EC:1.14.16.2 - FACTA Search

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Query: EC:1.14.16.2 (tyrosine hydroxylase)
14,760 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In the developing mesencephalon of the rat, the dopaminergic neurons are generated in the ventricular zone of the basal plate between E11 and E15 and then migrate along radial glia to the ventral surface of the developing mesencephalon. To study the factors that control migration and maturation of the dopaminergic neurons, we immunolabeled embryo and pups, ages E12-P21, for neural cell adhesion molecule (NCAM), polysialic acid (PSA) - a polysaccharide found in high amounts on NCAM during development, tyrosine hydroxylase (TH) - a marker of mesencephalic dopaminergic cells, and vimentin - the major cytoskeletal protein in radial glia in the rat. At E13, we noted that cells throughout the mesencephalon contained NCAM-immunoreactive (NCAM-IR) material but that cells along the ventral surface of the mesencephalon contained an increased amount of NCAM-IR material and PSA-immunoreactive (PSA-IR) material. At this age, we first noted a small number of TH-immunoreactive (TH-IR) cells adjacent to the marginal zone of the ventral surface of the mesencephalon. Many of the TH-IR cells contained an increased density of NCAM-IR material. At age E14, the pattern of increased density of NCAM-IR material on cells along the ventral surface of the mesencephalon persisted and a conspicuous amount of PSA-IR material was also noted on cells in this region. TH-IR cells were more numerous, and a striking number of the TH-IR cells also contained an increased amount of NCAM-IR material and PSA-IR material. With increasing age the distribution of NCAM-IR material and PSA-IR material in the mesencephalon became more uniform. Our work suggests that NCAM may be involved in control of migration and synthesis of TH in the dopaminergic cells of the developing mesencephalon.
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PMID:Mesencephalic dopaminergic cells exhibit increased density of neural cell adhesion molecule and polysialic acid during development. 134 68

Using specific antibody markers and double-label immunofluorescence microscopy, we have followed the fate of progenitor cells in the sympathoadrenal (SA) sublineage of the neural crest in developing rat embryos. Such progenitors are first recognizable in the primordial sympathetic ganglia at embryonic day 11.5 (E11.5), when they express tyrosine hydroxylase. At this stage, the progenitors also coexpress neuronal markers such as SCG 10 and neurofilament, together with a series of chromaffin cell markers called SA 1-5 (Carnhan and Patterson, 1991 a). The observation of such doubly labeled cells is consistent with the hypothesis that these cells represent a common progenitor to sympathetic neurons and adrenal chromaffin cells. Subsequent to E 11.5, expression of the chromaffin markers is extinguished in the sympathetic ganglia but retained by cells within the adrenal gland. Concomitant with the loss of the SA 1-5 immunoreactivity in sympathetic ganglia, a later sympathetic neuron-specific marker, B2, appears. In dissociated cell suspensions, some B2+ cells that coexpress SA 1 are seen. This implies a switch in the antigenic phenotype of developing sympathetic neurons, rather than a replacement of one cell population by another. The SA 1----B2 transition does not occur for the majority of cells within the adrenal primordium. In vitro, most B2+ cells fail to differentiate into chromaffin cells in response to glucocorticoid. Instead, they continue to extend neurites and then die. Taken together, these data imply that the SA 1----B2 transition correlates with a loss of competence to respond to an inducer of chromaffin differentiation. Thus, the development of SA derivatives is controlled both by environmental signals and by changes in the ability of differentiating cells to respond to such signals.
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PMID:Antibody markers identify a common progenitor to sympathetic neurons and chromaffin cells in vivo and reveal the timing of commitment to neuronal differentiation in the sympathoadrenal lineage. 194 Oct 94

