures able to accumulate "16 S," "10 S," and "4 S" AChE in the MEP-rich regions remain several months after denervation. In normal young rat sternocleidomastoid muscle at birth, all AChE forms are already accumulated in the MEP-rich region. After denervation at birth, the denervated muscle loses its ability to keep a high concentration of "4 S," "10 S," and "16 S" AChE in the old MEP-rich region. All AChE forms are still present 1 month after denervation, but they are decreased and diffusedly distributed over the whole length of the muscle. In particular, "16 S" AChE is detected in the same proportion (10-15%) all along the denervated muscle. Thus, the diffuse distribution of AChE, and especially "16 S" AChE, after neonatal denervation, contrasts with the maintained accumulation observed in adult denervated muscle. It seems that denervation of young muscle results in a specific loss of the muscle ability to concentrate high levels of all AChE forms at the old sites of innervation.     

Nucleotide specificity for the bidirectional transport of membrane-bounded organelles in isolated axoplasm.

Video microscopy of isolated axoplasm from the squid giant axon permits correlated quantitative analyses of membrane-bounded organelle transport both in the intact axoplasm and along individual microtubules. As a result, the effects of experimental manipulations on both anterograde and retrograde movements of membrane-bounded organelles can be evaluated under nearly physiological conditions. Since anterograde and retrograde fast axonal transport are similar but distinct cellular processes, a systematic biochemical analysis is important for a further understanding of the molecular mechanisms for each. In this series of experiments, we employed isolated axoplasm of the squid to define the nucleoside triphosphate specificity for bidirectional organelle motility in the axon. Perfusion of axoplasm with 2-20 mM ATP preserved optimal vesicle velocities in both the anterograde and retrograde directions. Organelle velocities decreased to less than 50% of optimal values when the axoplasm was perfused with 10-20 mM UTP, GTP, ITP, or CTP with simultaneous depletion of endogenous ATP with hexokinase. Under the same conditions, TTP and ATP-gamma-S were unable to support significant levels of transport. None of the NTPs tested had a differential effect on anterograde vs. retrograde movement of vesicles. Surprisingly, several inconsistencies were revealed when a comparison was made between these results and nucleoside triphosphate specificities that have been reported for putative organelle motors by using in vitro assays. These data may be used in conjunction with data from well-defined in vitro assays to develop models for the molecular mechanisms of axonal transport.     

The molecular weights of two forms of carbamoyl phosphate synthase from rat liver

1. N-Acetylglutamate-dependent carbamoyl phosphate synthase from rat liver was centrifuged in sucrose density gradients. The concentration-dependence of s was consistent with a chemical equilibrium existing between the 11S and 7.5S forms of the enzyme. 2. Under conditions favouring the 11S form, the properties of the enzyme in ultra-short-column equilibrium experiments suggest a molecular weight of 316000+/-42000 for the 11S form. 3. Under conditions favouring the 7.5S form, high-speed equilibrium-sedimentation measurements gave a value of 160000+/-10000 as the molecular weight of the 7.5S form of the enzyme.