Catecholamines in the sub-esophageal ganglia and the hemolymph of the giant African snail (Achatina fulica Férussac) determined by gas chromatography]

The content of three catecholamines (dopamine, L-norepinephrine and L-epinephrine) in the subesophageal ganglia and the hemolymph of Achatina fulica Férussac was measured by a gas chromatograph with electron capture detector. The dopamine content of the ganglia was 4.3 +/- 0.9 mug/g. L-Norepinephrine and L-epinephrine in the ganglia were not detected. The three catecholamines in the hemolymph were also not detected.     

Changes in the innervational connections of the urinary bladder upon experimental stimulation of the hypothalamus]

The innervation of the urinary bladder was studied in 40 rabbits, 5 of which were control and in 35 animals the posterior and anterior nuclei of the hypothalamus were stimulated by electric current through bipolar electrodes. The efferent innervation connections in whose terminal plexuses there occurred absorption of catecholamines were shown histochemically and neurohistologically to be involved in the pathological process. Reactive and degenerative changes were found to take place in receptory nerve terminations, and first of all in free ones. Then the bodies of pseudounipolar neurons of spinal ganglia were changed. Changes were also found in the connections of sensory neurons with the cells of Goll's and Burdach's nuclei.     

Catecholamines and catecholamine-synthesizing enzymes in guinea-pig sensory ganglia

Summary Cranial and spinal sensory ganglia of the guinea-pig were investigated by means of histochemistry and biochemistry for the presence of catecholamines and catecholamine-synthesizing enzymes. Sensory neurons exhibiting immunoreactivity to the rate-limiting enzyme of catecholamine synthesis, tyrosine nydroxylase (TH), were detected by immunohistochemistry in lumbo-sacral dorsal root ganglia, the nodose ganglion and the petrosal/jugular ganglion complex. The carotid body was identified as a target of TH-like-immunoreactive (TH-LI) neurons by the use of combined retrograde tracing and immunohistochemistry. Double-labelling immunofluorescence revealed that most TH-LI neurons also contained somatostatin-LI, but TH-LI did not coexist with either calcitonin gene-related peptide- or substance P-LI. TH-LI neurons did not react with antibodies to other enzymes involved in catecholamine synthesis, i.e., aromatic amino acid decarboxylase (AADC), dopamine--hydroxylase (DH), and phenylethanolamine-N-methyltransferase (PNMT). Petrosal neurons as well as their endings in the carotid body lacked dopamine- and L-DOPA-LI. Sensory neurons did not display glyoxylic acid-induced catecholamine fluorescence. Ganglia containing TH-LI neurons were kept in short-term organ culture after crushing their roots and the exiting nerve in order to enrich intra-axonal transmitter content at the ganglionic side of the crush. However, even under these conditions, catecholamine fluorescence was not detected in axons projecting peripherally or centrally from the ganglia. Sympathetic noradrenergic nerves entered the ganglia and terminated within them. Accordingly, biochemical analyses of guinea-pig sensory ganglia revealed noradrenaline but no dopamine. In conclusion, catecholamines within guinea-pig sensory ganglia are confined to sympathetic nerves, which fulfill presently unknown functions. The TH-LI neurons themselves, however, lack any additional sign of catecholamine synthesis, and the presence of enzymatically active TH within these neurons is questionable.     

Adrenal Medullary Transplants Increase Spinal Cord Cerebrospinal Fluid Catecholamine Levels and Reduce Pain Sensitivity

Previous work in this laboratory has shown that adrenal medullary transplants into the spinal cord subarachnoid space can reduce pain sensitivity. This analgesia most likely results from the release of neuroactive substances, particularly catecholamines and opioid peptides, from the transplanted cells into the CSF of the spinal cord, since it can be attenuated or blocked by alpha-adrenergic or opiate antagonists. The purpose of the present study was to more directly measure the release of catecholamines from adrenal medullary transplants in the spinal cord CSF using a spinal superfusion technique. CSF samples from rats with 6-month-old transplants were assayed for catecholamines using HPLC with electro-chemical detection. Results indicated that norepinephrine levels were increased threefold, and epinephrine levels nearly 100-fold, in animals with adrenal medullary transplants compared with control transplanted animals. There was no apparent increase in dopamine levels. Furthermore, the increased levels of total catecholamines were correlated with decreased pain sensitivity. Results of this study indicate that adrenal medullary transplants can survive for long periods in the rat spinal CSF and continue to release high levels of catecholamines. Together, the release of catecholamines and opioid peptides from adrenal medullary transplants may provide the ideal combination for the reduction of pain.     

