The effect of subtotal vagotomy of the plexus myentericus (Auerbach) on the function of the intramural nervous system. A quantitative histochemical examination in white laboratory mice]

The effect of a subtotal vagotomy on the function of the intramural nervous system of different parts of the intestinal tract is studied by means of quantitative measurements of the acetylcholinesterase (AChE) activity. By sham vagotomy it was possible to explore the effect of narcosis and laparotomy on the intramural nervous system of the intestine. Vagotomy is followed by a decrease in AChE activity of the ganglionic cells in all parts of the intestinal tract. A minimum of activity, about 50% of the normal concentration, is attained at the 16th postoperative day. After this time, a continual increase in AChE activity, along with a reactivation of the function of the ganglionic cells, can be observed. 90 days after vagotomy the ganglionic cells of the intramural nervous plexus show a normal enzyme activity. These results support the hypothesis that most of the cells of the myenteric plexus build up an autonomic nervous plexus, which is stimulated in an excitatory way by the vagus nerve and which will be inhibited by sympathetic stimulation.     

Ultrastructural localization of acetylcholinesterase in the synganglion of the tick,Dermacentor variabilis (Say)

Summary Light- and electron-microscopic enzyme cytochemistry was used to localize acetylcholinesterase (AChE) activity in the synganglion (brain) of the tick Dermacentor variabilis. High AChE activity was observed throughout the neuropil as well as adjacent to most neuronal perikarya. Intracellular activity was not observed by light microscopy. By electron microscopy, reaction product was localized at the plasma membrane of glia and neurons. Enzyme activity was not associated with the olfactory globuli neurons. In other types of neurons, small amounts of reaction product were observed in the Golgi apparatus and nuclear envelope. Large neurosecretory neurons contained activity that appeared to be associated with deep invaginations of the plasma membrane as well as intracellular membranes. AChE activity was also associated with processes of both neurons and glia. In most peripheral nerves AChE activity was associated with virtually all axons. Clearly then, AChE is associated with glia and non-cholinergic neurons as well as with presumed cholinergic neurons. The widespread localization and large amounts of AChE in the tick brain exceeds that reported for other invertebrates and vertebrates. As has been suggested for other animals, AChE in the tick brain may have functions in addition to its known role in cholinergic neurotransmission.     

Cytophotometric analyses of thalamic neuronal RNA in soman intoxicated rats

Quantitative azure B-RNA cytophotometry was used to monitor metabolic responses of individual neurons within the ventrobasal nuclear complex (VBC) and nucleus reticularis (NR) of the rat thalamus following administration of soman (0.5, 0.9 or 1.5 LD₅₀, sc). A dose-dependent depression in brain acetylcholinesterase (AChE) was evidenced. With respect to thalamic RNA responses, a complex pattern of RNA alterations was evidenced, with these two regions generally exhibiting opposite patterns of dose-related RNA changes. With sub-lethal dosages of soman, RNA accumulation was evidenced in the acetylcholine (ACh) mediated excitatory VBC region and RNA depletion in the ACh mediated inhibitory NR neurons. With a lethal dose, an opposite RNA response pattern observed in both thalamic regions. It is postulated that the observed RNA response pattern with sub-lethal dosages of soman is what one would anticipate with cholinergic brainstem reticular formation activation. The absence of such a response with lethal doses strongly suggests some disruption of functional excitatory cholinergic activity and perhaps also an impairment of inhibitory cholinergic synaptic activity.     

Seasonal Variations in the Circadian Activity of Ache in the Brain Stem Reticular Formation of Mice Under Normal and Constant Light Regimens

AChE activity in mouse brain stem reticular formation was studied at 4hr intervals for 48 hr at 4 different times of the year under normal (LD 12/12) and constant light (LL) regimens. Under both illumination regimens, a significant ultradian rhythm of AChE activity was observed. In the investigated seasons of the year, changes in AChE behaviour were limited to mean activity of the enzyme (median) as well as to the amplitude and acrophase of the rhythm.     

Cholinergic enzymes in the ciliary ganglia of the chicken and pigeon

In the present paper we have comparatively analyzed acetylcholinesterase (AChE) and cholinacetyltransferase (ChAT) activity in chick and pigeon ciliary ganglion. AChE specific activity in the pigeon ciliary ganglion is remarkably higher than the one occurring in the chick; conversely the ChAT specific activity is similar in the chick as well as in the pigeon. Higher AChE activity found in the pigeon ciliary ganglion can be partially attributed to a selective accumulation of the enzyme in already described membrane-limited formations typical of the choroid neurons. After post-ganglionic axotomy such formations undergo a progressive disappearance which parallels the decrease of AChE activity. The present data suggest the hypothesis that the structures under investigation as well as ganglionic AChE are possibly controlled through a retrograde mechanism by their target organ.     

