Striatal neurons with aromatic L-amino acid decarboxylase-like immunoreactivity in the rat

We found in the adult rat that a small number of striatal neurons showed aromatic L-amino acid-like immunoreactivity. These neurons had a cell body with 10-20 microns diameter and several spiny dendrites, and were distributed throughout the striatum (the caudate nucleus and putamen) without any particular topography. The number of these neurons was increased on the side ipsilateral to an electrothermic or 6-hydroxydopamine-induced lesion which had been placed in the midbrain regions around the substantia nigra pars compacta.     

Effect of pyridoxine deficiency on aromatic L-amino acid decarboxylase in adult rat brain

Summary We have investigated the effect of pyridoxine deficiency on aromatic L-amino acid decarboxylase (AADC) using both dihydroxyphenylalanine (DOPA) and 5-hydroxytryptophan (5HTP) as substrates in the rat brain. The activity ratios of DOPA decarboxylase/5HTP decarboxylase measured under optimal substrate and cofactor concentrations were different in the cerebellum, cerebral cortex, corpus striatum and hypothalamus of the normal rat. In pyridoxine deficiency, there were no parallel decreases in DOPA and 5HTP decarboxylase activities in various brain regions. Dialysis of brain homogenates, in the presence and absence of hydroxylamine, resulted in a total or near total loss of 5HTP decarboxylase activity compared to DOPA decarboxylase activity, indicating that pyridoxal phosphate may be more tightly bound to DOPA decarboxylase than to 5HTP decarboxylase. These results, indicating that pyridoxine deficiency has differential effects on the activity of AADC, are consistent with our earlier observation of non-parallel changes in dopamine and serotonin content in various brain regions of the pyridoxine-deficient rat.     

Development of tyrosine hydroxylase-, dopamine- and dopamine β-hydroxylase-immunoreactive neurons in a teleost, the three-spined stickleback

The development of catecholaminergic neuronal systems in the brain of a teleost, the three-spined stickleback, was studied through embryonic to early larval stages by immunocytochemistry using specific antibodies against dopamine, tyrosine hydroxylase and dopamine β-hydroxylase. By analysing the spatiotemporal patterns of development for the catecholaminergic nuclei, possible homologies with nuclei in amniote brains have been identified.

The noradrenergic neurons in the isthmus region of the rostral rhombencephalon originate in the same manner as the A4–A7 + subcoeruleus group in mammals. Their developmental characteristics show the largest similarities with the subcoeruleus group of birds and mammals, although some features are shared with developing A6 (locus coeruleus) neurons.

Catecholaminergic neurons never appear during development in the ventral mesencephalon of the three-spined stickleback. A group of large dopaminergic neurons that accompany the cerebrospinal fluid (CSF)-contacting neurons follows the border between the hypothalamus and the ventral thalamus into the caudal hypothalamus, where they are continuous with the dopaminergic neurons in the posterior tuberculum. They are thus topologically comparable with the dopaminergic neurons of the zona incerta in mammals.

The dopaminergic CSF-contacting neurons that line the median, lateral and posterior recesses of the third ventricle do not contain tyrosine hydroxylase-immunoreactivity at any developmental stage. This indicates that they take up and accumulate exogenous dopamine or -dihydroxyphenylalanine, and do not synthesize dopamine from tyrosine at any developmental stage. Tyrosine hydroxylase-immunoreactive neurons appear in the pineal organ on the day of hatching (120 h post-fertilization). They were still observed in 240-h-old larvae, but are absent in the pineal organ of adult sticklebacks.

The initial appearance and subsequent differentiation of catecholaminergic neurons in the stickle-back embryo follow essentially the same spatial and temporal pattern as in amphibian, avian and mammalian embryos. This observation supports the hypothesis that morphologically, topologically and chemically similar monoaminergic neurons in different vertebrate classes are homologous.     