Consecutive demonstration of catecholamines and dopamine-beta-hydroxylase within the same specimen.

A combined method was developed for characterization and differentiation of catecholamines in neuron populations containing more than one catecholamine, e.g. dopamine and norepinephrine. Its application to small intensely fluorescent (SIF-) cell clusters in sympathetic ganglia allows the successive demonstration of glyoxylic acid-induced catecholamine fluorescence and dopamine-beta-hydroxylase by indirect immunofluorescence within the same tissue section. Applying this technique to an example, two types of SIF-cells were demonstrated in the guinea pig superior cervical ganglion.     

Cyclic AMP content of autonomic ganglia as affected by catecholamines

The relative content of cAMP was measured in the rat ganglion nodosum, lumbar ganglia of the sympathetic trunk, the main pelvic ganglion and intramural ganglia of the heart. It was observed that the basal level of cAMP in the cardiac ganglia was lower than in other ganglia. The process of stimulation of the cAMP content by noradrenaline was most pronounced in the main pelvic and lumbar ganglia, that by dopamine in the cardiac ganglia. The catecholamines failed to alter the cAMP content in the ganglion nodosum.     

大鼠脊神经节内交感神经支配的荧光组织化学与HRP示踪观察

本研究应用乙醛酸诱发儿茶酚胺（ＣＡ）荧光技术观察大鼠肾上腺素（ＮＡ）能神经在脊神经节内的分布;并应用ＨＲＰ顺、逆行追踪技术对脊神经节内ＮＡ能神经纤维的起源及其与脊神经节神经元的关系进行了探讨。荧光组织化学观察发现、有些神经节神经元胞体周围分布有带膨体的ＮＡ能神经末梢;有的紧密围绕脊神经节细胞——卫星细胞复合体。颈上交感神经节内注射霍乱毒素Ｂ亚单位结合ＨＲＰ（ＣＢ┐ＨＲＰ）,在同侧Ｃ３～６节段脊神经节内可见标记的点状纤维末梢紧邻于节细胞旁。Ｔ１１～Ｌ２节段脊神经节内注射ＨＲＰ后,在同侧椎旁交感链（Ｔ９～Ｌ１）内可见标记的交感节后神经元胞体。上述实验结果表明,交感节后神经元发出节后纤维可直接到达脊神经节内,与节细胞发生接触。本研究提示、交感神经在脊神经节水平可能参与躯体初级传入信息的调制     

眼镜蛇毒对大鼠脊髓和脊神经节一氧化氮合酶表达的影响

目的 观察眼镜蛇毒对脊髓和脊神经节一氧化氮合酶(NOS)表达的影响。方法 将眼镜蛇毒注入大鼠右侧大腿后部,采用还原型尼克酰胺嘌呤二核苷酸脱氢酶(NADPH．d)法显示NOS的表达。结果 在眼镜蛇毒注射组,脊髓和脊神经节内的NOS阳性神经元和深染NOS阳性神经元明显多于注入生理盐水组和正常对照组。结论 注入眼镜蛇毒能上调大鼠脊髓和脊神经节NOS表达。     

Microfluorimetric quantitation of catecholamine turnover in the sympathetic neurons of rat

Summary The quantitative aspects of the formaldehydeinduced fluorescence and the turnover of catecholamines in the sympathetic neuronal perikaryon of different sympathetic ganglia were studied after a blockade of the amine synthesis with -methyltyrosine. The concentration of catecholamines was determined by microfluorimetric quantitation method. The half-life of catecholamines in sympathetic neuronal perikarya was short and depended on the ganglion studied. The turnover rate of catecholamines in sympathetic neurons was highest in superior cervical and lowest in coeliac ganglion. Brightly fluorescent fibers were still seen five hours after the amine synthesis blockade, whereas almost all cell bodies had lost their fluorescence. Also small intensely fluorescent cells were still brightly fluorescent after the follow-up period. Microfluorimetrically determined turnover of catecholamines gave more detailed information about the turnover of catecholamines in sympathetic nervous system when compared to the biochemical methods used earlier.     

Increase in rat brain acetylcholine induced by choline or deanol.

