Proteopedia

Neurotransmitters

(Redirected from Neurotransmitter)

Acetylcholine

Acetylcholinesterase (EC 3.1.1.7, e.g. from Torpedo californica, TcAChE) hydrolysizes the neurotransmitter acetylcholine , producing group. ACh directly binds (via its nucleophilic Oγ atom) within the catalytic triad of (ACh/TcAChE structure 2ace). The residues are also important in the ligand recognition. After this binding acetylcholinesterase ACh.

Acetylcholine Receptors

Nicotinic acetylcholine receptors

The receptor is a transmembrane pentameric glycoprotein. It cylindrical in appearance by electron microscopy approximately 16nm in length and 8nm in diameter. The main ion channel is composed of a water pore that runs through the entire length of the protein. If viewed from the synaptic cleft, the protein will look like a pseudo-symmetrical rosette shown in the picture below composed of 10 different alpha and 4 different beta subunits.

  • .
  • .
  • .

When cobra venom is introduced into the body is moves along the bloodstream to a diaphragm muscle. It works as a postsynaptic neurotoxin binding to the receptor as an extracellular ligand by interacting with OH group leaving the acetylcholine channel open which releases ions used in creating an action potential. There must be 5 molecules of cobra toxin (red) to block the receptor (blue) as each molecule binds with an individual alpha chain on the acetylcholine receptor. The 2nd image depicts an individual toxin binding with one chain on the receptor, both in the same color. . This representation shows each molecule of the .

Muscarinic acetylcholine receptors

M1, M3, M5 receptors are coupled with Gq proteins, while M2 and M4 receptors are coupled with Gi/o proteins. They belong to GPCRs Subfamily A18.

Acetylcholinesterase

Alzheimer's Disease

Adenosine

at Human A2A receptor.

Adenosine receptors

Gs → cAMP up

Agonists:

  • N6-3-methoxyl-4-hydroxybenzyl adenine riboside (B2)
  • ATL-146e
  • CGS-21680
  • Regadenoson
  • Adenosine

Antagonists:

  • Caffeine
  • aminophylline
  • theophylline
  • istradefylline
  • SCH-58261
  • SCH-442,416
  • ZM-241,385

Adrenaline (Epinephrine)/Noradrenaline (Norepinephrine)

  • .
  • .
  • Phenylethanolamine N-methyltransferase (Noradrenaline N-Methyltransferase) catalyzes the conversion of norepinephrine (noradrenaline) to epinephrine (adrenaline). This is the last step in the conversion of tyrosine to adrenaline[1].

Adrenergic receptors in general

The adrenergic receptors are metabolic G protein-coupled receptors. They are the targets of catecholamines. The binding of an agonist to them causes a sympathetic response.

  • The α-2 adrenergic receptor (A2AR) inhibits insulin or glucagons release.
  • The β-1 adrenergic receptor (B1AR) increases cardiac output and secretion of rennin and ghrelin.[2]
  • The β-2 adrenergic receptor (B2AR) triggers many relaxation reactions.

β1 adrenergic receptor

β2 adrenergic receptor

β2-adrenergic agonists:

  • Beta blockers:
    • Butoxamine
    • Timolol
    • Propranolol
    • ICI-118,551
    • Paroxetine

Beta-adrenergic receptor kinase

Monoamine oxidases (MAO)

Monoamine oxidases (MAO) (EC 1.4.3.4) are a family of enzymes that catalyze the oxidation of monoamines including adrenaline, noradrenaline, serotonin and dopamine.

Monoamine oxidase

Monoamine oxidase b

Dopamine

DOPA decarboxylase

Dopamine Receptors

Dopamine receptors are a class of metabotropic G protein-coupled receptors that are important in the central nervous system. Dopamine receptors are involved in many neurological processes that comprise motivation, pleasure, cognition, memory, learning, and fine motor skills. There are five subtype dopamine receptors, D1, D2, D3, D4, and D5. The D3 receptor is a part of the D2-like family.[3]

Agonists

  • Amphetamine[4]
  • Methamphetamine[5]

Antagonists

  • Clebopride[6]
  • Nafadotride[7]
  • Eticlopride.

(3pbl).

.

Parkinson's disease

DOPA decarboxylase is responsible for the synthesis of dopamine and serotonin from L-DOPA and L-5-hydroxytryptophan, respectively. It is highly stereospecific, yet relatively nonspecific in terms of substrate, making it a somewhat uninteresting enzyme to study. Although it is not typically a rate-determining step of dopamine synthesis, the decarboxylation of L-DOPA to dopamine by DDC is the controlling step for individuals with Parkinson's disease[8], the second most common neurodegenerative disorder, occuring in 1% of the population over the age of 65. The loss of dopaminergic neurons is the main cause of cognitive impairment and tremors observed in patients with the disease. The hallmark of the disease is the formation of alpha-synuclein containing Lewy bodies.

Currently, treatment for the disease is aimed at DOPA decarboxylase inhibition. Since dopamine cannot cross the blood-brain barrier, it cannot be used to directly treat Parkinson's disease. Thus, exogenously administered L-DOPA is the primary treatment for patients suffering from this neurodegenerative disease. Unfortunately, DOPA decarboxylase rapidly converts L-DOPA to dopamine in the blood stream, with only a small percentage reaching the brain. By inhibiting the enzyme, greater amounts of exogenously administered L-DOPA can reach the brain, where it can then be converted to dopamine. [9]. Unfortunately, with continued L-Dopa treatment, up to 80% of patients experience 'wearing-off' symptoms, dyskinesias and other motor complications (referred to as the "on-off phenomenon". [10]. Clearly, a better understanding of the catalytic mechanism and enzymatic activity of DDC in both healthy and PD individuals is critical to drug design and treatment of the disease.