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.     

Developmental changes and acetylcholinesterase activity in the metamorphosing brain of Tenebrio molitor: Correlation to ecdysteroid titers

The brain of Tenebrio molitor exhibited marked fluctuations in acetylcholinesterase (AChE) activity throughout metamorphosis. This was true AChE activity, since it was inhibited by high substrate concentrations and by 10 μM of the specific AChE inhibitor BW284C51 [(1,5-bis'4-allyldimethylammoniumphenyl)-pentan-3-one dibromide] but not by iso-OMPA (tetraisopropylpyrophosphoramide), a cholinesterase (but not AChE) inhibitor. The histochemical AChE activity was localized in the neuropile and the nuclear envelope of neurons and glial cells. The enzyme extracted from brains with 1% Triton X-100 and 1 M NaCl sedimented as a single peak in a sucrose density gradient, with a sedimentation coefficient of 5.4S. This single AChE sedimentation peak was mainly due to an amphiphilic dimeric form. AChE activity per brain increased in newly ecdysed pupa. AChE activity per milligram of protein exhibited a peak in the mid-pupa which could be correlated to the increase in ecdysteroid titers. © 1994 Wiley-Liss, Inc.     

Histo- and immunocytochemical characterization of the neurons of the mucosal plexus in the rat colon.

The mucosal plexus of the rat colon descendens is constituted of a network of nerves that, in contrast to most other segments of the digestive tract, contains also ganglia. The ganglia, consisting of neurons and glial cells, are located in the basal part of the lamina propria at distances between 100 and 1,200 microns. They are not vascularized. The neurons in these ganglia were characterized by means of: (1) the histochemical demonstration of acetylcholinesterase (AChE) activity, (2) the immunocytochemical identification of neurofilament proteins (NFP; 200 kD) and (3) their ultrastructure. The glial cells, which were AChE negative, could be distinguished from the neurons by differences in size and chromatin pattern. All neurons of the mucosal plexus reveal AChE activity in the perikaryon, but only parts of the axons are AChE positive. NFP-like immunoreactivity was detected in the perikarya but only in a minor part of the axons. These findings confirm previous light-microscopical observations and add new evidence for the existence of neurons (ganglia) in the mucosal plexus of the rat colon.     

The effect of acetylcholinesterase on outgrowth of dopaminergic neurons in organotypic slice culture of rat mid-brain

This study has investigated the possibility that acetylcholinesterase could play a non-classical role as an adhesion factor or growth factor in the development of dopaminergic neurons in organotypic slice culture of postnatal day 1 rats. When the culture medium was supplemented with acetylcholinesterase (3 U/ml), outgrowth of tyrosine hydroxylase-immunoreactive neurites was significantly enhanced. Addition of a specific inhibitor of acetylcholinesterase, BW284c51, caused a decrease in the number of tyrosine hydroxylase neurons and a reduction in the cell body size and extent of neurite outgrowth of remaining neurons. However, echothiophate which also inhibits AChE activity, did not produce these effects. Therefore acetylcholinesterase could act as a growth enhancing factor for dopaminergic neurons, and disruption of an as yet unidentified site on the acetylcholinesterase molecule by BW284c51 could decrease the survival and outgrowth of these neurons.     

Bicarbonate stimulatory action of nizatidine, a histamine H(2)-receptor antagonist, in rat duodenums.

