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.     

Cercal sensory regulation of acetylcholinesterase in nervous system of the cockroach, Periplaneta americana

Cercal ablation caused a significant loss in acetylcholinesterase (AChE) activity of the cercal nerves and terminal ganglion within 12 hr while a similar reduction in enzyme activity of connectives was noticed at least one day after cercectomy. The decrease in AChE activity of the nervous tissues showed a recovery toward control levels from 20 days of unilateral cercectomy whereas the bilateral cercectomy produced a continuous and irreversible decline in enzyme activity. These localized changes in AChE activity of the abdominal nervous system of the cockroach were attributed to be regulated by the cercal sensory innervation.     

Acetylcholinesterase Distribution in Axotomized Frog Motoneurons

Abstract: The distribution of acetylcholinesterase (AChE; EC 3.1.1.7) activity was examined in the perikarya and proximal axonal stumps of frog motoneurons injured by ventral root transection. Based upon measurements of net AChE accumulation in the proximal stumps of transected ventral roots, and upon orthograde clearances of AChE reported by others, it was determined that an amount of AChE equivalent to at least 0.7–2 times the perikaryal content of this enzyme enters the motor axon each day. A progressive decrease in the rate of AChE accumulation in transected axons during the first 3 days after ventral rhizotomy raised the possibility that excess enzyme might accumulate elsewhere within the axotomized motoneurons. However, AChE accumulation was detected only near the cut ends of the ventral roots and was not appreciably increased within injured motoneuronal cell bodies and proximal dendrites, which were isolated by a new method combining bulk and single-cell isolation techniques. These data suggest that AChE turnover is altered rapidly in response to axonal injury, thereby avoiding large perikaryal accumulations of this enzyme.     

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.     

The intra-axonal transport of acetylcholine and cholinergic enzymes in rat sciatic nerve during regeneration after various types of axonal trauma

The proximo-distal intra-axonal transport of acetylcholine (ACh) and cholinergic enzymes (choline acetyltransferase, CAT, and ACh-esterase, AChE) in rat regenerating sciatic nerve was studied by accumulation technique. Four types of axonal trauma were performed: freezing with solid CO₂, crushing, ligating the nerve with remaining tight silk ligature, and cutting the nerve. Normal and sham-operated rats were used as controls. One to twenty-nine days later, the nerves were crushed about 15 mm proximal to the trauma. The nerve segment proximal to this crush was dissected out 12 hr later and assayed for ACh-content and enzyme activities. The increase in this segment 12 hr after crushing was taken as an indication of proximo-distal transport in the regenerating nerves. ACh transport did not seem to vary during regeneration as compared to controls. In contrast, the transport of both CAT and AChE was initially markedly depressed. Towards the end of the observation period (29 days), a recovery of CAT-transport occurred in all groups. Recovery of AChE-transport was marked in the freeze and crush groups. In the cut group no recovery was seen and in the ligated group only a small recovery occurred. Thus, in the nerves where regeneration was facilitated by the presence of intact connective tissue sheaths (freezing and crushing) recovery of transport occurred earlier than in cut or ligated nerves.     

神经生长因子对兔坐骨神经损伤后脊髓前角运动神经元乙酰胆碱酯酶的影响

钳夹损伤兔右坐骨神经,于损伤处注射蛇毒ＮＧＦ４００Ｂｕ／ｋｇ／日,损伤术后１,３,７天和２,３,４,６,８周动态观察脊髓腰段伤侧第Ⅸ板层外侧群的大型运动神经元的ＡＣｈＥ活性改变。结果表明术后１,３天实验组（指损伤给药组）和对照组（指损伤对照组）ＡＣｈＥ活性均下降（Ｐ＞００５）;术后１,２,３周对照组ＡＣｈＥ活性明显下降,而实验组ＡＣｈＥ活性逐渐趋于恢复（Ｐ＜００１）;术后６周实验组ＡＣｈＥ活性恢复至正常水平（Ｐ＜００１）。本研究显示蛇毒ＮＧＦ对坐骨神经损伤后脊髓前角运动神经元ＡＣｈＥ活性恢复有促进作用,从而对运动神经元可起一定的保护作用和促进恢复的作用     