Total catecholamines, norepinephrine and small amounts of dopamine were measured in the spinal cord of rats by sensitive radiometric enzymatic assays. There was a considerable disparity between levels of NE and those of total CA suggesting the presence of significant amounts of another catecholamine in spinal cord. The demonstration of the presence of specific phenylethanolamine-N-methyl transferase activity in spinal cord suggested that the catecholamine could be epinephrine. The presence of epinephrine in spinal cord was confirmed by quantitative mass fragmentography. Pretreatment with intracisternal and intracerebroventricular 6-hydroxydopamine markedly reduced the contents of total catecholamines, no norepinephrine and dopamine-β-hydroxylase activity when compared to vehicle treated controls. In contrast, the levels of dopamine only fell to 50% of controls after 6-hydroxydopamine. Thus, in addition to descending noradrenergic tracts, adrenergic neurons appear to be present in the spinal cord.     

DEVELOPMENTAL CHANGES OF CHOLINESTERASES AND MONOAMINE OXIDASE IN CHICK EMBRYO SPINAL AND SYMPATHETIC GANGLIA

Abstract— Total cholinesterase, acetylcholinesterase, (AChE) and monoamine oxidase (MAO) activity and protein content were determined throughout the embryonic life of the chick in spinal and sympathetic ganglia. The greatest part of total cholinesterase activity was due to AChE.
AChE and MAO activity increased in both spinal and sympathetic ganglia very similarly from the 6th to the 12th day of incubation; from this day on a significant divergence occurred, mainly owing to a steady fall in spinal ganglion AChE, which decreased to approximately one tenth of the maximum value. The ratio of MAO activity in sympathetic and spinal ganglia increased from the 8th day onwards and approached 5·0 at hatching. The ratio between sympathetic and spinal ganglia, for AChE, choline acetylase (ChAc) and MAO activity, suggests a relationship between the maturation of the synapse in the sympathetic ganglia and the maximal activity of these enzymes.     

β2-Adrenoreceptor immunoreactivity in cardiac ganglia of the guinea pig

Summary Previous pharmacological studies in co-culture systems have indicated, the presence of β-adrenoreceptors on intrinsic cardiac neurons of the guinea pig (Horackovaet al., 1993) but radiologand binding studies of tissue sections failed to provide a definite answer as to the presence of such receptors on cardiac neuronsin situ, due to the iodine-binding properties of cardiac nerve bundles and ganglia (Molenaaret al., 1992). We therefore addressed this question by immunohistochemistry, using antisera raised against synthetic peptides of the β2-adrenoreceptor. For comparison, cholinergic and catecholaminergic neurons were identified immunohistochemically by means of antibodies against the enzymes involved in the synthesis of acetylcholine (choline acetyltransferase), and of catecholamines (tyrosine hydroxylase). Virtually all intrinsic cardiac neurons contained both β2-adrenoreceptor- and choline acetyltransferase-immunoreactivities. In addition, some nerve fibre bundles exhibited β2-adrenoreceptor-immunoreactivity. Several ganglia were innervated by tyrosine hydroxylase-immunoreactive axons, but the majority of ganglia did not receive tyrosine hydroxylase-immunoreactive nerve terminals, and additional intraganglionic sources of catecholamine synthesis could not be identified. Thus, the results are in favour of β-adrenergic modulation of guinea pig cardiac ganglia by humorally and, partially, by locally released catecholamines.     

Adrenergic innervation of the extramedullary arteries of the spinal cord of cats]

The adrenergic nerves of the radical and longitudinal arteries and the dura mater at the level of cervical, thoracic and lumbar segments of the ventral and dorsal sides of the spinal cord were studied in 70 mature cats by methods of Falck and Glenner. The adrenergic fibres form developed plexuses different in the density of disposition of nerve conductors on the arteries of different segments of the spinal cord. The adrenergic fibres are also found in the pia mater tissue. Nerve fibres containing active monoaminoxidase are less in number than adrenergic ones found by Falck's method. It is probably due to activation of catecholamines being realized by other ways in addition to oxydative desamination.     