Striatal cells containing aromatic L-amino acid decarboxylase: an immunohistochemical comparison with other classes of striatal neurons

In a previous study, we described a population of striatal cells in the rat brain containing aromatic L-amino acid decarboxylase, the enzyme involved in the conversion of L-DOPA into dopamine. We have also presented evidence that these cells produce dopamine in the presence of exogenous L-DOPA. In this paper, we further characterize these striatal aromatic L-amino acid decarboxylase-containing cells in order to determine whether they form a subclass of one of the known categories of striatal neurons or if they represent a novel cell type. Using immunohistochemical methods, we compared the morphology and distribution of the aromatic L-amino acid decarboxylase-immunolabeled cells with those of other classes of striatal neurons. Our results show that both the morphology and distribution of aromatic L-amino acid decarboxylase-immunolabeled cells are very distinctive and do not resemble those of cells labeled for other striatal neuronal markers. Double-labeling procedures revealed that aromatic L-amino acid decarboxylase cells do not co-localize somatostatin or parvalbumin, and only a very small percentage of them co-localize calretinin. However, the population of aromatic L-amino acid decarboxylase cells label intensely for GABA.Overall, our results suggest that these aromatic L-amino acid decarboxylase-containing cells represent a class of striatal GABAergic neurons not described previously.     

Tyrosine hydroxylase- and/or aromatic l-amino acid decarboxylase-containing cells in the suprachiasmatic nucleus of the Syrian hamster (Mesocricetus auratus)

Catecholamines, including dopamine (DA), affect the activity of cells in the suprachiasmatic nucleus (SCN) of the hypothalamus, the principal circadian clock in mammals. This study examined the distribution of dopaminergic cells in the SCN of the male Syrian hamster, using both single- and double-label immunocytochemistry for tyrosine hydroxylase (TH), the rate-limiting enzyme in DA synthesis and for aromatic

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-amino acid decarboxylase (AADC), the second enzyme needed to produce DA. Some neurons immunopositive for TH (TH+) were found in the SCN, but most of the TH+ cells of the region were located just outside the borders of the nucleus, as defined by pyronin Y staining. In the SCN, 91% of these cells were also immunopositive for AADC and thus, likely to be dopaminergic. Cells positive for AADC, many of which were not TH+, were found throughout the SCN, with the highest concentration seen in the ventral aspects of the nucleus. Cells containing AADC, but lacking TH may synthesize products other than DA, such as trace amines. These anatomical observations suggest that local neurons that produce DA and perhaps trace amines, may play a role in SCN function and in the neural control of circadian rhythms.     

Circadian rhythm of aromatic L-amino acid decarboxylase in the rat suprachiasmatic nucleus: gene expression and decarboxylating activity in clock oscillating cells

BACKGROUND: Aromatic L-amino acid decarboxylase (AADC) is the enzyme responsible for the decarboxylation step in both the catecholamine and indoleamine synthetic pathways. In the brain, however, a group of AADC containing neurones is found outside the classical monoaminergic cell groups. Since such non-monoaminergic AADC is expressed abundantly in the suprachiasmatic nucleus (SCN), the mammalian circadian centre, we characterized the role of AADC in circadian oscillation. RESULTS: AADC gene expression was observed in neurones of the dorsomedial subdivision of the SCN and its dorsal continuant in the anterior hypothalamic area. These AADC neurones could uptake exogenously applied L-DOPA and formed dopamine. AADC was co-expressed with vasopressin and the clock gene Per1 in the neurones of the SCN. Circadian gene expression of AADC was observed with a peak at subjective day and a trough at subjective night. The circadian rhythm of AADC enzyme activity in the SCN reflects the expression of the gene. CONCLUSIONS: Non-monoaminergic AADC in the SCN is expressed in clock oscillating cells, and the decarboxylating activity of master clock cells are under the control of the circadian rhythm.     

Comparative topography of dopamine- and tyrosine hydroxylase-immunoreactive neurons in the rat arcuate nucleus

The distribution of dopamine (DA)-immunoreactive (IR) cells is described in the rat arcuate nucleus of the hypothalamus and its adjacent areas and compared with that of tyrosine hydroxylase (TH)-IR cells. Small DA-IR cells were seen to be aggregated mainly in the dorsomedial part of the nucleus, but were hardly detectable in its ventrolateral portion and neighbouring periarcuate region which showed many larger TH-IR cells. This study reveals, for the first time, the differences in the respective topography of those neurons which actually contain detectable DA and those which contain TH, the initial synthesizing enzyme of catecholamine.     

