Neuronal transmitter

The pathway for synthesis of the catecholamines dopamine, noradrenaline and adrenaline, illustrated in Fig. 8.5, was first proposed by Hermann Blaschko in 1939 but was not confirmed until 30 years later. The amino acid /-tyrosine is the primary substrate for this pathway and its hydroxylation, by tyrosine hydroxylase (TH), to /-dihydroxyphenylalanine (/-DOPA) is followed by decarboxylation to form dopamine. These two steps take place in the cytoplasm of catecholaminereleasing neurons. Dopamine is then transported into the storage vesicles where the vesicle-bound enzyme, dopamine-p-hydroxylase (DpH), converts it to noradrenaline (see also Fig. 8.4). It is possible that /-phenylalanine can act as an alternative substrate for the pathway, being converted first to m-tyrosine and then to /-DOPA. TH can bring about both these reactions but the extent to which this happens in vivo is uncertain. In all catecholamine-releasing neurons, transmitter synthesis in the terminals greatly exceeds that in the cell bodies or axons and so it can be inferred... 

Adrenaline is the main hormone released from the adrenal medulla. The glandular cells in this structure correspond to the second, postganglionic neuron of the sympathetic nervous system. Furthermore, adrenaline can be found in chromaffin cells in various tissues. For the better understanding of the function of noradrenaline it is important to realize that this substance, as a neuronal transmitter, affects only the innervated target structure, that is it acts mainly locally. Among these effects are the activation of the musculus dilatator to widen the pupillae in response to a reduced light intensity, an increase in heart rate as a response to a blood pressure drop due to a reduction of the peripheral resistance or constriction... 

Substance P (related tachykinins) Substance P is an important sensory neuron transmitter in the ENS and elsewhere. Tachykinins appear to be excitatory cotransmitters with ACh at ENS neuromuscular junctions. Found with CGRP in cardiovascular sensory neurons. Substance P is a vasodilator (probably via release of nitric oxide). 

The antidepressant effect of thymoleptics manifests after a prolonged latency usually 1-3 weeks pass before subjective or objective improvement becomes noticeable (A). In contrast, somatic effects are immediately evident specifically, the interference with neuronal transmitter/modulator systems (norepinephrine, serotonin, acetylcholine, histamine, dopamine). Reuptake of released serotonin, norepinephrine, or both is impaired (—< elevated concentration in synaptic cleft) and/or receptors are blocked (example in A). These effects are demonstrable in animal studies and are the cause of acute adverse effects. 

Rao, M.S. and Landis, S.C. (1993) Cell interactions that determine sympathetic neuron transmitter phenotype and the neurokines that mediate them. J. Neurobiol. 24 215-232. 

The decarboxylation of glutamic acids to the neuronal transmitter y-aminobutyric acid (GABA) has been much studied, and since the original discovery that the reaction occurred with retention of configuration (247), the process has been used to prepare labeled samples of GABA (248-255). 

Substance P, an undecapeptide, is a member of the tachykinin peptide group. It is an important sensory neuron transmitter in the ENS and, of course, in primary afferents involved in nociception. Substance P contracts intestinal and bronchiolar smooth muscle but is an arteriolar vasodilator (possibly via NO release). It may also play a role in renal and salivary gland functions. 

Since the primary purpose of this review is to study the opiates and their immediate derivatives, it is not proposed to examine in detail the interactions of the weak, peripherally-acting analgesics with neuronal transmitters readers interested in this group of drugs per se may consult reviews by Randall [4] and De Stevens [5]. However, this is not to totally dismiss as unimportant the role of central neuronal transmitters in the formulation and perception of some forms of chronic inflammatory or somatic pain a number of recent reports have demonstrated the value of certain tricyclic anti-depressant agents in alleviating this type of pain in man [6,7]. 

CGRP is widely distributed throughout the peripheral and central nervous systems and is found ia sensory neurons and ia the autonomic and enteric nervous systems. In many iastances CGRP is co-localized with other neuroregulators, eg, ACh ia motor neurons, substance P, somatostatin, vasoactive intestinal polypeptide (VIP), and galanin ia sensory neurons. It is also present ia the CNS, with ACh ia the parabigeminal nucleus and with cholecystokinin (CCK) ia the dorsal parabrachial area. CGRP functions as a neuromodulator or co-transmitter. 

