Transport and turnover of acetylcholinesterase and choline acetyltransferase in rat sciatic nerve and skeletal muscle

Change in the neurochemical signature and morphological development of the parvocellular isthmic projection to the avian tectum

Neurons can change their classical neurotransmitters during ontogeny, sometimes going through stages of dual release. Here, we explored the development of the neurotransmitter identity of neurons of the avian nucleus isthmi parvocellularis (Ipc), whose axon terminals are retinotopically arranged in the optic tectum (TeO) and exert a focal gating effect upon the ascending transmission of retinal inputs. Although cholinergic and glutamatergic markers are both found in Ipc neurons and terminals of adult pigeons and chicks, the mRNA expression of the vesicular acetylcholine transporter, VAChT, is weak or absent. To explore how the Ipc neurotransmitter identity is established during ontogeny, we analyzed the expression of mRNAs coding for cholinergic (ChAT, VAChT, and CHT) and glutamatergic (VGluT2 and VGluT3) markers in chick embryos at different developmental stages. We found that between E12 and E18, Ipc neurons expressed all cholinergic mRNAs and also VGluT2 mRNA; however, from E16 through posthatch stages, VAChT mRNA expression was specifically diminished. Our ex vivo deposits of tracer crystals and intracellular filling experiments revealed that Ipc axons exhibit a mature paintbrush morphology late in development, experiencing marked morphological transformations during the period of presumptive dual vesicular transmitter release. Additionally, although ChAT protein immunoassays increasingly label the growing Ipc axon, this labeling was consistently restricted to sparse portions of the terminal branches. Combined, these results suggest that the synthesis of glutamate and acetylcholine, and their vesicular release, is complexly linked to the developmental processes of branching, growing and remodeling of these unique axons.

Cholinergic activity is essential for maintaining the anterograde transport of Choline Acetyltransferase in Drosophila

Cholinergic activity is essential for cognitive functions and neuronal homeostasis. Choline Acetyltransferase (ChAT), a soluble protein that synthesizes acetylcholine at the presynaptic compartment, is transported in bulk in the axons by the heterotrimeric Kinesin-2 motor. Axonal transport of soluble proteins is described as a constitutive process assisted by occasional, non-specific interactions with moving vesicles and motor proteins. Here, we report that an increase in the influx of Kinesin-2 motor and association between ChAT and the motor during a specific developmental period enhances the axonal entry, as well as the anterograde flow of the protein, in the sensory neurons of intact Drosophila nervous system. Loss of cholinergic activity due to  Hemicholinium and Bungarotoxin treatments, respectively, disrupts the interaction between ChAT and Kinesin-2 in the axon, and the episodic enhancement of axonal influx of the protein. Altogether, these observations highlight a phenomenon of synaptic activity-dependent, feedback regulation of a soluble protein transport in vivo, which could potentially define the quantum of its pre-synaptic influx.

Glycogen synthase kinase-3 reduces acetylcholine level in striatum via disturbing cellular distribution of choline acetyltransferase in cholinergic interneurons in rats

Cholinergic interneurons, which provide the main source of acetylcholine (ACh) in the striatum, control the striatal local circuits and deeply involve in the pathogenesis of neurodegenerative diseases. Glycogen synthase kinase-3 (GSK-3) is a crucial kinase with diverse fundamental functions and accepted that deregulation of GSK-3 activity also plays important roles in diverse neurodegenerative diseases. However, up to now, there is no direct proof indicating whether GSK-3 activation is responsible for cholinergic dysfunction. In the present study, with combined intracerebroventricular injection of Wortmannin and GF-109203X, we activated GSK-3 and demonstrated the increased phosphorylation level of microtubule-associated protein tau and neurofilaments (NFs) in the rat striatum. The activated GSK-3 consequently decreased ACh level in the striatum as a result of the reduction of choline acetyltransferase (ChAT) activity. The alteration of ChAT activity was due to impaired ChAT distribution rather than its expression. Furthermore, we proved that cellular ChAT distribution was dependent on low phosphorylation level of NFs. Nevertheless, the cholinergic dysfunction in the striatum failed to induce significant neuronal number reduction. In summary, our data demonstrates the link between GSK-3 activation and cholinergic dysfunction in the striatum and provided beneficial evidence for the pathogenesis study of relevant neurodegenerative diseases.