L-amino acid decarboxylase- and tyrosine hydroxylase-immunoreactive cells in the extended olfactory amygdala and elsewhere in the adult prairie vole brain

Neurons synthesizing dopamine (DA) are widely distributed in the brain and implicated in a tremendous number of physiological and behavioral functions, including socioreproductive behaviors in rodents. We have recently been investigating the possible involvement of sex- and species-specific TH-immunoreactive (TH-ir) cells in the male prairie vole (Microtus ochrogaster) principal bed nucleus of the stria terminalis (pBST) and posterodorsal medial amygdala (MeApd) in the chemosensory control of their monogamous pairbonding and parenting behaviors. These TH-ir cells are not immunoreactive for dopamine-beta-hydroxylase (DBH), suggesting they are not noradrenergic but possibly DAergic. A DAergic phenotype would require them to contain aromatic L-amino acid decarboxylase (AADC) and here we examined the existence of cells immunoreactive for both TH and AADC in the pBST and MeApd of adult virgin male and female prairie voles. We also investigated the presence of TH/AADC cells in the anteroventral periventricular nucleus (AVPV), medial preoptic area (MPO), arcuate nucleus (ARH), zona incerta (ZI), substantia nigra (SN) and ventral tegmental area (VTA). Among our findings were: (1) the pBST and MeApd each contained completely non-overlapping distributions of TH-ir and AADC-ir cells, (2) the AVPV contained surprisingly few AADC-ir cells and almost no TH-ir cells contained AADC-ir, (3) approximately 60% of the TH-ir cells in the MPO, ARH, and ZI also contained AADC-ir, (4) unexpectedly, only about half of TH-ir cells in the SN and VTA contained AADC-ir, and (5) notable populations of AADC-ir cells were found outside traditional monoamine-synthesizing regions, including some sites that do not contain AADC-ir cells in adult laboratory rats or cats (medial septum and cerebral cortex). In the absence of the chemical requirements to produce DA, monoenzymatic TH-ir cells in the virgin adult prairie vole pBST, MeApd, and elsewhere in their brain may instead produce L-DOPA as an end product and use it as a neurotransmitter or neuromodulator, similar to what has been observed for monoenzymatic TH-synthesizing cells in the laboratory rat brain.     

Effect of metals and phenylalanine on the activity of human tryptophan hydroxylase-2: comparison with that on tyrosine hydroxylase activity

We cloned the human tryptophan hydroxylase-2 (hTPH2) gene by RT-PCR, and expressed and purified its product as a maltose-binding protein (MBP)-fusion protein. We investigated the effects of essential divalent cations and L-phenylalanine (L-Phe) on the hTPH2 activity for the first time, and compared them with those on human tyrosine hydroxylase (hTH1) activity. We found that cobaltous and manganous ions inhibited the activities of both enzymes but that hTH1 was affected at lower concentrations than hTPH2. From kinetic analyses, we found that phenylalanine acted as an inhibitor more strongly against hTPH2 than against hTH1. These data are important for elucidating the molecular mechanism underlying the alterations in the contents of serotonin and catecholamines in the brain under pathological and physiological conditions, such as hyperphenylalaninemia and chronic manganese toxicity.     

Comparison between the L-DOPA histofluorescence procedure and the indirect immunofluorescence with anti-T6 and -HLA-DR monoclonal antibodies in visualizing Langerhans cells of human epidermis

In order to assess the reliability of the L-DOPA histofluorescence (HF) procedure in visualizing the Langerhans cells (LC) of human epidermis, serial sections of human normal skin samples have been incubated with L-DOPA and alternatively processed for the L-DOPA HF and the indirect IF with anti-T6 and anti-HLA-DR monoclonal antibodies. Results demonstrated a good correlation of LC labelling; comparison between the number of L-DOPA positive (T6 positive and L-DOPA positive) HLA-DR positive dendritic cells did not show statistically significant differences. Therefore, the L-DOPA HF represents a valuable method for detecting LC in the human normal epidermis.     