Experiments were done to study the fate of transient catecholaminergic (TC) cells that develop in the rodent gut during ontogeny. When they are first detected, at Day E11 in rats, TC cells are distributed along the vagal pathway, in advance of the descending fibers of the vagus nerves, and in the foregut. The early TC cells coexpress the immunoreactivities of several neural markers, including 150-kDa neurofilament protein, peripherin, microtubule associated protein (MAP) 5, and growth-associated protein (GAP)-43, with those of the catecholamine biosynthetic enzymes tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH). All cells in the fetal rat bowel at Day E11 that express neural markers also express TH immunoreactivity. The primitive TC cells also express the immunoreactivities of neural cell adhesion molecule (N-CAM), neuropeptide Y (NPY), and nerve growth factor (NGF) receptor (and NGF receptor mRNA). By Day E12 TC cells are found along the vagal pathway and throughout the entire preumbilical bowel. At this age TC cells acquire additional characteristics, including MAP 2 and synaptophysin immunoreactivities and acetylcholinesterase activity, which indicate that they continue to mature as neurons. In addition, TC cells of the rat are immunostained at Day E12 by the NC-1 monoclonal antibody, which in rats labels multiple cell types including migrating cells of neural crest origin. Despite their neural properties, at least some TC cells divide and therefore are neural precursors and not terminally differentiated neurons. At Day E10 TH mRNA-containing cells were not detected by in situ hybridization; however, by Day E11 TH mRNA was detected in sympathetic ganglia and in scattered cells in the mesenchyme of the foregut and vagal pathway. At this age, the number of enteric and vagal cells containing TH mRNA is about 30% less than the number of cells containing TH immunoreactivity in adjacent sections. The ratio of TH mRNA-containing cells to TH-immunoreactive vagal and enteric cells is even less at Day E12, especially in more caudal regions of the preumbilical bowel. A similar decline in the ratio of TH mRNA-containing to TH-immunoreactive cells was not observed in sympathetic ganglia. After Day E12 TH mRNA cannot be detected in enteric or vagal cells by in situ hybridization; nevertheless, TH immunoreactivity continues to be present through Day E14. DBH, NPY, and NGF receptor immunoreactivities are expressed by TH-immunoreactive transitional cells in the fetal rat gut after TH mRNA is no longer detectable.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Transiently catecholaminergic (TC) cells in the bowel of the fetal rat: precursors of noncatecholaminergic enteric neurons. 197 56

In situ hybridization was used to examine the appearance of mRNA specific for tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine (CA) biosynthesis, in neural crest derivatives of the rat embryo. These derivatives include sympathetic ganglia and transient catecholaminergic cells of embryonic intestine. Messenger RNA is first detected in sympathetic ganglia at E11.5, the age corresponding to the initial immunocytochemical expression of TH protein. In older embryos increased accumulation of TH-specific mRNA in sympathetic ganglia parallels the increase in TH immunoreactivity. By contrast, mRNA for TH is difficult to detect in embryonic intestines at E11.5 but is found instead in cells clustered at the dorsal boundaries of the pharynx and foregut. Cells expressing TH mRNA are infrequently found in embryonic intestines at any age, even though TH protein is immunohistochemically apparent. Treatment of pregnant rats with doses of reserpine, known to increase circulating levels of glucocorticoid hormones and prolong the expression of TH protein in embryonic gut cells, dramatically but transiently increases the number of gut cells at E12.5 with detectable TH mRNA. After E13.5 TH mRNA is undetectable even in reserpine-treated guts. Reserpine treatment also increases the labeling density in sympathetic ganglia. Taken together, these data are consistent with the hypothesis that the microenvironment of the embryonic intestine affects gene expression directly to alter phenotype. Moreover, although reserpine administration briefly increases TH mRNA levels, the effect is short-lived and does not alter neurotransmitter phenotypic conversion.
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PMID:Regulation of tyrosine hydroxylase mRNA in catecholaminergic cells of embryonic rat: analysis by in situ hybridization. 256 2

Catecholaminergic cells are transiently present during development of the fetal murine bowel. These transient catecholaminergic (TC) cells appear at Day E10, but by Day E13 can no longer be detected. In order to evaluate the hypothesis that these cells are the precursors of enteric neurons, we investigated the possibilities that TC cells coexpress neuronal and catecholaminergic markers, that they can be found along the presumed path followed by crest-derived cells migrating to the gut, and that they are proliferating. TC cells were identified immunocytochemically using polyclonal or monoclonal antibodies to tyrosine hydroxylase (TH). At Day E9.5, TH-immunoreactive cells were observed to be present along the wall of the primordial esophagus in lines that extended from the developing nodose ganglia down to the boundary of the stomach. At Day E9.5, TC cells were absent from the remaining foregut. These lines of esophageal TH-immunoreactive cells became continuous with similar cells in the wall of the stomach and duodenum on Day E10. Coincident expression of neurofilament immunoreactivity was seen in all of the esophageal TH-immunoreactive cells present at Day E9.5, as well as in the entire set of esophageal and lower enteric TH-immunoreactive cells present at Day E10 (or later); moreover, at Days E9.5 and E10, all of the neurofilament-immunoreactive cells in the esophagus, stomach, or duodenum were also TH-immunoreactive. In contrast, neurofilament immunoreactivity was not expressed by the endodermally derived pancreatic duct and islet cells, which were also TH-immunoreactive; nor could expression of neurofilament immunoreactivity be detected in the TH-immunoreactive cells of the nodose ganglia. It was not until Day E11 that neurofilament-immunoreactive cells, which did not coexpress TH immunoreactivity (the definitive phenotype of enteric neurons) began to appear in the gut. Vagal axons reached as far distally as the nodose ganglion on Day E9.5, the esophagogastric junction on Day E10, and did not enter the stomach until Day E11. When the vagus nerves reached their level, the TH-immunoreactive cells in the wall of the esophagus came to lie among the nerve fibers. TH-immunoreactive cells are thus present on the pathway ultimately followed by the vagus nerves, but they develop before vagal fibers reach their level. The vagal TH-immunoreactive cells, therefore, are probably not initially migrating on vagal fibers, but appear instead to be overtaken by the descending vagus nerves.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Transient catecholaminergic (TC) cells in the vagus nerves and bowel of fetal mice: relationship to the development of enteric neurons. 256 10