Neurogenetics of slow axonal transport: from cells to animals

Slow axonal transport is a multivariate phenomenon implicated in several neurodegenerative disorders. Recent reports have unraveled the molecular basis of the transport of certain slow component proteins, such as the neurofilament subunits, tubulin, and certain soluble enzymes such as Ca(2+)/calmodulin-dependent protein kinase IIa (CaM kinase IIa), etc., in tissue cultured neurons. In addition, genetic analyses also implicate microtubule-dependent motors and other housekeeping proteins in this process. However, the biological relevance of this phenomenon is not so well understood. Here, the authors have discussed the possibility of adopting neurogenetic analyses in multiple model organisms to correlate molecular level measurements of the slow transport phenomenon to animal behavior, thus facilitating the investigation of its biological efficacy.

Interaction with a kinesin-2 tail propels choline acetyltransferase flow towards synapse

Bulk flow constitutes a substantial part of the slow transport of soluble proteins in axons. Though the underlying mechanism is unclear, evidences indicate that intermittent, kinesin-based movement of large protein-aggregates aids this process. Choline acetyltransferase (ChAT), a soluble enzyme catalyzing acetylcholine synthesis, propagates toward the synapse at an intermediate, slow rate. The presynaptic enrichment of ChAT requires heterotrimeric kinesin-2, comprising KLP64D, KLP68D and DmKAP, in Drosophila. Here, we show that the bulk flow of a recombinant Green Fluorescent Protein-tagged ChAT (GFP::ChAT), in Drosophila axons, lacks particulate features. It occurs for a brief period during the larval stages. In addition, both the endogenous ChAT and GFP::ChAT directly bind to the KLP64D tail, which is essential for the GFP::ChAT entry and anterograde flow in axon. These evidences suggest that a direct interaction with motor proteins could regulate the bulk flow of soluble proteins, and thus establish their asymmetric distribution.

Kinesin-2 differentially regulates the anterograde axonal transports of acetylcholinesterase and choline acetyltransferase inDrosophila

Choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) are involved in acetylcholine synthesis and degradation at pre- and postsynaptic compartments, respectively. Here we show that their anterograde transport in Drosophila larval ganglion is microtubule-dependent and occurs in two different time profiles. AChE transport is constitutive while that of ChAT occurs in a brief pulse during third instar larva stage. Mutations in the kinesin-2 motor subunit Klp64D and separate siRNA-mediated knock-outs of all the three kinesin-2 subunits disrupt the ChAT and AChE transports, and these antigens accumulate in discrete nonoverlapping punctae in neuronal cell bodies and axons. Quantification analysis further showed that mutations in Klp64D could independently affect the anterograde transport of AChE even before that of ChAT. Finally, ChAT and AChE were coimmunoprecipitated with the kinesin-2 subunits but not with each other. Altogether, these suggest that kinesin-2 independently transports AChE and ChAT within the same axon. It also implies that cargo availability could regulate the rate and frequency of transports by kinesin motors.

Choline acetyltransferase: the structure, distribution and pathologic changes in the central nervous system

Choline acetyltransferase (ChAT), the enzyme responsible for the biosynthesis of acetylcholine, is presently the most specific indicator for monitoring the functional state of cholinergic neurones in the central and peripheral nervous systems. ChAT is a single-strand globular protein. The enzyme is synthesized in the perikaryon of cholinergic neurones and transported to the nerve terminals probably by both slow and rapid axoplasmic flows. ChAT exists in at least two forms in cholinergic nerve terminals: (i) soluble; and (ii) non-ionically membrane-bound forms. Multiple mRNA species of ChAT (R-, N-and M-types) are transcribed from different promoter regions and produced by different splicing in the mouse, rat, and human. All transcripts encode the same ChAT protein in rodents, while in human M-type mRNA has the capability to generate both large and small forms of ChAT proteins and R-and N-types ChAT mRNA generate a small form, which corresponds to the rodent ChAT. The genomic structure of ChAT is unique compared with other enzymes for neurotransmitters. The first intron of the ChAT gene encompasses the open reading frame encoding another protein, vesicular acetylcholine transporter (VAChT), which is responsible for the transportation of acetylcholine from the cytoplasm into the synaptic vesicles. The expressions of ChAT and VAChT appear to be coordinately regulated by multiple regulatory elements in cholinergic neurones. Immunohistochemical and in situ hybridization studies have revealed the localization of cholinergic neurones in the central nervous system: the medial septal nucleus, the nucleus of the diagonal band of Broca, the basal nucleus of Meynert, the caudate nucleus, the putamen, the nucleus accumbens, the pedunculopontine tegmental nucleus, the laterodorsal tegmental nucleus, the medial habenular nucleus, the parabigeminal nucleus, some cranial nerve nuclei, and the anterior horn of the spinal cord. Focally distributed cholinergic neurones project fibers to many areas in the central nervous system and construct a complicated cholinergic network, playing an important role in neuropsychic activities, such as learning, memory, arousal, sleep and movement. Central cholinergic neurones are involved in several neurodegenerative diseases such as Alzheimer's disease and amyotrophic lateral sclerosis, in which disturbance of the central cholinergic system does not appear to be closely related to the etiology, but rather to the development of clinical symptoms. In addition, abnormalities of ChAT in the brain have been recently demonstrated in schizophrenia and sudden infant death syndrome.