Distribution of tyrosine hydroxylase- and serotonin-immunoreactive cells in the central nervous system of the thornback guitarfish, Platyrhinoidis triseriata

Brainstem reticular nuclei of amniotes (mammals, birds and reptiles) may share a common phylogenetic origin as demonstrated by their many shared features (hodology, cytoarchitectonics, presence of neurochemicals). By studying characteristics of these nuclei in outgroups of amniotes, we hope to obtain clues about the phylogeny of the reticular formation. In this paper we report the distribution of immunoreactivity to tyrosine hydroxylase (TH) and serotonin (5-HT) in the brain of an elasmobranch, the thornback guitarfish, Platyrhinoidis triseriata. Our working hypothesis is that if morphologically and immunohistochemically similar cell groups are present, they are homologous to cell groups in amniotes. Thus we have used mammalian terminology. The dorsal and lateral pallium of the telencephalon and many diencephalic nuclei contained TH+ cells. In the mesencephalon, TH+ cell groups were located in raphe linearis, the ventral tegmentum and substantia nigra. The rhombencephalon contained TH+ cells in a putative locus coeruleus (A6), and a subcoeruleus group. Probable A5, A2/C2 and A1/C1 groups were also located. A few 5-HT+ cells were located in the telencephalon and many were found in the diencephalon. In the mesencephalon, 5-HT+ cells were located in the nucleus reticularis pedunculopontinus pars dissipatus (B9). Metencephalic cells were found in reticularis pontis oralis lateralis and medialis, the reticulotegmental nucleus, nucleus centralis superior (B8), reticularis magnocellularis and reticularis pontis caudalis. In the myelencephalon, 5-HT+ cells were contained in raphe pallidus, reticularis paragigantocellularis lateralis and reticularis ventralis pars alpha. The cell shapes, locations, and neurochemical content of Platyrhinoidis reticular groups were very similar to those of amniotes. This elasmobranch has most of the 5-HT+ and TH+ cell groups found in mammals with the major exception that no 5-HT+ cells were in a nucleus which might correspond to raphe dorsalis.     

System L-amino acid transporters are differently expressed in rat astrocyte and C6 glioma cells

The system L-amino acid transporter is a major nutrient transport system that is responsible for Na+-independent transport of neutral amino acids including several essential amino acids. We have compared and examined the expressions and functions of the system L-amino acid transporters in both rat astrocyte cultures and C6 glioma cells. The rat astrocyte cultures expressed the l-type amino acid transporter 2 (LAT2) with its subunit 4F2hc, whereas the l-type amino acid transporter 1 (LAT1) was not expressed in these cells. The C6 glioma cells expressed LAT1 but not LAT2 with 4F2hc. The [14C]l-leucine uptakes by the rat astrocyte cultures and C6 glioma cells were Na+-independent and were completely inhibited by the system l selective inhibitor, BCH. These results suggest that the transport of neutral amino acids including several essential amino acids into rat astrocyte cultures and C6 glioma cells are for the most part mediated by LAT2 and LAT1, respectively. Therefore, the rat astrocyte cultures and C6 glioma cells are excellent tools for examining the properties of LAT2 and LAT1, respectively. Moreover, the specific inhibition of LAT1 in cancer cells might be a new rationale for anti-cancer therapy.     

Dual effects of L-3,4-dihydroxyphenylalanine on aromatic L-amino acid decarboxylase, dopamine release and motor stimulation in the reserpine-treated rat: evidence that behaviour is dopamine independent