选择性切除交感神经对大鼠心内神经节中去甲肾上腺素、乙酰胆碱和NPY的影响

为了探讨心内神经节中去甲肾上腺素（ＮＡ）、乙酰胆碱（ＡＣｈ）和ＮＰＹ的相互作用,本实验应用６－ＯＨ－ＤＡ选择性切除大鼠心脏交感神经纤维,然后应用荧光和酶组织化学法、免疫组织化学结合图像分析法观察了大鼠心内神经节ＮＡ、ＡＣｈＥ活性和ＮＰＹ的变化。结果显示：实验组大鼠心内神经节中儿茶酚胺荧光反应阳性和ＮＰＹ免疫反应（ＮＰＹ－ＩＲ）阳性的神经纤维明显减少,ＡＣｈＥ阳性神经纤维明显增多,ＡＣｈＥ反应性神经元积分光密度增加,而儿茶酚胺荧光反应和ＮＰＹ－ＩＲ阳性神经元变化不明显。结果提示：１．交感神经化学切除后大鼠心内神经节中ＮＡ、ＡＣｈＥ活性和ＮＰＹ出现不同的变化,体现了心脏交感神经和副交感神经的相互抑制作用;２．心内神经节可能含有两种性质的ＮＰＹ,即交感性和非交感性ＮＰＹ。     

ON THE DEVELOPMENT OF SYMPATHETIC NERVE TRUNK VESICLES DURING AXONAL TRANSPORT: DENSITY GRADIENT ANALYSIS OF DOPAMINE β-HYDROXYLASE IN BOVINE SPLENIC NERVE

—Dopamine β-hydroxylase was used as a marker enzyme for sympathetic nerve vesicles which were studied by density gradient technique in bovine splenic nerves. The enzyme analyses were complicated by the occurrence of inhibitors which had to be carefully neutralized with copper. The inhibitor was mainly found in the soluble fraction and no evidence for the occurrence of endogenous inhibitors in the nerve vesicles was obtained. A great variation in density of the dopamine β-hydroxylase containing particles was observed. This was probably mainly due to the variation in vesicle maturation since dopamine β-hydroxylase was distributed more towards the lighter gradient fractions in the proximal nerve segment preparations compared with intrasplenic nerve segment preparations. Noradrenaline/protein and noradrenaline/dopaminc β-hydroxylase ratios were found to be increased about 1·7-fold in the vesicle fraction isolated from the proximal nerve segments to those from the intrasplenic segments. A further increase of the noradrenaline/dopamine β-hydroxylase ratio was observed in a fraction with the same density isolated from the spleen. On the basis of these findings the noradrenaline/protein ratio was calculated to be about 500-600 nmol/mg in the nerve terminal vesicles.     

Effect of partial ischemia and axotomy on activities of cholinergic enzymes in lower motor neurons of the dog

Activities of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) in the ventral spinal cord, ventral spinal roots and in the central and peripheral stumps of the sciatic nerve transected under conditions of partial ischemia (produced by aortic ligation just below the renal arteries) were compared to those obtained under intact blood supply in time intervals 5, 10, or 15 days after surgery. The significant increase of ChAT activity in the central part of the sciatic nerve following 15 days of partial ischemia correlated with less significant elevation of ChAT in the ventral spinal cord. The changes of AChE activity were not significant during partial ischemia. ChAT in the peripheral stump of the sciatic nerve following 5 days of partial ischemia was preserved by 40% and AChE by 20% more than under normal blood supply. On the contrary, in the next 5 days interval losses of enzymes activity in the degenerating nerve were greater. ChAT was almost totally inactivated whereas 50% of AChE activity was preserved until the end of period examined.     

