During the 1980s, indications for the existence of intramembrane interactions between different G protein-coupled receptors, mainly between neuropeptide and monoamine receptors, were obtained in several brain areas (1, 2). It was later proposed that a possible molecular mechanism for this phenomenon was receptor heteromerization (3) and direct evidence for homo-and heteromerization of G protein-coupled receptors has been obtained by several groups. It was first shown that serotonin 5-HT-1B receptors exist as monomers and dimers (4). This was followed by demonstration of dimers and oligomers of dopamine D 1 and D 2 receptors (D 1 and D 2 R) in transfected Sf cells (5-7) and of adenosine A 1 receptors (A 1 Rs) in a natural cell line and in mammalian brain (8). It has recently been reported that a fully functional ␥-aminobutyric acid (GABA) type B receptor demands the heterodimerization of GABA B R1 and GABA B R2 receptors (9-12). Moreover, two functional opioid receptors, the and ␦ subtypes, can undergo heteromerization, which changes the pharmacology of the individual receptors and potentiates signal transduction (13). Finally, D 2 R and somatostatin receptor subtype 5 have been shown to physically interact by forming heterooligomers with enhanced functional activity (14). Direct protein-protein coupling can also exist between G proteincoupled anion channel receptors, as recently shown for dopamine D5 receptor and GABA A receptor, making possible bilateral inhibitory interactions between these receptors (15).Antagonistic adenosine͞dopamine interactions have been widely reported in the central nervous system in behavioral and biochemical studies. Furthermore, in animal models, adenosine agonists and antagonists are potent atypical neuroleptics and antiparkinsonian drugs, respectively (16-18). Thus, adenosine agonists inhibit and adenosine antagonists, such as caffeine, potentiate the behavioral effects induced by dopamine agonists. The evidence suggests that this antagonism is at least in part caused by an intramembrane interaction between specific subtypes of dopamine and adenosine receptors, namely, between
Dopamine (DA) neurotransmission in the central nervous system (CNS) is found throughout chordates, and its emergence predates the divergence of chordates. Many of the molecular components of DA systems, such as biosynthetic enzymes, transporters, and receptors, are shared with those of other monoamine systems, suggesting the common origin of these systems. In the mammalian CNS, the DA neurotransmitter systems are diversified and serve for visual and olfactory perception, sensory–motor programming, motivation, memory, emotion, and endocrine regulations. Some of the functions are conserved among different vertebrate groups, while others are not, and this is reflected in the anatomical aspects of DA systems in the forebrain and midbrain. Recent findings concerning a second tyrosine hydroxylase gene (TH2) revealed new populations of DA-synthesizing cells, as evidenced in the periventricular hypothalamic zones of teleost fish. It is likely that the ancestor of vertebrates possessed TH2 DA-synthesizing cells, and the TH2 gene has been lost secondarily in placental mammals. All the vertebrates possess DA cells in the olfactory bulb, retina, and in the diencephalon. Midbrain DA cells are abundant in amniotes while absent in some groups, e.g., teleosts. Studies of protochordate DA cells suggest that the diencephalic DA cells were present before the divergence of the chordate lineage. In contrast, the midbrain cell populations have probably emerged in the vertebrate lineage following the development of the midbrain–hindbrain boundary. The functional flexibility of the DA systems, and the evolvability provided by duplication of the corresponding genes permitted a large diversification of these systems. These features were instrumental in the adaptation of brain functions to the very variable way of life of vertebrates.
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