The comparative effects of L-3,4-dihydroxphenylalanine (L-DOPA) on dopamine synthesis, release and behaviour were studied in the reserpine-treated rat. Acute administration of L-DOPA (25-200 mg/kg) dose-dependently inhibited the activity of aromatic L-amino acid decarboxylase (AADC) in the substantia nigra and corpus striatum. The antiparkinsonian drugs budipine (10 mg/kg) and amantadine (40 mg/kg) enhanced AADC activity in these regions, and prevented or reversed AADC inhibition by L-DOPA. Dual probe dialysis revealed that low doses of L-DOPA (25-50 mg/kg) dose-dependently stimulated the release of dopamine and 3,4-dihydroxyphenylacetic acid (DOPAC) in nigra and striatum, whilst high doses of L-DOPA (100-200 mg/kg) completely suppressed the release of dopamine, but not DOPAC. Sulpiride (50 microM) administered via the probes antagonized dopamine release in response to 25 mg/kg L-DOPA, but greatly facilitated release by 200 mg/kg L-DOPA. Dopamine release was blocked by the centrally acting AADC inhibitor NSD 1015, but facilitated by the central AADC activator budipine. In behavioural tests L-DOPA (plus benserazide, 50 mg/kg) only reversed akinesia at 200 mg/kg, and not at 25-100 mg/kg. Pretreatment with either NSD 1015 (100 mg/kg) or budipine (10 mg/kg) markedly potentiated the motor stimulant action of a threshold dose of L-DOPA (100 mg/kg). A combination of NSD 1015 (100 mg/kg) and benserazide (50 mg/kg) potentiated L-DOPA behaviour more effectively than either inhibitor alone. NSD 1015-facilitated L-DOPA behaviour was antagonized by sulpiride (100 mg/kg) and not by SCH 23390 (1 mg/kg), whereas budipine-facilitated L-DOPA behaviour was fully antagonized by SCH 23390 and only partially by sulpiride. These results show that behaviourally active doses of L-DOPA in the reserpinized rat are not accompanied by significant increases in extracellular dopamine and are therefore probably not dopamine mediated. We propose that L-DOPA is capable of directly stimulating dopamine D2 and possibly non-dopamine receptors, thereby inhibiting dopamine efflux presynaptically and promoting motor activation postsynaptically. A stimulant action of L-DOPA on motor behaviour, preferentially mediated by D1 > D2 receptors, suggests that L-DOPA may also be capable of yielding a dopamine-like response in the absence of detectable dopamine release. These findings are incorporated into a new model of L-DOPA's actions in the reserpinized rat, and their possible implications for our understanding of L-DOPA in Parkinson's disease are discussed.     

Topographic relations between tyrosine hydroxylase- and luteinizing hormone-releasing hormone-immunoreactive fibers in the median eminence of adult rats

Employing electron microscopic double immunolabeling, we determined a close apposition of tyrosine hydroxylase (TH) and luteinizing hormone-releasing hormone (LHRH) nerve fibers in the rat median eminence (ME). These axo-axonic contacts occurred frequently in the internal and palisade zones, i.e. at the level of the fiber preterminals. In the superficial area of the ME, major TH fibers abutted on the basal lamina and some were projected into the pericapillary space of the portal vessels. Conversely, LHRH fibers were arrested by the endfeet of tanycytes in reaching the basal lamina.     

Aromatic L-amino acid decarboxylase in the rat brain: immunocytochemical localization during prenatal development

Immunocytochemically labeled cells containing the enzyme aromatic L-amino acid decarboxylase were localized in the brain of rat embryos at gestational age E15-E19. Cell groups that contained aromatic L-amino acid decarboxylase but lacked either the enzyme tyrosine hydroxylase or the indolamine serotonin were referred to as "D" groups. Anatomical landmarks, cytoarchitectonic structure and histochemical staining for acetylcholinesterase were used to delineate the position of "D" groups. In the E15 embryo three "D" groups existed. The first to appear, named D1, was located in the spinal cord and had been demonstrated before. A large "D" cell cluster was found in the walls of the central forebrain deep to the hypothalamic sulcus. This group distributed dorsally in the ventral dorsal thalamic region and ventrally in the dorsal hypothalamus. The rostral-most "D" group, D14, occurred in the ventral telencephalon just medial to fibers of the nigrostriatal projection. D14 was the smallest of the early groups. In E16 and E17 embryos dorsal di- and mesencephalic "D" groups were first detected. During the course of ontogeny a considerable increase of immunoreactive cells occurred and segregation of the large central forebrain cluster into several rostrally and laterally distributed "D" groups took place. Some "D" groups that occur in the adult brain were not present in the E19 embryo. This study provides a first report of the localization of several unique cell groups in the brain of rat embryos and their appearance at different stages of gestation. It also gives further support to the notion that variations of aromatic L-amino acid decarboxylase staining intensities may be characteristic of different monoamine neurons.     