神经生长因子促进坐骨神经再生修复的酶组织化学研究

目的研究对兔右坐骨神经损伤后局部给予蛇毒神经生长因子(NGF),观察坐骨神经酶活性变化和超微结构的恢复情况,探讨NGF对神经再生的影响.方法乙酰胆碱酯酶(AChE)、酸性磷酸酶(ACPase)的酶组织化学技术和电镜技术.结果神经损伤后:AChE活性明显下降,NGF组的AChE活性恢复快于盐水对照组;ACPase活性逐渐增高,NGF组的ACPase活性恢复时间短于盐水对照组.坐骨神经的超微结构在神经损伤后也发生变化,NGF组的变化程度小于盐水对照组,恢复时间短于对照组.结论NGF可通过影响酶物质的代谢而起到加快受损神经恢复的作用.为临床上应用蛇毒NGF治疗周围神经损伤提供形态学依据.     

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.     

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.     

LOCAL CHANGES IN SUBCELLULAR DISTRIBUTION OF DOPAMINE-β-HYDROXYLASE (EC 1.14.2.1) AFTER BLOCKADE OF AXONAL TRANSPORT

Abstract— The distribution of DBH activity between soluble and sedimentable fractions of hypotonic homogenates was examined in rat sympathetic ganglia and nerves after interruption of axonal transport. Local application of colchicine to superior cervical ganglia caused an increase mainly in particulate DBH activity, which was presumably bound to membranes. Likewise, in sciatic nerves, particulate DBH activity accumulated on both sides of a ligature and disappeared from a region well below a ligature much faster than did soluble activity. On the other hand, 18 h after simultaneous application of two ligatures to the nerve, neither total DBH activity nor subcellular distribution of this activity changed in the isolated nerve region. More detailed analysis showed that ligation affected the distribution of DBH activity within a fraction that sedimented at 140,000 g after homogenization of nerves in isotonic sucrose. Just above a ligature, osmotically releasable DBH activity was a smaller proportion of the sedimentable activity than in control nerves. However, as compared to controls, osmotically releasable DBH activity was a larger proportion of the activity in the sedimentable fraction from a region well below a ligature. A model was developed which accounts for some of these results by postulating that DBH is associated with different compartments in sciatic nerve which have different rates of transport and different proportions of soluble and bound enzyme.     

PROPERTIES OF THE EXTERNAL ACETYLCHOLINESTERASE IN GUINEA-PIG IRIS

Abstract— The acetylcholinesterase (AChE) of intact iris, the so-called external AChE, differs in several respects from the AChE in an homogenate of iris, called the total AChE. Maximum enzyme activities of the external and total AChE were obtained with an ACh concentration of 10 and 1.3 m m , respectively. The total AChE exhibited substrate inhibition at high substrate concentrations, whereas the external enzyme did not exhibit substrate inhibition in the range studied. The external AChE activity, when measured at 1.3 m m -ACh. accounted only for 12% of the total enzyme activity. After irreversible inhibition of AChE with diisopropylfluorophosphate (DFP) or methylisocyclopentylfluorophosphate (soman) the external AChE recovered to almost normal values after 48 h, whereas only 30% of the total AChE recovered during this period. Pupillographic studies after inhibition with DFP demonstrated that pupillary diameter had reached normal size after 24 h.
Destruction of the cholinergic input to iris reduced the total AChE activity by 40%, but did not alter the external AChE activity nor its rate of recovery after DFP inhibition. The specific activities of total AChE and total choline acetyltransferase were significantly higher in the sphincter than in the dilator muscle. After such denervation of iris the greatest reduction in total AChE and choline acetyltransferase were found in the sphincter region. After treatment with DFP the total AChE was inhibited to the same extent and recovered at the same rate in both regions.
After extraction of AChE from iris with various salt solutions and detergents, the particulate enzyme recovered faster than the soluble enzyme from DFP inhibition.     