Nizatidine, a histamine H(2)-antagonist, is known to inhibit acetylcholinesterase (AChE) activity and is used clinically as a gastroprokinetic agent as well as the anti-ulcer agent. We examined whether or not nizatidine stimulates duodenal HCO(3)(-) secretion in rats through vagal-cholinergic mechanisms by inhibiting AChE activity. Under pentobarbital anesthesia, a proximal duodenal loop was perfused with saline, and the HCO(3)(-) secretion was measured at pH 7.0 using a pH-stat method and by adding 10 mM HCl. Nizatidine, neostigmine, carbachol, famotidine or ranitidine was administered i.v. as a single injection. Intravenous administration of nizatidine (3-30 mg/kg) dose-dependently increased the HCO(3)(-) secretion, and the effect at 10 mg/kg was equivalent to that obtained by carbachol at 0.01 mg/kg. The HCO(3)(-) stimulatory action of nizatidine was observed at the doses that inhibited the histamine-induced acid secretion and enhanced gastric motility. This effect was mimicked by neostigmine (0.03 mg/kg) and significantly attenuated by bilateral vagotomy and pretreatment with atropine but not indomethacin. The IC(50) of nizatidine for AChE of rat erythrocytes was 1.4 x 10(-6) M, about 12 times higher than that of neostigmine. Ranitidine showed the anti-AchE activity and increased duodenal HCO(3)(-) secretion, similar to nizatidine, whereas famotidine had any influence on neither AChE activity nor the HCO(3)(-) secretion. On the other hand, duodenal damage induced by acid perfusion (100 mM HCl for 4 h) in the presence of indomethacin was significantly prevented by nizatidine and neostigmine, at the doses that increased the HCO(3)(-) secretion. These results suggest that nizatidine increases HCO(3)(-) secretion in the rat duodenum, mediated by vagal-cholinergic mechanism, the action being associated with the anti-AChE activity of this agent.     

Morphofunctional stateof the cholinergic nervous apparatus of the normal duodenum and the duodenum after subdiaphragmatic vagotomy

Histochemical study of the intramural nervous apparatus of the duodenum was carried out under normal conditions and following bilateral subphrenic vagotomy. Morphometric and microspectrofluorimetric methods gave informations on the reduction of the number of the cholinergic nervous fibers and of the acetylcholinesterase activity in them after a brief increase of these indices during the first 24 hours after vagotomy, with their subsequent return to the initial values.     

Effect of preganglionic sympathectomy on the cholinesterase activity in the superior cervical ganglia of rats and hamsters

Summary By employing biochemical assay and histochemical enzyme techniques the effect of preganglionic sympathectomy on the cholinesterase (ChE) activity in the superior cervical ganglia of rats and hamsters was investigated. Biochemical assays indicate that the ChE activity in the superior cervical ganglia of adult rats and hamsters is 57.19 and 28.63 respectively (expressed in u moles acetylcholine hydrolyzed per min per g of tissue); two weeks after preganglionic denervation, about 50% and 60% of ChE activity are lost respectively. Histochemical enzyme examination reveals that in the rat superior cervical ganglion, the majority of the neurons are adrenergic with weak to moderate acetylcholinesterase (AChE) reaction and the minority of the neurons are cholinergic with strong AChE activity, while only one type of adrenergic neurons exhibits a weak AChE activity in the hamster superior cervical ganglion. The AChE activity is localized in the perinuclear area, in the cisternae of the rough surfaced endoplasmic reticulum, in the Golgi complex and on the plasma membrane of the hamster's neurons; it is mainly localized in the cisternae of the rough surfaced endoplasmic reticulum of the rat's neurons. AChE reaction product is also detected on the axolemmal membranes of the preganglionic nerve fibers in the sympathetic ganglia of rats and hamsters.After preganglionic sympathectomy, the AChE activity in the adrenergic neurons and in the preganglionic unmyelinated nerve fibers is markedly reduced, whereas the cholinergic neurons and preganglionic myelinated nerve fibers remain unchanged. On the basis of these results two conclusions have been reached: (1) The fact that strong AChE activity localized in the cholinergic neurons and preganglionic myelinated fibers is not influenced by denervation, suggests that these structures are able to produce AChE. (2) The reduction of AChE activity in the rat and hamster superior cervical ganglia two weeks after preganglionic denervation, observed by histochemical examination, can be correlated with a concomitant measurable reduction determined by biochemical assays.Supported in part by a grant from the National Science Council, Republic of China. The author wishes to express his gratitude to the Department of Pharmacology, College of Medicine, National Taiwan University, for the use of its equipment for biochemical assays     

Concurrent acetylcholinesterase staining and gamma-aminobutyric acid uptake of cortical neurons in culture

Gamma-aminobutyric acid (GABA) uptake and acetylcholinesterase (AChE) content were demonstrated concurrently in cortical neurons grown in tissue culture. Positive reactions either for GABA uptake or for AChE content were encountered in pyramidal and stellate, as well as spindle-shaped neurons. Neither reaction was confined to a specific morphological subtype. Nearly half the neurons were negative for either reaction. Most of the remaining neurons were positive only for GABA or only for AChE. However, a subpopulation of neurons showed not only a high AChE content, but also an avid GABA uptake. Thus, four types of neurons could be identified on the basis of these two reactions. The high AChE content in some of the cortical neurons that also showed GABA uptake indicates that there are at least two distinct types of GABAergic neurons.     