Axonal transport and MR imaging: prospects for contrast agent development

Axonal transport plays a critical role in the physiology and pathology of neurons, yet there have been virtually no clinical tools for its evaluation in human subjects. A wide variety of molecules that can act as axonal transport facilitators have been discovered and, in many cases, used to deliver labels detectable with histologic methods. Recently a number of investigators have reported preliminary success in developing intraneural contrast agents based on various versions of dextran-coated magnetite that may render magnetic resonance imaging capable of depicting axonal transport. It is not yet clear whether any clinically useful agents will eventually be developed, but there has been considerable progress in identifying design factors for such a pharmaceutical agent.

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 approximately 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.

Reduced axonal transport of the G4 molecular form of acetylcholinesterase in the rat sciatic nerve during aging

Aging in the sciatic nerve of the rat is characterized by various alterations, mainly cytoskeletal impairment, the presence of residual bodies and glycogen deposits, and axonal dystrophies. These alterations could form a mechanical blockade in the axoplasm and disturb the axoplasmic transports. However, morphometric studies on the fiber distribution indicate that the increase of the axoplasmic compartment during aging could obviate this mechanical blockade. Analysis of the axoplasmic transport, using acetylcholinesterase (AChE) molecular forms as markers, demonstrates a reduction in the total AChE flow rate, which is entirely accounted for by a significant bidirectional 40-60% decrease in the rapid axonal transport of the G4 molecular form. However, the slow axoplasmic flow of G1 + G2 forms, as well as the rapid transport of the A12 form of AChE, remain unchanged. Our results support the hypothesis that the alterations observed in aged nerves might be related either to the impairment in the rapid transport of specific factor(s) or to modified exchanges between rapidly transported and stationary material along the nerves, rather than to a general defect in the axonal transport mechanisms themselves.

Axonal transport of the molecular forms of acetylcholinesterase in rats at the onset of diabetes induced by streptozotocin

During the development of streptozotocin-induced diabetic neuropathy in the rat, the axonal transport of 4 acetylcholinesterase molecular forms was studied by measuring their accumulation on both sides of transected sciatic nerves. Our results indicate that both the anterograde and retrograde axonal transport of all these forms remain normal between 2 and 5 weeks after the induction of diabetes by streptozotocin injection.

NGF effects on developing forebrain cholinergic neurons are regionally specific

Nerve growth factor (NGF) has been shown to have an effect on neurons in the central nervous system (CNS). A number of observations suggest that NGF acts as a trophic factor for cholinergic neurons of the basal forebrain and the caudate-putamen. We sought to further characterize the CNS actions of NGF by examining its effect on choline acetyltransferase (ChAT) activity in the cell bodies and fibers of developing neurons of the septum and caudate-putamen. ChAT activity was increased after even a single NGF injection. Interestingly, the magnitude of the effect of multiple NGF injections suggested that repeated treatments may augment NGF actions on these neurons. The time-course of the response to NGF was followed after a single injection on postnatal day (PD) 2. NGF treatment produced long-lasting increases in ChAT activity in septum, hippocampus and caudate-putamen. The response in cell body regions (septum, caudate-putamen) was characterized by an initial lag period of approximately 24 hr, a rapid rise to maximum values, a plateau phase and a return to baseline. The response in hippocampus was delayed by 48 hr relative to that in septum, indicating that NGF actions on ChAT were first registered in septal cell bodies. Finally, developmental events were shown to have a regionally specific influence on the response of neurons to NGF. For though the septal response to a single NGF injection was undiminished well into the third postnatal week, little or no response was detected in caudate-putamen at that time. In highlighting the potency and regional specificity of NGF effects, these observations provide additional, support for the hypothesis that NGF is a trophic factor for CNS cholinergic neurons.