Regulation of UDP-Galactose:Ceramide Galactosyltransferase and UDP-Glucose:Ceramide Glucosyltransferase After Crush and Transection Nerve Injury

The enzyme activities of ceramide galactosyltransferase and ceramide glucosyltransferase were assayed as a function of time (0, 1, 2, 4, 7, 14, 21, 28, and 35 days) after crush injury or permanent transection of the adult rat sciatic nerve. These experimental models of neuropathy are characterized by the presence and absence of axonal regeneration and subsequent myelin assembly. Within the first 4 days after both injuries, a 50% reduction of ceramide galactosyltransferase-specific activity was observed compared to values found in the normal adult nerve. This activity remained unchanged at 7 days after injury; however, by 14 days the ceramide galactosyltransferase activity diverged in the two models. The activity increased in the crushed nerve and reached control values by 21 days, whereas a further decrease was observed in the transected nerve such that the activity was nearly immeasurable by 35 days. In contrast, the ceramide glucosyltransferase activity showed a rapid increase between 1 and 4 days, followed by a plateau that was 3.4-fold greater than that in the normal adult nerve, which persisted throughout the observation period in both the crush and transection models. [3H]Galactose precursor incorporation studies at 7, 14, 21, and 35 days after injury confirmed the previously observed shift in biosynthesis from the galactocerebrosides during myelin assembly in the crush model to the glucocerebrosides and oligohexosylceramide homologues in the absence of myelin assembly in the transection model. The transected nerves were characterized by a peak of biosynthesis of the glucocerebrosides at 14 days. Of particular interest is the biosynthesis of the glucocerebrosides and the oligohexosylceramides at 7 and 14 days after crush injury.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Chemical and structural changes of neurofilaments in transected rat sciatic nerve

The sequence of changes occurring in transected rat sciatic nerve was examined by electron microscopy and by sodium dodecyl sulfate (SDS) polyacrylamide disc gel electrophoresis. Representative segments of transected nerves were processed for ultrastructural examinations between 0 and 34 days after the transection of sciatic nerves immediately below the sacro-sciatic notch. The remainder of the transected nerves and the intact portions of sciatic nerves were desheathed and immediately homogenized in 1 percent SDS containing 8 M urea and 50 mM dithioerythritol. Solubilized proteins were analyzed on 12 percent gels at pH 8.3 in a discontinuous electrophoretic system. Initial changes were limited to the axons of transected nerve fibers and were characterized by the loss of microtubules and neurofilaments and their replacement by an amorphous floccular material. These changes became widespread between 24 and 48 h after transection. The disruption of neurofilaments during this interval occurred in parallel with a selective loss of 69,000, 150,000 and 200,000 mol wt proteins from nerve homogenates, thus corroborating the view that these proteins represent component subunits of mammalian neurofilaments. Furthermore, the selective changes of neurofilament proteins in transected nerves indicate their inherent lability and suggest their susceptibility to calcium-mediated alterations. Electrophoretic profiles of nerve proteins during the 4-34-day interval after nerve transection reflected the breakdown and removal of myelin, the proliferation of Schwann cells and the deposition of endoneurial collagen. A marked increase of intermediate-sized filaments within proliferating Schwann cell processes was not accompanied by the appearance of neurofilamentlike proteins in gels of nerve homogenates.     

Subcellular distribution of axonally transported adenylate cyclase: effect of nerve constriction and comparison with acetylcholinesterase

