Dopamine, expression

Kalia V, Fenske C, Hole DR, Wilson CA (1999) Effect of gonadal steroids and gamma-aminobutyric acid on LH release and dopamine expression and activity in the zona incerta in rats. J Reprod Fertil 777 189-197. 

Chio, C. L., Lajiness, M. E., and Huff, R. M. (1994). Activation of heterologously expressed D3 dopamine receptors Comparison with D2 dopamine receptors. Mot. Pharmacol. 45 51-60. 

The dopamine system constitutes the cellular and biochemical network that is involved in the synthesis, release, and response to dopamine. In general, this involves cells that express significant levels of tyrosine hydroxylase (TH) and limited amounts of dopamine (3-hydioxylase [1]. Dopamine-responsive cells express receptors specifically activated by this neurotransmitter, which are known as dopamine Dl, D2, D3, D4, and D5 receptors [2, 3]. 

MAO converts dopamine to DOPAC (3,4-dihydrox-yphenylacetic acid), which can be further metabolized by COMT to form homovanillic acid (HVA). HVA is the main product of dopamine metabolism and the principal dopamine metabolite in urine. Increased neuronal dopaminergic activity is associated with increases in plasma concentrations of DOPAC and HVA. COMT preferentially methylates dopamine at the 3 -hydroxyl position and utilizes S-adenosyl-L-methio-nine as a methyl group donor. COMT is expressed widely in the periphery and in glial cells. In PD, COMT has been targeted since it can convert l-DOPA to inactive 3-OMD (3-O-methyl-dopa). In the presence of an AADC inhibitor such as carbidopa, 3-OMD is the major metabolite of l-DOPA treatment. 

Hirschsprung s disease have ETB receptor mutations). The lack of ET-3/ETB receptor results in the absence of parasympathic ganglionic neurons in the myenteric plexus (Auerbach). Mice with an ET-3/ETB receptor disruption die within 2 weeks after birth. In transgenic mice, in which the expression of the ETB receptor is driven by the dopamine (3-hydroxylase promoter, normal myenteric plexus are present and no enteric disorder develops. These mice, however, show a salt-sensitive hypertension, which can be efficiently treated with amiloride, indicating that ETB receptors are involved in the regulation of natriuresis via the amilorid-sensitive sodium channel ENaC. 

The transporters for 5HT, noradrenaline and dopamine, biogenic monoamines, are genetically related, exist as single isoforms and are expressed on the surface of nerve cells, which use monoamines as (or convert them into) their cognate neurotransmitter. The single-isoform monoamine transporters fulfil all three fundamental functions (reuptake, limiting synaptic transmission, and control of the extracellular neurotransmitter concentration). Inactivation of DAT, NET, or SERT results in an increased extracellular lifetime and level of monoamine neurotransmitter, but decreased intracellular storage and evoked release (Fig. 3). 

Figure 17.8 Comparison of the antagonist potencies of some neuroleptics on different NT receptors. Data are shown for haloperidol (HAL), chlorpromazine (CPZ), clozapine (CLOZ) and risperidone (RISP) acting on dopamine Dj and D2, 5-HT2 (S2), alpha (0(2) adrenoceptors and cholinergic muscarinic receptors (M). The height of each column shows an average of the dissociation constants obtained from a number of publications (see Seeman 1990). The values, which can vary some fiftyfold, are expressed as the negative logarithms (i.e. 9 = 10 M,lnM) so that the higher the column, the more potent the compound. The order of potency of the four compounds at each receptor is shown alongside...

Swerdlow, N.R. Swanson, L.W. and Koob, G.F. Substantia innominata Critical link in the behavioral expression of mesolimbic dopamine stimulation in the rat. Neurosci Lett 50 19-24, 1984. 

With respect to other ethnic groups, African Americans may have a differential sensitivity to weight gain on clozapine (de Leon etal, 2007). They may also require lower doses than Caucasians (Kelly et al, 2006) and inter-individual as well as ethnic responsiveness maybe partly explained by differences in dopamine receptor polymorphisms (Hwang et al, 2005). It is conceivable that side effects may also be differentially expressed based on pharmacodynamic differences resulting from polymorphisms in other receptor types (histaminergic, muscarinic, etc.). This area remains largely unexplored with respect to ethnic differences in antipsychotic side effects. 