Molecular biology and neurobiology of choline acetyltransferase

In the 45 years since the first description of choline acetyltransferase (ChAT; EC 2.3.1.6.), significant progress has been made in characterizing the molecular properties of this important neurotransmitter synthetic enzyme. We are now on the verge of understanding its genetic regulation and biological function(s). The Drosophila cDNA has been cloned, sequenced, and expressed in both a eucaryotic and a procaryotic system. The levels of ChAT specific mRNA have been determined during Drosophila development. Monoclonal and polyclonal antibodies have been produced to the enzyme from a variety of sources and used for biochemical and immunocytochemical studies. Two well characterized genetic systems have identified the ChAT gene and described a series of useful alleles. As a nervous system specific protein expressed only in the subset of neurons using acetylcholine as a neurotransmitter, ChAT is a good model for uncovering the processes and factors responsible for regulating genes involved in neurotransmitter phenotype selection and maintenance. Recent studies have described the purification of a cholinergic factor from muscle conditioned medium and indicated the potential importance of nerve growth factor (NGF) for regulating ChAT expression in the central nervous system. These factors, or ones remaining to be discovered, may be involved in the etiology or disease process of neurodegenerative nervous system disorders such as Alzheimer's disease.

Fast axonal transport of acetylcholinesterase in rat sciatic motoneurons is enhanced following prolonged daily running, but not following swimming

The effects of increases in neuronal activity on fast axonal transport of acetylcholinesterase (AChE) in sciatic motoneurons were studied by subjecting rats to daily running or swimming training (8 weeks). Net accumulation of AChE activity proximal and distal to a ligature served to evaluate orthograde and retrograde transport. Results showed that runners had greater orthograde and retrograde transport of AChE as compared to control animals, while no changes were found in swimmers. These adaptations in the runners were caused by the long-term nature of the training regimen since an acute exercise session had no effect on AChE transport. The observed changes may be attributed to an increase in the mobile fraction of AChE in the motoneurons. Since swimming training had no effect on transport but entails a high level of neuronal activity, it is suggested that increased impulse activity is not the factor mediating the adaptations in axonal transport of AChE which resulted from running training.

Trophic control of cholinesterase activity in a testosterone-dependent muscle of the rat: effects of castration and denervation

The effects of testosterone withdrawal and chronic denervation on muscle weight and acetylcholinesterase (AChE) activity were studied in the hormone-sensitive levator ani muscle of the rat. Castration of adult male rats for 7 to 60 days caused a linear decrease of the weight, protein content, and AChE activity of the muscle, which stabilized after 30 days. Muscle weight and protein content decreased 2.3% per day. The total AChE activity decreased 7 days later 3.2% per day, reaching 37% of control at day 30. AChE activity per unit weight was increased in all castrated groups. Muscle weights and AChE activity of the extensor digitorum longus and soleus muscles were not altered after castration. Denervation of all three muscles caused 50% reduction of the muscle weight and protein content after 15 days. Total AChE activity decayed exponentially with a rate of 0.12 per day to 15 to 18% of control values. AChE activity per unit weight in the denervated muscles was always lower than in the control muscles. Combined castration and denervation intensified only the levator ani protein loss. The different onset and time course of the effects induced by castration and denervation indicate distinct mechanisms involved in the trophic control of muscle proteins and AChE activity. Chronic muscle denervation decreased total AChE activity to 15% of normal, whereas castration reduced the enzyme to 40% of the control values. The results indicate that neuronal and hormonal influences on AChE activity of the levator ani are not additive but overlap.