Abstract: Despite several studies indicating that cyclic nucleotides and their associated enzymes are present in peripheral nerves, their role in neuronal function remains unknown. One possible role is that of a modulating influence in the processes associated with axonal growth and maintenance, and in axonal regeneration. This study has used the frog sciatic nerve as a preparation for investigating the subcellular distribution of neuronai adenylate cyclase activity in normal and crush-injured nerves. The experiments have focused primarily on the axonal transport of adenylate cyclase activity and its subcellular redistribution at the site of constriction. The adenylate cyclase activity measurements were also compared with similar measurements of acetylcholinesterase distribution. Adenylate cyclase activity in normal sciatic nerves increased in the segment proximal to a nerve constriction over time, but did not increase distal to the constriction. Subcellular fractionation of the accumulating activity indicated that the majority of axonally transported enzyme was associated with microsomal organelles; however, an additional transported component was found in the nuclear/mitochondrial fraction. The transport velocities of these two components were different. The microsomal activity appeared to be transported with Group I proteins, while the nuclear/mitochondrial activity was transported with Group II. Rapidly transported Group I proteins have been suggested to be destined principally for the axolemma or the agranular reticu-lum, and the more slowly transported Group II proteins to be associated with intracellular organelles, including synaptic structures. Thus, axonally transported adenylate cyclase activity may have more than one functional role in peripheral nerve. The association of both adenylate cyclase and Protein I, an endogenous substrate for cyclic AMP, with Group II transport offers the intriguing possibility of a structural correspondence. Adenylate cyclase activity in Group I, however, did not appear to be transported with organelles which also contained acetylcholinesterase. The two enzymes, in terms of both velocity of transport and susceptibility to retrograde transport, were handled differently by the neuron. The subcellular distribution of adenylate cyclase activity in an isolated nerve segment was also found to change over time. Microsomal activity decreased, while nuclear/mitochondrial activity transiently increased and then also decreased. This may offer some indication of the morphological location of adenylate cyclase and its potential involvement in Wallerian degeneration and nerve regeneration, particularly in view of recent reports concerning the importance of local injury-induced changes to the initiation of nerve regeneration. We have proposed a dynamic association between axonal calcium and cyclic AMP concentration, which provides a method for membrane renewal or degradation in the intact axon and may offer a molecular basis for the structural reorganization occurring in the proximal segment of an injured nerve.     

Decreased G4 (10S) Acetylcholinesterase Content in Motor Nerves to Fast Muscles of Dystrophic 129/ReJ Mice: Lack of a Specific Compartment of Nerve Acetylcholinesterase?

Acetylcholinesterase (AChE; EC 3.1.1.7) activity and the distribution of its molecular forms were studied in the nervous system of normal and dystrophic 129/ReJ mice, including the sciatic-tibial nerve trunk and motor nerves to slow- and fast-twitch muscles. In normal mice, motor nerves to the slow-twitch soleus exhibited a low AChE activity together with a low level of G4 (10S form) as compared with nerves of the predominantly fast-twitch plantaris and extensor digitorum longus. In contrast, in dystrophic mice, the AChE activity as well as the G4 content of nerves to the fast-twitch muscles were low, displaying an AChE content similar to that of the nerve of the soleus muscle. In the sciatic-tibial nerve trunk, the AChE activity decreased along the nerve in an exponential mode, at rates that were similar in both conditions. However, in dystrophic mice, the AChE activity was reduced throughout the nerve length by a constant value of approximately 180 nmol/h/mg protein. Further analyses indicated that AChE in this nerve trunk was distributed among two compartments, a decaying and a constant one. The decay involved exclusively the globular forms. The activity of A12 (16S form) remained constant along the nerve and was similar in both normal and dystrophic mice. In addition, according to the equation describing the decay of AChE, the reduction in enzymatic activity observed in the dystrophic mice affected mainly G4 in the constant compartment. Brain, spinal cord, sympathetic ganglia, and serum, which were also examined, showed no remarkable differences between the two conditions in their G4 content. The AChE abnormalities that we found in nervous tissues of 129/ReJ dystrophic mice were confined to the motor system.     

Vasoactive-intestinal-polypeptide (VIP)-like immunoreactive cells in the skull base of rats. A combined study using acetylcholinesterase histochemistry

We investigated the distribution of vasoactive intestinal polypeptide (VIP)-like immunoreactive cell bodies in relation to the major cerebral and internal carotid arteries at the skull base in rats. Acetylcholinesterase (AChE) histochemistry was also applied to investigate the localization of this enzyme. VIP staining revealed a few positive cell bodies in nerves close to the internal carotid artery at the base of the skull as well as in the cerebral arterial wall. Ganglion-like cell bodies were detectable within the greater superficial petrosal (GSP) nerve. AChE activity was observed in VIP-like immunoreactive cell bodies along the whole of the GSP nerve. These cell bodies in the GSP nerve may give rise to at least some of the perivascular VIP- and AChE-containing nerves of the internal carotid arteries at the base of the skull.