An analysis of dorsal root ganglia differentiation using three tissue culture systems

Summary The histogenesis of the dorsal root ganglia of chick embryos (ages 3 to 9 days) was followed in three different tissue culture systems. Organotypic explants included dorsal root ganglia connected to the lumbosacral segment of the spinal cord or isolated explants of the contralateral ganglia. Additionally, dissociated monolayer cultures of ganglia tissue were established. The gradual differentiation of progenitor neuroblasts into distinct populations of large ventrolateral and small dorsomedial neurons was observed in vivo and in vitro. Neurites developed after 3 days in the presence or absence of nerve growth factor in the medium. In contrast, autoradiographic analysis indicates that [³H]thymidine incorporation in neuronal cultures differed significantly from intact embryos. In vivo, the number of neuronal progenitor cells labeled with [³H]thymidine decreased in older embryos; in vitro, uptake of [³H]thymidine label was not observed in ganglionic progenitor cells regardless of the age of the donor embryo or the type of culture system. Lack of proliferation in ganglionic progenitor cells was not due to degeneration because vital staining and uptake of [³H]deoxyglucose indicated that neurons were metabolically active. Furthermore, the block in mitotic activity in vitro was limited to presumptive ganglionic neuronal cells. In the ependyma of the spinal cord segment connected to the dorsal root ganglia, neuronal progenitor cells were heavily labeled as were non-neuronal cells within both spinal cord and ganglia. Our results suggest that in vitro conditions can promote the differentiation of sensory neurons from early embryos (E3.5–4.5) without proliferation of progenitor cells.     

Demonstration of sensory-motor innervation of postmetamorphic forelimb regenerates of Triturus alpestris (Urodela) on cryotome serial sections using horseradish peroxidase

A method has been developed to obtain horseradish peroxidase-treated serial sections containing spinal cord as well as bilateral ventral and dorsal roots, dorsal root ganglia and spinal nerves. Young postmetamorphic newts (Triturus alpestris) served as experimental animals. After cryotome cross sectioning the forelimb region of the trunk, slices 80 microns in thickness were mounted serially with up to 15 sections per slide. This facilitated subsequent staining manipulations and made partial loss of sections less likely.     

Fluorescence microscopic observations of catecholamines in cultures of the sympathetic chains

Summary A histochemical technique for the demonstration of catecholamines developed by Falck et al. has been successfully applied to the sympathetic chains of rats and mice maintained in vitro. Catecholamines were localized in the nerve fibers, showing identical green fluorescence as in tissue sections of healthy rats. The cultures 8 days in vitro exhibited positive reaction in a few terminals, whereas sister cultures 1 month in vitro showed strong fluorescence reaction in thicker proximal axons and networks of nerve fibers as well. Reactivity of neuron somas became positive after 1 month of cultivation. Application of reserpine in amount of 0.00025 mg/ml for 2 hours resulted in complete disappearance of fluorescence. Furthermore, cultures of spinal ganglia from fetal rat produced no fluorescence reaction with this technique. Therefore, the reaction is specific for sympathetic nervous tissue and reliable for the differentiation of sympathetic neurons from other types of nerve cells.This work was supported by research grant NBO 3173 from the National Institute of Neurological Diseases and Blindness, U.S. Public Health Service, and research grant No. 355 from the National Multiple Sclerosis Society, New York.     

Sensory innervation of the canine esophagus, stomach, and duodenum.

The sensory innervation of the postpharyngeal foregut was investigated by injecting the enzyme horseradish peroxidase (HRP) into the walls of the esophagus, stomach, or duodenum. The transported HRP was identified histochemically, labeled neurons in the spinal and vagal ganglia were counted, and the results were plotted using an SAS statistical program. The spinal sensory fields of each viscus were defined using three determinations: craniocaudal extent, principal innervation field, and peak innervation field. The data revealed that innervation fields are craniocaudally extensive, the sensory field of each viscus overlaps significantly with its neighbor, yet each viscus can be characterized by a field of peak innervation density. Craniocaudal innervation of the esophagus spans as many as 22-23 paired spinal ganglia (C1-L2). There are two peak innervation fields for the cervical (C2-C6 and T2-T4) and for the thoracic (T2-T4 and T8-T12) sectors of the esophagus. The sensory innervation of the stomach extends craniocaudally over as many as 25 paired spinal ganglia (C2-L5). The peak innervation field of the stomach spans a large area comprising the cranial, middle, and the immediately adjoining caudal thoracic ganglia (T2-T10). The duodenum is innervated craniocaudally by as many as 15 paired thoracolumbar ganglia (T2-L3). Peak innervation originates in the middle and caudal thoracic ganglia and cranial lumbar (T6-L1) ganglia. There is a recognizable viscerotopic organization in the sensory innervation of the postpharyngeal foregut; successively more caudal sectors of this region of the alimentary canal are supplied with sensory fibers from successively more caudal spinal dorsal root ganglia. Vagal afferent innervation of the esophagus, stomach, and duodenum is bilateral and originates predominantly, but not exclusively, from vast numbers of neurons in the nodose (distal) ganglia. The esophagus is innervated bilaterally and more abundantly by jugular (proximal) ganglia neurons than is either the stomach or duodenum. The physiological significance of the findings are discussed in relation to the phenomena of visceral pain and referred pain.     

