Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
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Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
Query: EC:4.6.1.1 (
adenylate cyclase
)
19,190
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
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.
...
PMID:Sub-types of serotonin receptors: biochemical changes and pharmacological consequences. 162 53
Thirty-three years ago, Gaddum and Picarelli classified the serotonin (5-HT) receptors in the guinea-pig ileum into D and M types based on the activity of dibenzyline (D) and morphine (M) to block contractions of intestinal smooth muscles caused by 5-HT. The subsequent location of specific ligand binding sites for 5-HT in the brain has led to the identification of 10 5-HT receptor subtypes in rat brain. While there is some controversy over the functional importance of many of these receptor subtypes, 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 subfamily which may be coupled either to
adenylate cyclase
(most 5-HT1 subtypes) or phosphatidyl inositol (5-HT2 subtypes). The central "M" receptors (now termed 5-HT3) appear to occupy a ligand-gated ion channel superfamily. The cloning of these receptor subtypes has been of importance in enabling them to be classified as specific protein molecules encoded by specific genes. A problem now arises with regard to the linking of the changes in the cellular activity of the various receptor subtypes with the plethora of behavioural changes that arise as a consequence of the actions of 5-HT in the brain. The present review summarizes the evidence implicating the role of specific 5-HT receptor subtypes in thermoregulation, modulation of cardiovascular function, eating
disorders, sleep
, sexual activity, anxiety states, aggression, schizophrenia and depression. A summary of the relationship between these receptor subtypes and their possible involvement in the aetiology of these diseases is also given.
...
PMID:Serotonin receptors--where are they going? 802 39
Recent advances in molecular biology, biochemistry, cell biology and behavioral pharmacology together with the development of more selective ligands to the various adenosine receptors have increased our understanding of the functioning of central adenosine A(2A) receptors. The A(2A) receptor is one of four adenosine receptors found in the brain. Its expression is highest in striatum, nucleus accumbens and olfactory tubercles, although it also occurs in neurons and microglia in most other brain regions. The receptor has seven transmembrane domains and couples via Gs to
adenyl cyclase
stimulation. Antagonistic interactions between A(2A) receptors and dopamine D(2) receptors have been described, as stimulation of the A(2A) receptor leads to a reduction in the affinity of D(2) receptors for D(2) receptor agonists. The A(2A) receptor is thought to play a role in a number of physiological responses and pathological conditions. Indeed, A(2A) receptor antagonists may be useful for the treatment of acute and chronic neurodegenerative disorders such as cerebral ischemia or Parkinson's disease. A(2A) receptor agonists may treat certain types of seizures or
sleep disorders
. This review discusses the characteristics, distribution, pharmacochemical properties and regulation of central A(2A) receptors, as well as A(2A) receptor-mediated behavioural responses and their potential role in various neuropsychiatric disorders.
...
PMID:Central adenosine A(2A) receptors: an overview. 1061 96
The suprachiasmatic nuclei (SCN) residing in the anterior hypothalamus maintains a near-24-h rhythm of electrical activity, even in the absence of environmental cues. This circadian rhythm is generated by intrinsic molecular mechanisms in the neurons of the SCN; however, the circadian clock is modulated by a wide variety of influences, including glutamate and pituitary
adenylate cyclase
-activating peptide (PACAP) from the retinohypothalamic tract, melatonin from the pineal gland, and neuropeptide Y from the intergeniculate leaflet. By virtue of these and other inputs, the SCN responds to environmental cues such as light, social and physical activities. In turn, the SCN controls or influences a wide variety of physiologic and behavioral functions, including attention, endocrine cycles, body temperature, melatonin secretion, and the sleep-wake cycle. Regulation of the sleep-wake cycle by the SCN has important implications for development of therapies for
sleep disorders
, including those involving desynchronization of circadian rhythms and insomnia.
...
PMID:The brain's master circadian clock: implications and opportunities for therapy of sleep disorders. 1697 92
Adenosine is an established neuromodulator in the mammalian retina, with A1 adenosine receptors being especially prevalent in the innermost ganglion cell layer. Activation of A1 receptors causes inhibition of
adenylate cyclase
, decreases in intracellular cyclic AMP (cAMP) levels and inhibition of protein kinase A (PKA). In this work, our aim was to characterize the effects of adenosine on the light responses of intrinsically photosensitive retinal ganglion cells (ipRGCs) and to determine whether these photoreceptors are subject to neuromodulation through intracellular cAMP-related signalling pathways. Using multielectrode array recordings from postnatal and adult rat retinas, we demonstrated that adenosine significantly shortened the duration of ipRGC photoresponses and reduced the number of light-evoked spikes fired by these neurons. The effects were A1 adenosine receptor-mediated, and the expression of this receptor on melanopsin-containing ipRGCs was confirmed by calcium imaging experiments on isolated cells in purified cultures. While inhibition of the cAMP/PKA pathway by adenosine shortened ipRGC light responses, stimulation of this pathway with compounds such as forskolin had the opposite effect and lengthened the duration of ipRGC spiking. Our findings reveal that the modification of ipRGC photoresponses through a cAMP/PKA pathway is a general feature of rat ganglion cell photoreceptors, and this pathway can be inhibited through activation of A1 receptors by adenosine. As adenosine levels in the retina rise at night, adenosinergic modulation of ipRGCs may serve as an internal regulatory mechanism to limit transmission of nocturnal photic signals by ipRGCs to the brain. Targeting retinal A1 adenosine receptors for ipRGC inhibition represents a potential therapeutic target for
sleep disorders
and migraine-associated photophobia.
...
PMID:Adenosine modulates light responses of rat retinal ganglion cell photoreceptors througha cAMP-mediated pathway. 2503 40
