Sub-types of serotonin receptors: biochemical changes and pharmacological consequences.
Thirty-three years ago, Gaddum and Picarelli classified the serotonin receptors in the guinea pig ileum into D and M types based on the activity of dibenzyline and morphine to block contractions of intestinal smooth muscle caused by serotonin. The subsequent location of specific ligand binding sites for serotonin in the brain has led to the identification of at least eight serotonin receptor sub-types in rat brain. While there is some controversy over the functional importance of many of these receptor sub-types, there is evidence that they fall into two major groups according to the nature of their coupling to secondary messengers or ion channels. Thus the 5-HT1 and 5-HT2 receptors appear to occupy the G protein receptor sub-family which may be coupled either to adenylate cyclase (most 5-HT1 sub-types) or phosphatidyl inositol (5-HT2 sub-types). The central "M" receptors (now termed 5-HT3) appear to occupy a ligand gated ion channel super-family. The cloning of three of the serotonin receptor sub-types in 1989 (5-HT1A, 5-HT1C and 5-HT2) has been of importance in enabling the receptor sub-types to be classified as specific protein molecules encoded by specific genes. The problem now arises with regard to the linking of the changes in the cellular activity of the various receptor sub-types with the plethora of behavioural changes that arise as a consequence of the actions of serotonin in the brain. The present review summarizes the evidence implicating the role of specific serotonin receptor sub-types in eating disorders, sleep, sexual activity, anxiety states, aggression, schizophrenia and depression. A summary of the relationship between these receptor sub-types and their possible involvement in the aetiology of these diseases is shown in Table 2.[1]References
- Sub-types of serotonin receptors: biochemical changes and pharmacological consequences. Leonard, B.E. International clinical psychopharmacology. (1992) [Pubmed]
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