Transient expression of catecholaminergic phenotypic traits is a widespread phenomenon during embryonic development in mammals, occurring in cells of the embryonic gut mesenchyme, in ventrolateral portions of the neural tube, cells of cranial sensory and dorsal root ganglia, and in the embryonic pancreas. In the current study the manifestation of the catecholamine (CA) phenotype in these populations has been further defined. Specifically, the existence of the high-affinity uptake process for CAs in these populations has been investigated. By combining the techniques of radioautography following accumulation of [3H]norepinephrine (3H-NE) and [3H]dopamine (3H-DA) with immunohistochemical detection of tyrosine hydroxylase (T-OH), it has been possible to demonstrate simultaneously CA accumulation by T-OH-positive gut cells. Uptake of 3H-NE was first detected in T-OH-positive cells of the gut on gestational day 12.5 (E12.5). By contrast, T-OH immunoreactivity was first detected on E11.5. By E13.5 virtually every T-OH-positive cell oral to the umbilical flexure was radioautographically labeled. Uptake at E13.5 displayed Michaelis-Menten saturation kinetics, had a Vmax of 35 fmole/gut/min, a Km of 1.45 microM, was blocked by desmethylimipramine (DMI), and by incubation at 4 degrees C. On subsequent gestational days, silver grains marking areas of amine concentration were found increasingly over T-OH-negative cells. A similar pattern of uptake was found in guts which had been grown in organotypic tissue culture for the purpose of eliminating extrinsic sympathetic innervation. T-OH-positive gut cells also accumulated 3H-DA. Concentration of 3H-DA was blocked by both benztropine and DMI suggesting that accumulation had properties common to both NE and DA systems. By contrast to cells of the gut, accumulation of CAs was not a property of transiently T-OH-positive cells in other locations. Therefore, specific, high-affinity uptake and retention of CAs is an additional property of transiently catecholaminergic gut cells. Appearance of CA synthetic enzymes precedes the appearance of the CA storage process in cells of the gut. Persistence of the uptake process after the loss of detectable T-OH suggests continued viability of the population. The absence of CA accumulation by other T-OH-positive cells suggests basic molecular differences among the various populations.
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PMID:Selective expression of high-affinity uptake of catecholamines by transiently catecholaminergic cells of the rat embryo: studies in vivo and in vitro. 285 67

The pancreatic islets of mouse embryos are comprised of four different endocrine cell types and of cells containing a hormone (i.e., glucagon) and a catecholamine enzyme (tyrosine hydroxylase, TH) which appear sequentially during development in vivo. The presence of TH in glucagon cells, however, is transient, since adult pancreatic A cells do not express the enzyme. In this study we sought to determine whether the endocrine precursor cells are primed to differentiate and express catecholamine enzymes during their maturation following a predetermined sequence or whether these processes are regulated by environmental cues. To answer this question, we used immunocytochemical procedures to examine the differentiation of pancreatic rudiments removed from E11 mouse embryos and maintained in culture and of pancreases that regenerated in vitro from E11 pancreatic ducts. We found that although all the endocrine cell types differentiate in the gland in culture, the sequence of their appearance is different from that in vivo, suggesting that the timing of differentiation may be regulated by environmental factors. We also found that, in vitro, the pancreas contains TH-glucagon cells, indicating that the expression of the enzyme by pancreatic A cells is independent of factors present in vivo. Moreover, the fact that the TH-glucagon cells also differentiate during pancreatic regeneration suggests that the expression of the enzyme may be a characteristic stage of endocrine cell precursors during maturation.
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PMID:Differentiation of prospective mouse pancreatic islet cells during development in vitro and during regeneration. 288 18