The contribution of cholinergic enzymes and acetylcholine from the lumbar sympathetic chain to the rat sciatic nerve

This study was performed to investigate how much of the acetylcholine (ACh), choline acetyltransferase (ChAT) and ACh-esterase (AChE) in the rat sciatic nerve originate from the somatic motor input and from the automatic sympathetic input, respectively. The somatic motor axons to the sciatic nerve were eliminated by surgical transsection of the spinal roots, (rhizotomy) and the autonomic component was removed by surgical resection of the lumbar sympathetic chain bilaterally (sympathectomy). Also combined operations were performed. In intact (non-crushed) sciatic nerve rhizotomy caused a reduction in ACh content by 70%, in ChAT-activity by 55%, and in AChE-activity by 41%. Sympathectomy alone had very little influence on ACh and ChAT, but reduced AChE by 20%. After crushing the nerve 13 hours before sacrifice, all three substances accumulated proximal to the crush region as described previously. When compared to the control group, sympathectomy alone caused a reduction in accumulated amounts of AChE only, while ACh and ChAT accumulations were essentially unchanged. Rhizotomy alone caused a substantial reduction in accumulated amounts of all three substances, but most prominently in ACh and ChAT-amounts. After sympathectomy in combination with rhizotomy ACh-accumulations were very low, and enzyme activities were reduced more than in the group with rhizotomy alone. A certain amount of residual ChAT and AChE was present in the nerve, and the location of this is discussed. The fact that combined sympathectomy and rhizotomy lowered ACh accumulations significantly more than would be expected from the results after either operation alone is commented upon.

Slow and fast axonal transport of acetylcholinesterase molecular forms in polyarthritic rats

Acetylcholinesterase (AChE) activity and its distribution among different molecular forms were studied in the sciatic nerve of normal and polyarthritic rats. Axonal transport of each form was investigated on the basis of its accumulation on both sides of a transection. Although an increase in total AChE activity could be detected in the sciatic nerves of polyarthritic animals, both anterograde and retrograde axonal transport of all the molecular forms investigated were similar in normal and polyarthritic rats. This suggests that neither slow nor fast axonal transport is impaired in polyarthritic rats. Hence, the neurophysiological modifications observed at the spinal, thalamic and cortical levels of the CNS are presumably not a consequence of peripheral axonal disability.

Fiber type and non-endplate acetylcholinesterase in normal and experimentally altered muscles

The non-endplate (sarcoplasmic) acetylcholinesterase (AChE) was investigated in eight different muscles of the rat. Serial consecutive sections were stained for AChE, myofibrillar ATPase (after alkaline and acid preincubation), and cytochrome C-oxidase. The following general correlation could be established: within a given muscle the sarcoplasmic AChE was highest in type IIB fibers, lowest in type I and intermediate in type IIA. Additionally, the intensity of the reaction was directly proportional to the size of the type IIA fibers. The distribution of sarcoplasmic AChE was correlated to the ATPase fiber types but was complementary to the cytochrome C-oxidase staining pattern. In single fiber preparations, accumulation of AChE at the myotendinous junction was found to occur in "cap-like" form exclusively in fibers with very low or absent sarcoplasmic AChE. To study the role of innervation in the expression of the sarcoplasmic AChE, we cross-reinnervated the extensor digitorum longus (EDL) muscle with the soleus (SOL) nerve and vice versa (X-EDL, X-SOL). In the X-EDL the sarcoplasmic AChE was transformed to that of a normal SOL as were also the ATPase and the cytochrome oxidase. Surprisingly, in the X-SOL the high AChE activity typical for a normal EDL was present after 3 weeks but decreased steadily to very low levels lacking any correlation with ATPase and cytochrome oxidase. The results suggest that the cytoplasmic AChE of the SOL muscle depends more on the load-bearing function of the muscle than on the imposed impulse pattern. There is additional evidence for a retrograde effect of the X-SOL upon its motoneurons.

Is fast fiber innervation responsible for increased acetylcholinesterase activity in reinnervating soleus muscles?

During reinnervation of the completely denervated rat hind limb we observed previously a temporary overproduction of acetylcholinesterases in the soleus but not in the extensor digitorum longus muscle. In the present study, we investigated whether the predominantly slow soleus, which is low in AChE activity, is initially reinnervated by axons that originally innervated fast muscle fibers with high AChE activity, such as those of the extensor digitorum longus. Local denervation of the rat soleus was carried out to eliminate reinnervation by axons destined for other muscles. This produced an overshoot in AChE activity that was qualitatively similar to that observed with high sciatic crush. Local denervation of the soleus in the guinea pig was done because this muscle is composed solely of slow (type I) fibers, thereby virtually eliminating the possibility of homologous muscle fast fiber innervation. The overshoot in this preparation was qualitatively similar to that seen with distal denervation in the guinea pig and local and distal denervation in the rat. Thus, initial fast fiber innervation is not responsible for the patterns of change in AChE activity seen with reinnervation in the soleus. We concluded that the neural control of AChE is different in these two muscles and may reflect specific differences in the characteristics of AChE regulation in fast and slow muscle. How these neural influences are translated into muscle synthesis and degradation remains unknown.