Drosophila Ddc is expressed primarily in the CNS and the hypoderm, the epithelial layer of the fly that secretes the cuticle. In the CNS, Ddc is expressed in a small subset of neurons that produce either dopamine or serotonin (Budnik and White, 1988 Valles and White, 1988). In the hypoderm, Ddc expression leads to synthesis of dopamine, which is further metabolized into quinones that have a vital function in the cross-linking, hardening, and pigmentation of the fly cuticle (Wright, 1987). The developmental profile of DDC activity in these two tissues is quite different (Hirsh, 1986). DDC is first detected during late embryo-... 

Vertebrates also show expression of AADC in both neural and non-neural tissues. AADC has been purified from kidney (Christenson et al., 1972), liver (Ando-Yamamoto et al., 1987), adrenal medulla (Albert et al., 1987), and pheochromocytoma (Coge et al., 1989 Ichinose et al., 1989). In the adrenal medulla dopamine is further processed into epinephrine and norepinephrine, which are released from the chromaffin cells during stress to increase heart rate and blood pressure. There are no detectable monoamines in the liver and kidney, and the function of AADC in these tissues is unknown. AADC activity has also been... 

Figure 3. Sketch of DDC-expressing neurons in the Drosophila larval CNS. The CNS consists of brain lobes and a segmented ventral ganglion. Filled circles represent dopamine cells open circles represent serotonin cells grayed circles represent DDC cells that contain no detectable tyrosine hydroxylase or serotonin immunoreactivity, indicating that these cells may produce neither transmitter (Lundell and Hirsh, 1994). M, medial dopamine neurons VL, ventrolateral serotonin neurons DL, dorsolateral dopamine neurons. The hatched rectangle shows the region of the ventral ganglion that is shown in Figures 4 and 6.

The majority of DDC-expressing cells in the brain lobes are dopamine cells. Most of these dopamine cells have axons that project into a common axonal fiber extending anteriomedially within the brain lobe and then separating into finer fibers that cross between the lobes. The dopamine cells occur in small clusters of two to six cells, which suggests that these cells might share common lineages. The serotonin cells within the lobes are also found in pairs, and each pair projects axons into closely associated tracts. The pathways of the serotonin tracts often parallel those of the dopamine cells but are distinct (Lundell and Hirsh, 1994). 

Figure 4 shows confocal images of the staining pattern for DDC (Fig. 4A), serotonin (Fig. 4B), and TH (Fig. 4C) in the segmental ventral ganglion of the CNS from third instar larvae. Panels B and C are the same CNS double stained with serotonin and TH. The DDC-expressing cells can be categorized into a set of paired ventral lateral serotonin cells (Fig. 4A,B labeled VL in 4A), and two morphologically distinct types of dopamine cells, the medial dopamine cells (Fig. 4A,C labeled M) and the dorsal-lateral dopamine cells (Fig. 4A,C labeled DL). Figure 4 demonstrates clearly that individual DDC cells synthesize either serotonin or dopamine, but not both. One additional set of cells shows TH immunoreactivity in the ventral ganglion. These six large vacuolated cells are located more laterally than any other DDC cells (Fig. 4C, unlabeled short arrows). It is likely that the immunoreactivity in these cells results from a non-specific cross-reaction, since these cells are not...

The axonal projections from the DDC-expressing cells in the ventral ganglion also show tendencies to follow common pathways. The projections from the ventral lateral serotonin cells extend medially to fuse with axons projecting from the contralateral serotonin cells. At the midline, this projection is met by an axonal projection from the medial dopamine cell. 

Figure 8. Colocalization of DDC and ZFH-2 in larval CNS. This figure shows abdominal segments 4-7 of a third instar larval CNS. DDC im-munoreactivity is cytoplasmic and is shown in red, whereas ZFH-2 im-munoreactivity is nuclear and is shown in green. Only the outside cell of each pair of serotonin neurons expresses ZFH-2. One medial dopamine cell shown at the top also shows ZFH-2 expression. This projection does not include the dorsolateral cells, which also express ZFH-2. A similar projection has been published in Lundell and Hirsh (1992).

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