Ultrastructural localization of acetylcholinesterase

Summary A method is described allowing localization of acetylcholinesterase (AChE) by both light and electron microscopy. During the reaction lead thio-diacetyl is decomposed, and therefore precipitated as PbS in the presence of native-SH group produced by the hydrolysis of acetylthiocholine perchlorate. The reaction takes place at neutral pH, since improves the sensitivity of AChE localizations. Application of the method to parasympathetic neurons showed that AChE was mainly localized in the rough endoplasmic reticulum of the perikaryons. No reaction was visible in glial cells. AChE was also localized on the plasma membrane of parasympathetic neurons. In mouse embryo muscles AChE activity was seen to be high and was not yet restricted to the synaptic area. The well developed Schwann cells accompanying the neurites displayed constant AChE activity on their plasma membrane.Supported by a grant of INSERM C.R.L. N⁰ 79-5-318-6     

Acetylcholinesterase activity in antennal receptor neurons of the sphinx moth Manduca sexta

Summary We have used a cytochemical technique to investigate the distribution of acetylcholinesterase (AChE) activity in the antenna of the sphinx moth Manduca sexta. High levels of echothiophate-insensitive (presumably intracellular) AChE activity were found in six different types of antennal receptors localized in specific regions of the three antennal segments of the adult moth. Mechanosensory organs in the scape and pedicel, the Böhm bristles and Johnston's organ, are innervated by AChE-positive neurons. In each annulus of the antennal flagellum, AChE-positive neurons are associated with six sensilla chaetica and a peg organ, probably a sensillum styloconicum. At least 112 receptor neurons (8–10 per annulus) innervating the intersegmental membranes between the 14 distalmost annuli also exhibit high levels of echothiophate-resistant AChE. In addition, each annulus has more than 30 AChE-positive somata in the epidermis of the scale-covered (back) side of the flagellum, and 4 AChE-positive somata reside within the first annulus of the flagellum. Since none of the olfactory receptor neurons show a high level of echothiophateresistant AChE activity, and all known mechanoreceptors are AChE-positive, apparently intracellular AChE activity in the antenna correlates well with mechanosensory functions and is consistent with the idea that these cells employ acetylcholine as a neurotransmitter.     

大鼠肠道内NOS与AChE、VIP阳性神经元的分布关系研究

应用一氧化氮合酶 (NOS)、乙酰胆碱酯酶 (ACh E)组织化学及血管活性肠肽 (VIP)免疫组织化学方法 ,光镜下比较观察大鼠肠道内 NOS、ACh E、VIP阳性神经元的形态学特征。结果显示 ,肠肌间丛 NOS阳性神经元胞体大小不等 ,形态不一 ,NOS、ACh E和 VIP阳性神经元的分布密度为 ACh E>NOS>VIP,在不同的肠段和层次分布密度有差异 ,NOS与 ACh E存在共染。在肌间丛和粘膜下丛 ,少数 VIP与 NOS共染。在粘膜下丛 ,三种阳性神经元的分布密度为 ACh E>VIP>NOS。在肌间丛和粘膜下丛 ,可见 VIP阳性末梢环抱 NOS阳性神经元胞体 ,两者呈终扣样接触。上述结果提示 NOS阳性神经元与 ACh E、 VIP阳性神经元有密切的形态学联系。在消化道功能调节上 ,它们可能起协调作用。     

A comparison of tabun-inhibited rat brain acetylcholinesterase reactivation by three oximes (HI-6, obidoxime,and K048) in vivo detected by biochemical and histochemical techniques

Tabun belongs to the most toxic nerve agents. Its mechanism of action is based on acetylcholinesterase (AChE) inhibition at the peripheral and central nervous systems. Therapeutic countermeasures comprise administration of atropine with cholinesterase reactivators able to reactivate the inhibited enzyme. Reactivation of AChE is determined mostly biochemically without specification of different brain structures. Histochemical determination allows a fine search for different structures but is performed mostly without quantitative evaluation. In rats intoxicated with tabun and treated with a combination of atropine and HI-6, obidoxime, or new oxime K048, AChE activities in different brain structures were determined using biochemical and quantitative histochemical methods. Inhibition of AChE following untreated tabun intoxication was different in the various brain structures, having the highest degree in the frontal cortex and reticular formation and lowest in the basal ganglia and substantia nigra. Treatment resulted in an increase of AChE activity detected by both methods. The highest increase was observed in the frontal cortex. This reactivation was increased in the order HI-6 < K048 < obidoxime; however, this order was not uniform for all brain parts studied. A correlation between AChE activity detected by histochemical and biochemical methods was demonstrated. The results suggest that for the mechanism of action of the nerve agent tabun, reactivation in various parts of the brain is not of the same physiological importance. AChE activity in the pontomedullar area and frontal cortex seems to be the most important for the therapeutic effect of the reactivators. HI-6 was not a good reactivator for the treatment of tabun intoxication.     