Aromatic l-amino acid decarboxylase- and tyrosine hydroxylase- immunohistochemistry in the adult human hypothalamus

The distribution of cell bodies immunoreactive for tyrosine hydroxylase and aromatic l-amino acid decarboxylase was studied in the adult human hypothalamus. Many neurons in the posterior (A11) and caudal dorsal hypothalamic areas (A13) as well as in the arcuate (A12) and periventricular (A14) zone were immunoreactive for the two enzymes, suggesting that they were dopaminergic. Numerous tyrosine hydroxylase-immunoreactive neurons, which were not immunoreactive for aromatic l-amino acid decarboxylase, could be seen in the paraventricular, supraoptic and accessory nuclei (A15) as well as in the rostral dorsal hypothalamic area. These were considered to be non-dopaminergic. Conversely, large numbers of small neurons immunoreactive for aromatic l-amino acid decarboxylase but not for tyrosine hydroxylase, were identified in the premammillary nucleus (D8), zona incerta (D10), lateral hypothalamic area (D11), anterior portion of the dorsomedial nucleus (D12), suprachiasmatic nucleus (D13), medial preoptic area and bed nucleus of the stria terminalis (D14). In the human hypothalamus, besides dopaminergic cell bodies, there exists a large number of tyrosine hydroxylase-only and aromatic l-amino acid decarboxylase-only neurons, whose physiological roles remain to be determined.     

Distribution of dopamine-immunoreactive neuronal perikarya and fibres in the brain of a teleost, Gasterosteus aculeatus L. comparison with tyrosine hydroxylase- and dopamine-beta-hydroxylase-immunoreactive neurons

The distribution of dopamine in the brain of the teleost Gasterosteus aculeatus L. was demonstrated with the indirect peroxidase-antiperoxidase immunohistochemical method using highly specific antibodies against a dopamine-glutaraldehyde-thyroglobulin conjugate. Dopamine-immunoreactive (DAir) neuronal somata were observed in all main brain regions. In the forebrain, DAir neurons were located in a continuous cell column extending from the caudal part of the olfactory bulbs to the preoptic area. The neurons lie lateral to the dorsal (and caudally to the subcommissural) portion of the ventral telencephalic area, and ventromedial to the central nuclei of the dorsal area. In the diencephalon, cerebrospinal fluid-contacting neurons were located in the paraventricular organ and in the subependymal layers of the dorsal and caudal zones of the periventricular hypothalamus. Small DAir neurons were observed in the suprachiasmatic nucleus, in the parvocellular preoptic nucleus and in the ventromedial thalamic nucleus, while large perikarya were observed dorsolateral to the dorsal zone of the periventricular hypothalamus ('PVO-accompanying cells'), in the posterior tuberal nucleus and in the most rostral portion of the mammillary bodies. Numerous small DAir neurons were located in the periventricular pretectal nucleus. In the brainstem, DAir neurons were observed in the isthmus region, in the dorsal raphe nucleus and in the lateral parts of the nucleus of the solitary tract. DAir perikarya were also observed in the area postrema. Direct comparison with the distribution of tyrosine hydroxylase- and dopamine-beta-hydroxylase-immunoreactivity (THir and DBHir) gave the following results: THir neurons were found in all areas where DAir neurons were located, except for the paraventricular organ and the dorsal and caudal zones of the periventricular hypothalamus, which were devoid of THir. DBHir (putatively noradrenergic or adrenergic) neurons were observed in the lateral parts of the nucleus of the solitary tract, and in the isthmus region. The DBHir neurons in the isthmus region, which have previously been shown to be noradrenergic, appeared to be identical with the THir and DAir neurons of the same area. DAir axons were found in high numbers in most parts of the brain. Especially dense innervation was found in the ventrolateral and posterior parts of the dorsal telencephalic area, the region surrounding the lateral recesses of the third ventricle, the interpeduncular nucleus, the dorsal and median raphe nuclei (the rostral raphe nuclei), and in the nucleus of the solitary tract.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunocytochemical localization of the catecholamine-synthesizing enzymes, tyrosine hydroxylase and dopamine-β-hydroxylase, in the hypothalamus of cattle