Axonal transport of the molecular forms of acetylcholinesterase in developing and regenerating peripheral nerve

In chick sciatic nerve, acetylcholinesterase (AChE) occurs in four main molecular forms characterized by their sedimentation coefficients in sucrose gradients, referred to as G1 (5S), G2 (7.5S), G4 (11S), and A12 (20S). Under normal conditions, we previously showed by accumulation technique that the G4 and A12 forms are rapidly transported along the axons, whereas G1 and G2 are carried much more slowly. Here, we used to the same technique to study the anterograde axonal transport of these different AChE forms during normal axonal growth and experimental regeneration. During the first 2 months after hatching, G4 and A12 transport virtually doubled, whereas G1 + G2 transport increased only slightly. After nerve cutting, crushing, or freezing, the flow rates of G1 + G2 and G4 in the regenerating proximal stump decreased by 75% at 4 to 7 days compared with control values and that of A12, by 90 to 95%. In crushed and frozen nerves the transport of all four AChE forms slowly recovered thereafter, but failed to attain control values even after 7 weeks. In cut nerves, on the contrary, no significant recovery of G1 + G2, or G4 transport occurred, but A12 transport began to recover by day 7. Taken together, our results show that axonal transport of G1 + G2, G4, and A12 is selectively regulated in chick sciatic nerve, and suggest that the A12 form of AChE might have a special role and/or destination in regenerating axons.

Cholinesterase activities in the somatic nervous system of rabbits with experimental allergic neuritis

The allergic inflammatory disorders of the nervous tissue are associated with a complex series of cellular and humoral immune activities and they usually result at least in demyelination, but according to morphologic evidence also in secondary neuronal changes. Using the colorimetric method of Ellman et al. (G. L. Ellman, K. D. Courtney, V. Anders, and R. M. Featherstone, 1961, Biochem. Pharmacol. 7:88-95) the activities of enzymes splitting acetylthiocholine iodide (AThCh) were determined from various parts of the somatic nervous system of rabbits with experimental allergic neuritis (EAN), a primary demyelinating disease of the peripheral nerves. It was found that the total activity of AThCh-splitting enzymes was decreased already in an early phase of the disease in the dorsal root ganglia (DRG). In a well developed phase of the disease the activity of acetylcholinesterase (AChE) seemed to be decreased by 33% in the ventral roots and by a lesser amount in the DRG and the most proximal part of the sciatic nerves. The mechanism of the recorded changes may be related either to specific or to nonspecific immune events or to both. Proteolytic activity released by macrophages in the target tissue may, by inactivating the hydrolytic activity of AChE, at least partly explain these findings. Because the activity of AChE in the structures studied derives from a neuronal origin, our results provide biochemical evidence for the involvement of neurons in the sensory ganglia and of axolemma in the ventral roots in EAN.

Acetylcholinesterase content in both motor nerve and muscle is correlated with twitch properties

The activity and molecular forms of acetylcholinesterase (AChE) were studied in the rat soleus muscle and its nerve, as compared to their fast-twitch counterparts. The soleus muscle and its nerve exhibited both significantly lower AChE activity and less of the G4 (10S) molecular form. In addition, the soleus muscle displayed a specific increase in the A8 (13S) and A4 (8.8S) asymmetric forms, not seen in any of the fast-twitch muscles examined. These results indicate that the AChE content of a muscle and its nerve are linked and depend on the twitch properties, and that the slow-twitch muscle is characterized by a specific set of AChE molecular forms.