A serum-free culture of the neurons in the septal, preoptic, and hypothalamic region. Effects of triiodothyronine and estradiol

Serial modifications of Bottenstein and Sato' serum-free hormone-supplemented medium resulted in a new promising medium (1 : 1 mixture of L15 and MCDB 104 containing several supplements) for culturing neonatal rat brain cells. This medium favored the morphological and biochemical differentiation of the neurons, including particular types of cholinergic and cholinoceptive neurons, obtained enzymatically from the septum, preoptic area, and hypothalamus. On the other hand, the growth of non-neuronal cells was markedly suppressed in this medium. Therefore, their effects on the neurons are minimized in this culture. Effects of triiodothyronine (T3) and estradiol (E2) on the activities of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE), synthetic and degradative enzymes for acetylcholine, respectively, were examined in this culture. The optimal concentrations of T3 and E2 for AChE activity were around 1 nM and 10 pM, respectively. However, E2 appeared to be somewhat inhibitory at higher concentrations. Although the activity of ChAT was maximum around 10 pM of E2, the ChAT activity increased as the concentration of T3 was increased to 100 nM.     

A comparison of tabun-inhibited rat brain acetylcholinesterase reactivation by three oximes (HI-6, obidoxime, and K048) in vivo detected by biochemical and histochemical techniques

Tabun belongs to the most toxic nerve agents. Its mechanism of action is based on acetylcholinesterase (AChE) inhibition at the peripheral and central nervous systems. Therapeutic countermeasures comprise administration of atropine with cholinesterase reactivators able to reactivate the inhibited enzyme. Reactivation of AChE is determined mostly biochemically without specification of different brain structures. Histochemical determination allows a fine search for different structures but is performed mostly without quantitative evaluation. In rats intoxicated with tabun and treated with a combination of atropine and HI-6, obidoxime, or new oxime K048, AChE activities in different brain structures were determined using biochemical and quantitative histochemical methods. Inhibition of AChE following untreated tabun intoxication was different in the various brain structures, having the highest degree in the frontal cortex and reticular formation and lowest in the basal ganglia and substantia nigra. Treatment resulted in an increase of AChE activity detected by both methods. The highest increase was observed in the frontal cortex. This reactivation was increased in the order HI-6 < K048 < obidoxime; however, this order was not uniform for all brain parts studied. A correlation between AChE activity detected by histochemical and biochemical methods was demonstrated. The results suggest that for the mechanism of action of the nerve agent tabun, reactivation in various parts of the brain is not of the same physiological importance. AChE activity in the pontomedullar area and frontal cortex seems to be the most important for the therapeutic effect of the reactivators. HI-6 was not a good reactivator for the treatment of tabun intoxication.     

CNS--endocrine pancreas system. III. Further studies on the vagal responsiveness to insulin deficiency

Distribution and activity of acetylcholinesterase (AChE) in the neurons of the central vagal nuclei at the level of the medulla oblongata were studied in intact and alloxan-diabetic adult male rats by Gomori's histochemical method. Peculiarities of intracellular distribution of the enzyme in the Nucl. dorsalis n. vagi (ND) and Nucl. ambiguus n. vagi (NA) of intact animals were demonstrated. Changes in the ratio of cholinergic neurons with moderate and strongly-positive AChE staining reactions were revealed in the ND of alloxan-diabetic rats. The dynamics of the changes attested to increased AChE activity of these neurons in response to insulin deficiency. The data obtained are additional evidence for the responsiveness of ND neurons to insulin deficiency, which was demonstrated earlier in alloxan-diabetic rats by karyometry (Akmayev and Rabkina, 1976 b). It is suggested that changes in the plasma glucose or insulin levels may be the stimulus that influences the activity of the ND cholinergic neurons. By means of this mechanism the central vagal nucleus at the medulla oblongata level may be implicated in the feedback control of insulin secretion.