Neuronal Norepinephrine Depleting Agents. Reserpine (Table 6) is the most active alkaloid derived from Rauwolfia serpentina. The principal antihypertensive mechanism of action primarily results from depletion of norepinephrine from peripheral sympathetic nerves and the brain adrenergic neurons. The result is a drastic decrease in the amount of norepinephrine released from these neurons, leading to decrease in vascular tone and lowering of blood pressure. Reserpine also depletes other transmitters including epinephrine, serotonin [50-67-9] dopamine [51-61-6] ... 

This is the case when the excitatory Dx receptors on these striatal GABAergic projection neurons are no longer activated since the transmitter dopamine is reduced (green broken arrows at 2). The indirect pathway is... 

Cotransmission is transmission through a single synapse by means of more than one transmitter. For example, to elicit vasoconstriction, postganglionic sympathetic neurones release their classical transmitter noradrenaline (which acts on smooth muscle a-adrenoceptors) as well as ATP (which acts on smooth muscle P2 receptors) and neuropeptide Y (which acts on smooth muscle Yx receptors). 

The neurokinin, substance P (SP), may be involved as a sensory transmitter in afferent vagal nerves involved in the vomiting reflex. Both SP and its receptors (NKi receptors) have been detected in several areas of the brain associated with vomiting, including the AP, NTS and dorsal motor vagal nucleus. The neurokinin can activate neurons in the AP and NTS. SP is present also in sensory nerves in the gut as well as being co-localised with serotonin in some enterochromaffin cells. 

NPY is primarily (but not exclusively) synthesised and released by neurons, which in the peripheral nervous system are predominantly sympathetic neurons [1]. In most cases, NPY acts as a co-transmitter that is preferentially released upon high frequency nerve stimulation. NPY can be metabolised by the enzyme dipeptidylpeptidase IV (also known as CD26) to generate the biologically active fragment NPY3 36. 

The neuropeptides are peptides acting as neurotransmitters. Some form families such as the tachykinin family with substance P, neurokinin A and neurokinin B, which consist of 11 or 12 amino acids and possess the common carboxy-terminal sequence Phe-X-Gly-Leu-Met-CONH2. Substance P is a transmitter of primary afferent nociceptive neurones. The opioid peptide family is characterized by the C-terminal sequence Tyr-Gly-Gly-Phe-X. Its numerous members are transmitters in many brain neurones. Neuropeptide Y (NPY), with 36 amino acids, is a transmitter (with noradrenaline and ATP) of postganglionic sympathetic neurones. 

NET (SLC6A2) Noradre-naline, dopamine 1 CNS noradrenergic neurons (emanate from locus coeruleus and lateral tegmental area), sympathetic nervous system Clearance of interstitial neuro-transmitter, reuptake into neurons... 

Several classes of drugs modulate the firing rates or patterns of midbrain dopamine neurons by direct, monosynaptic, or indirect, polysynaptic, inputs to the cell bodies within the ventral mesencephalon (i.e., nicotine and opiates). In contrast, amphetamine, cocaine, and methylphenidate act at the level of the dopamine terminal interfering with normal processes of transmitter packaging, release, reuptake, and metabolism. 

Enterochromaffin cells are interspersed with mucosal cells mainly in the stomach and small intestine. In the blood, serotonin is present at high concentrations in platelets, which take up serotonin from the plasma by an active transport process. Serotonin is released on platelet activation. In the central nervous system, serotonin serves as a transmitter. The main serotonin-containing neurons are those clustered in form of the Raphe nuclei. Serotonin exerts its biological effects through the activation of specific receptors. Most of them are G-protein coupled receptors (GPCRs) and belong to the 5-HTr, 5-HT2-, 5-HT4-, 5-HTs-, 5-HT6-, 5-HT7-receptor subfamilies. The 5-HT3-receptor is a ligand-operated ion channel. 

There are numerous transmitter substances. They include the amino acids glutamate, GABA and glycine acetylcholine the monoamines dopamine, noradrenaline and serotonin the neuropeptides ATP and NO. Many neurones use not a single transmitter but two or even more, a phenomenon called cotransmission. Chemical synaptic transmission hence is diversified. The basic steps, however, are similar across all neurones, irrespective of their transmitter, with the exception of NO transmitter production and vesicular storage transmitter release postsynaptic receptor activation and transmitter inactivation. Figure 1 shows an overview. Nitrergic transmission, i.e. transmission by NO, differs from transmission by other transmitters and is not covered in this essay. 

In contrast to the small transmitter molecules, the neuropeptides are synthesized in the rough endoplasmic reticulum of the neuronal perikarya. They are enclosed in vesicles in the Golgi apparatus. The vesicles travel down to the terminals by axonal transport. 

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