The turnover of acetylcholine in ligated sciatic nerves of the rat

The accumulation of acetylcholine (ACh) and choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) activities proximal to a crush on rat sciatic nerves was investigated after superfusion of the nerves in situ with or without inhibitors of ACh synthesis and/or AChE. 9 h after crushing of nerves, the ACh-content of the 5 mm segment of nerve immediately proximal to the crush was increased from 37 +/- 5 to 80 +/- 4 pmol (mean +/- SE), while ChAT-activity was increased to 112 +/- 10% and AChE-activity to 198 +/- 19% over that in non-ligated nerves. Superfusion of the nerves for 8 h with Krebs' bicarbonate medium had no effect on enzyme accumulations, but reduced the ACh content to 59 +/- 4 pmol. The presence of hemicholinium 3 (HC-3) (2 X 10(-5) M) in the superfusion medium reduced the ACh content markedly (to 17 +/- 2 pmol), but had no effect on enzyme accumulations at the crush. Adding eserine (10(-5) M) or soman (10(-6) M) to the superfusion medium increased ACh content to 133 +/- 8 pmol and 101 +/- 8 pmol, respectively, and markedly reduced AChE-activity; ChAT activity was not effected. Superfusion with a combination of HC-3 and eserine caused a marked reduction in ACh content compared with eserine alone; the effect was less with soman. The results are consistent with the view that the ACh which accumulates proximal to crush exists in a protective organelle, but that there is a continuous turnover of ACh due to leakage of ACh from the organelle, both during axonal transport and after accumulation.

Capsaicin applied to peripheral nerve inhibits axoplasmic transport of substance P and somatostatin

Capsaicin was applied locally to the sciatic or saphenous nerve, and the effects on axoplasmic transport, neurogenic plasma extravasation, and thermal pain were studied. Capsaicin (10 mg/ml) led to a complete block of axoplasmic transport of immunoreactive substance P (I-SP) and somatostatin (I-SRIF) in rat sciatic nerve without affecting the transport of noradrenaline or acetylcholinesterase. Inhibition of I-SP transport was also found in sciatic nerves of guinea-pig, cat and rabbit. In contrast, one or two weeks after systemic capsaicin treatment (125 mg/kg s.c.), orthograde transport of I-SP was the same in control and capsaicin-treated rats. After local capsaicin application to the sciatic nerve, a decrease of I-SP was found not only in skin and sciatic nerve distal to the site of application, but also in dorsal root ganglia, dorsal roots and the dorsal half of the spinal cord segments L 4-5. This was accompanied by a loss of acid phosphatase activity in the substantia gelatinosa supplied by sciatic nerve afferents. Plasma extravasation by mustard oil was reduced in the skin of the hind paw with a time course identical to the I-SP depletion. The response to noxious heat (hot plate test) was, however, abolished earlier. These results indicate that capsaicin applied to a peripheral nerve inhibits axoplasmic transport in sensory but not in adrenergic or cholinergic neurons, which leads to long-term biochemical and functional changes of the entire sensory neuron. In addition, capsaicin appears to inhibit impulse propagation in certain populations of sensory neurons.

Turnover of the molecular forms of acetylcholinesterase in the rat diaphragm

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 less than 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 low of AChE activity was restricted to the 4S enzyme, which had an apparent half-life of 6.2 h.

Turnaround of axoplasmic transport of selected particle-specific enzymes at an injury in control and diisopropylphosphorofluoridate-treated rats

Reversal of direction (turnaround) of axonal transport of particle-specific enzyme activities was studied at a ligature placed on rat sciatic nerve. In the principal experiment, the ligature remained on the nerve in vivo several hours, allowing enzyme activities (acetylcholinesterase, acid phosphatase, and monoamine oxidase) to accumulate immediately proximal to the tie. The nerve was then tied a second time, proximal to the first tie, and incubated in vitro for several more hours. Accumulation of enzyme activities just distal to the second tie was measured. This second accumulation, of activities traveling in the retrograde direction, was shown to be the result of turnaround in several ways. (1) The increase in activity distal to the second tie was equal to the decrease in activity proximal to the first. (2) The increase in enzyme activities distal to the second tie was greatly reduced when the accumulation proximal to the first tie was trapped by placing a third tie between the first and second ties. (3) It was shown that the activity that accumulated distal to the second tie could not have been in retrograde motion at the time of the first tie. (4) Accumulation distal to the second tie was not a function of the length of nerve segment included between the two ties. In contrast to the consistent occurrence of turnaround of orthograde flow, turnaround of retrograde flow could not be demonstrated. Turnaround transport was blocked by incubation in the cold and in the presence of NaCN or vinblastine. The turnaround process operated on all three enzymes studied, suggesting that it operates on lysosomes and mitochondria, as well as on the endoplasmic reticulum-like material bearing acetylcholinesterase. Evidence for the participation of the transport process in the renewal of AChE in the distal portions of the axon was obtained in experiments using diisopropylphosphorofluoridate and cycloheximide.