Immunocytochemical staining for the presence of catecholamine synthesizing enzymes, tyrosine hydroxylase and dopamine β-hydroxylase, was used to characterize the regional distribution of catecholaminergic neurons in the hypothalamus and adjacent areas of domestic cattle, Bos taurus. In steers, heifers and cows, tyrosine hydroxylase-immunoreactive perikarya was located throughout periventricular regions of the third cerebral ventricle, in both anterior and retrochiasmatic divisions of the supraoptic nucleus, suprachiasmatic nucleus, and ventral and dorsolateral regions of the paraventricular nucleus, dorsal hypothalamus, ventrolateral aspects of the arcuate nucleus, along the ventral hypothalamic surface between the median eminence and optic tract, and in the posterior hypothalamus. Immunostained perikarya ranged from small (10–20 μm, parvicellular) to large (30–50 μm, magnocellular) and were of multiple shapes: round, triangular, fusiform or multipolar, often with 2–5 processes of branched arborization. There were no dopamine-β-hydroxylase immunoreactive perikarya observed within the hypothalamus and adjacent structures. However, both tyrosine hydroxylase and dopamine-β-hydroxylase immunoreactive fibers and punctate varicosities were observed throughout regions of tyrosine hydroxylase immunoreactivity perikarya. Generally, the location and pattern of hypothalamic tyrosine hydroxylase immunoreactivity and dopamine-β-hydroxylase immunoreactive were similar to those reported for most other large brain mammalian species, however, there were several differences with commonly used small laboratory animals. These included intense tyrosine hydroxylase immunoreactivity of perikarya within the retrochiasmatic division of the supraoptic nucleus (ventral A15 region), the absence of tyrosine hydroxylase immunoreactive perikarya below the anterior commissure or within the bed nucleus of stria terminalis (absence of the dorsal A15 region), an abundance of tyrosine hydroxylase immunoreactive perikarya within the ependymal layer of the median eminence, heavy innervation of the arcuate nucleus with dopamine-β-hydroxylase immunoreactive fibers and varicosities, and the paucity of dopamine-β-hydroxylase immunoreactive throughout the median eminence.     

Localization of non-monoaminergic aromatic L-amino acid decarboxylase neurons (D-neurons) in the human striatum and their functional significance

It has recently been reported that the human corpus striatum, especially its ventral part, named as the nucleus accumbens, contains numerous non-monoaminergic aromatic L-amino acid decarboxylase (AADC; the second-step monoamine synthesizing enzyme) neurons (D-neurons). D-neurons are the neurons immunoreactive for AADC but not immunoreactive for dopamine or serotonin. They lack the first-step monoamine synthesizing enzymes, tyrosine hydroxylase and tryptophan hydroxylase. AADC is also the rate-limiting enzyme of phenylethylamine (PEA) synthesis. D-neurons might participate in the manifestation of efficacy of pharmacotherapy for Parkinson's disease by uptaking monoamine precursors including L-dopa or droxidopa (L-threo-DOPS) and by converting them to dopamine or noradrenaline, respectively. As the nucleus accumbens is one of the brain regions that are involved in the pathogenesis of schizophrenia and drug dependence, D-neurons might be related to the etiology of these mental disorders. It has also been suggested that striatal D-neurons are the pluripotential cells that have compensating functions against aging or degeneration.     

Carbonic anhydrase II in rat acid secreting cells: comparison of osteoclasts with gastric parietal cells and kidney intercalated cells

Location of carbonic anhydrase II, an important enzyme involved in acid production, was studied using an immunogold method on ultracryosections. Its distribution in osteoclasts was compared with that in gastric parietal cells and kidney intercalated cells of the inner stripe of outer medulla. It is shown that the distribution of carbonic anhydrase II is much similar in all of these acid producing cells: most of the enzyme is cytoplasmic and nucleoplasmic and only a small fraction of the enzyme is associated with the apical plasma membrane. It seems likely that carbonic anhydrase II has a similar role in all of these acid producing cells.