We sought to determine whether the precursors of catecholamine-containing neurons in the developing peripheral and central nervous systems of chickens and rats express the biosynthetic enzymes tyrosine hydroxylase [THase; tyrosine 3-monooxygenase; L-tyrosine, tetrahydropteridine: oxygen oxidoreductase (3-hydroxylating), EC 1.14.16.2] or dopamine beta-hydroxylase [DBHase; 3,4-dihydroxyphenylethylamine, ascorbate:oxygen oxidoreductase (beta-hydroxylating), EC 1.14.17.1], prior to the time they withdraw from the cell cycle. Chicken embryos (stages 26-27) were injected with [3H-thymidine and 4 hr later were prepared for the simultaneous demonstration of radioautographically labeled nuclei in immunoreactive THase cells. The brains and sympathetic chains of rat fetuses (days E12-E14), exposed for 2 hr to [3H]thymidine, were treated similarly except that peripheral tissues were stained with a specific antibody to DBHase as well as anti-THase. In the peripheral nervous system of both chicken and rat, nuclei of THase-containing cells were radioautographically labeled. DBHase-containing cells in the peripheral nervous system of rats were also labeled and thus are noradrenergic. THase was localized in cells of the brain of the same rat fetuses beginning on day E12 (no THase was detected on day E11 or E11.5) in the mantle layer of the ventral mesencephalic and rostrolateral rhombocephalic cellular groups; however. THase-containing cells in the central nervous system did not incorporate [3H]thymidine. We conclude that, during development, the adrenergic neuronal precursors of the peripheral nervous system but not of the central, have the capacity to synthesize catecholamines before they withdraw from the cell cycle. Differences in the maturation of peripheral and central neurons may be related to differences in their embryological origin.
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PMID:Catecholamine biosynthetic enzymes are expressed in replicating cells of the peripheral but not the central nervous system. 610 65

We describe the transient expression of catecholaminergic traits in cranial sensory and dorsal root ganglia of the embryonic rat in vivo. Isolated cells expressing tyrosine hydroxylase (T-OH) immunoreactivity were initially detected in trigeminal (V) ganglion anlages as early as gestational Day 10.5 (E10.5; 18-22 somites). Neurofilament (NF) protein was also evident in V at these early stages. By E11.5 (27-30 somites) clusters of T-OH-positive cells were visible in V. Many of these cells were bipolar; others sent processes into the primitive brainstem. In addition, cells expressing T-OH were apparent in primordia of sensory ganglia serving the glossopharyngeal (IX) and vagal (X) cranial nerves. By this stage (E11.5) all cranial sensory ganglia were rich in NF protein, but immunoreactivity was confined to cellular processes rather than perikarya. By E12 (35-37 somites), only a few, faintly positive T-OH-containing cells were evident in V. However, DBH- and T-OH-positive cells were visible within the more caudal nodose and petrosal ganglia. Furthermore, isolated bipolar cells expressing T-OH were detected in rostral dorsal root ganglia at this stage. Catecholamine fluorescence could not be detected in any sensory ganglia even after maternal treatment with inhibitors of monoamine oxidase. Catecholaminergic cells were not seen at any stage in anlages of the acousticovestibular nucleus. Immunoreactive T-OH was undetectable in all ganglia by E13.5 (46-48 somites). These findings highlight the fact that transient expression of the catecholamine phenotype during development is a widespread phenomenon, evident in a variety of cell types of diverse embryonic origin.
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PMID:Transient expression of selected catecholaminergic traits in cranial sensory and dorsal root ganglia of the embryonic rat. 614 Nov 17

Previous [3H]thymidine studies in Nissl-stained sections in rats established that the substantia nigra pars compacta and the ventral tegmental area originate sequentially according to an anterolateral to posteromedial neurogenetic gradient. We investigated whether that same pattern is found in mice in the dopaminergic neurons in each of these structures. Using tyrosine hydroxylase immunostaining combined with [3H]thymidine autoradiography, the time of origin of dopaminergic midbrain neurons in the retrorubral field, the substantia nigra pars compacta, the ventral tegmental area, and the interfascicular nucleus was determined in postnatal day 20 mice. The dams of the experimental animals were injected with [3H]thymidine on embryonic days (E) 11-E12, E12-E13, E13-E14, and E14-E15. The time of origin profiles for each group indicated significant differences between populations. The retrorubral field and the substantia nigra pars compacta arose nearly simultaneously and contained the highest proportion of neurons, 49 to 37%, generated on or before E11. Progressively fewer early-generated neurons were found in the ventral tegmental area (20%), and the interfascicular nucleus (8.5%). In addition, anterior dorsolateral neurons in the substantia nigra and ventral tegmental area were more likely to be generated early than the posterior ventromedial neurons. These findings indicate that mouse and rat brains have nearly identical developmental patterns in the midbrain, and neurogenetic gradients in dopaminergic neurons are similar to those found in Nissl studies in rats.
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PMID:Time of neuron origin and gradients of neurogenesis in midbrain dopaminergic neurons in the mouse. 749 72

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