Identification of Different Types of Spinal Afferent Nerve Endings That Encode Noxious and Innocuous Stimuli in the Large Intestine Using a Novel Anterograde Tracing Technique

In mammals, sensory stimuli in visceral organs, including those that underlie pain perception, are detected by spinal afferent neurons, whose cell bodies lie in dorsal root ganglia (DRG). One of the major challenges in visceral organs has been how to identify the different types of nerve endings of spinal afferents that transduce sensory stimuli into action potentials. The reason why spinal afferent nerve endings have been so challenging to identify is because no techniques have been available, until now, that can selectively label only spinal afferents, in high resolution. We have utilized an anterograde tracing technique, recently developed in our laboratory, which facilitates selective labeling of only spinal afferent axons and their nerve endings in visceral organs. Mice were anesthetized, lumbosacral DRGs surgically exposed, then injected with dextran-amine. Seven days post-surgery, the large intestine was removed. The characteristics of thirteen types of spinal afferent nerve endings were identified in detail. The greatest proportion of nerve endings was in submucosa (32%), circular muscle (25%) and myenteric ganglia (22%). Two morphologically distinct classes innervated myenteric ganglia. These were most commonly a novel class of intraganglionic varicose endings (IGVEs) and occasionally rectal intraganglionic laminar endings (rIGLEs). Three distinct classes of varicose nerve endings were found to innervate the submucosa and circular muscle, while one class innervated internodal strands, blood vessels, crypts of lieberkuhn, the mucosa and the longitudinal muscle. Distinct populations of sensory endings were CGRP-positive. We present the first complete characterization of the different types of spinal afferent nerve endings in a mammalian visceral organ. The findings reveal an unexpectedly complex array of different types of primary afferent endings that innervate specific layers of the large intestine. Some of the novel classes of nerve endings identified must underlie the transduction of noxious and/or innocuous stimuli from the large intestine.     

Immunohistochemistry and Biosynthesis of N-Acetylaspartylglutamate in Spinal Sensory Ganglia

N-Acetylaspartylglutamate (NAAG) is a nervous system-specific dipeptide which has been implicated in chemical neurotransmission. Antisera were prepared against NAAG in order to study its cellular distribution. When these antisera were applied to tissue sections of rat spinal sensory ganglia, NAAG-like immunoreactivity was detected within a subpopulation of relatively large neuronal cell bodies in cervical, lumbar, and thoracic ganglia. In order to confirm the presence of NAAG within these neurons, the dipeptide was extracted and purified from spinal ganglia using high-performance liquid chromatography and its composition confirmed by amino acid analysis. Further, the biosynthesis of NAAG was studied in vitro by following the incorporation of either [3H]glutamine or [3H]glutamate into the glutamate residue of the purified dipeptide. [3H]Aspartate was not incorporated efficiently into NAAG under these conditions, suggesting a precursor role for the large N-acetylaspartate pool. The incorporation of radiolabeled amino acids into newly synthesized NAAG by spinal sensory ganglia was not inhibited by incubation of the cells with anisomycin or cycloheximide at concentrations which significantly inhibited protein synthesis. These data suggest that NAAG is present in a subpopulation of primary afferent spinal neurons and that its biosynthesis is mediated by a dipeptide synthetase.     

Cosinor analysis of the circadian dynamics of transcription in populations of neurocytes from a number of sections of the rat nervous system

Diurnal fluctuations of endogenous RNA polymerases activity were studied in the cell nucleus of the cerebral stem and spinal nervous system populations (neurocytes of the hypothalamic suprachiasmatic nuclei, superior cervical ganglia, spinal ganglia L5, motoneurones of the spinal cord and Purkinje cells) were revealed. The acrophases of the visual cortex neurones were observed just before light reception.