GABA

GABA receptors

GABA (i.e. gamma-aminobutyric acid) is the primary inhibitory neurotransmitter of the vertebrate central nervous system. GABA can bind one of two different receptor proteins, each using a discrete mechanism to elicit a cellular response. Upon binding with GABA, GABAB receptors (metabotropic) utilize a second messenger amplification pathway that ultimately results in an inhibitory signal for neuronal transmission. This pathway for signal transmission differs from GABAA receptors (ionotropic), which are considered ligand-gated ion channels as the binding of GABA results in the opening of ion channels leading to the inhibition of a neuronal signal.

(PDB code 4ms3).

GABA(A) receptor-associated protein

Glutamate

Glutamate receptors

  • .

Ionotropic Glutamate Receptors

Ionotropic Glutamate Receptors (IGluRs) are a family of ligand-gated ion channels that are responsible for fast excitatory neurotransmission.[11] Primarily localized to nerve synapses in mammals, IGluRs are implicated in nearly all aspects of nervous system development and function.[12] Synapses form the connection between two neuronal cells. Within synapses, neurotransmitters are released from vesicles in presynaptic cells and interact with receptors in postsynaptic cells to allow for communication between nerve cells.[11] GluR domains include the amino terminal domain (ATD), transmembrane domain (TMD) and ligand-binding domain (LBD). Glutamate is the predominant neurotransmitter of excitatory synapses and interacts specifically with AMPA and NMDA IGluRs.

  • AMPA receptor is a non-NMDA-type IGluR
  • Kainate receptor (GluK) is a non-NMDA-type IGluR which is activated by the agonist kainate.
  • NMDA receptor (NMDAR) is a IGluR which binds to the agonist NMDA. It contains subuntis NR1, NR2A, NR2B, NR2C, NR2D, NR3A, NR3B.
  • Ionotropic Glutamate Receptors
  • AMPA glutamate receptor

Full view of the glutamate receptor shows the overall structure (N-terminal, ligand-binding and transmembrane domains) in and models. is a part of the extracellular domain. This domain is implicated in receptor assembly, trafficking, and localization.

  • .
  • . This domain widens in response to glutamate binding allowing for positive ions to pass through the post-synaptic membrane.
  • .
  • .

Metabotropic Glutamate Receptors

Metabotropic glutamate receptors are glutamate receptors that activate ion channels indirectly through a signaling cascade involving G proteins[13]. They are members of the large class of seven-transmembrane domain receptors, the G protein-coupled receptors. Glutamate receptors are classified into 3 groups based on their homology, mechanism and pharmacological properties.

Histamine

.

Histamine receptors

Allergy symptoms are mostly caused by the release of histamine in response to allergens. The binding of histamine to the extracellular portion of the H1 receptor triggers a structural change of the transmembrane portion, leading to a change in the C terminal area. This c terminal region interacts with G proteins, leading to the activation of the Gq signalling pathway, which triggers allergy symptoms like itchy eyes and runny noses. Many allergy drugs are anti-histamines, in that they bind to the histamine receptor but do not cause the conformational change that leads to a response. The H1 receptor is a histamine receptor belonging to the family of rhodopsin-like G-protein-coupled receptors. The H1 receptor is linked to an intracellular G-protein (Gq) that activates phospholipase C (see Unique bidirectional interactions of Phospholipase C beta 3 with G alpha Q and the inositol triphosphate (IP3) signalling pathway. When a ligand binds to a G protein-coupled receptor that is coupled to a Gq heterotrimeric G protein, the α-subunit of Gq can bind to and induce activity in the PLC isozyme PLC-β, which results in the cleavage of PIP2 into IP3 and DAG.

Neurotensin

Neurotensin receptors

The neurotensin receptor (NTSR1) belongs to the superfamily of proteins known as G protein-coupled receptors (GPCRs). Currently around 800 G protein-coupled receptors have been identified and are hypothesized to be responsible for roughly 80% of signal transduction.[14] GPCRs are involved in a vast array of physiological processes within the body that range from interactions with dopamine to effects on secretion of bile in the intestines.[15] [16] Due to the vast array of functions that these proteins serve and their high abundance within the body, these proteins have become major drug targets.[17]

The ligand for NTSR1 is the 13 amino acid peptide, neurotensin (NTS)[18], and the majority of the effects of NTS are mediated through NTSR1[18]. NTS has a variety of biological activities including a role in the leptin signaling pathways [19], tumor growth [20], and dopamine regulation [21]. NTSR1 was crystallized bound with a C-terminal portion of its tridecapeptide ligand, . The shortened ligand was used because of oits higher potency and efficacy than its full-length counterpart[18].

Like other G protein-coupled receptors, NTSR1 is composed of 3 distinct regions. An where neurotensin binds and causes a conformational change of the protein. A region containing (PDB code:4GRV) that transduce the signal from the extracellular side of the cell membrane to the intracellular side. Lastly, an intracellular region that when activated by a conformational change in the protein activates a G-protein associated with this receptor.

The in NTSR1 is located at the top of the protein (Figure 1). NTSR1 also contains an allosteric , which is located directly beneath the ligand binding pocket and the two pockets, which are separated by the residue [22]. NTSR1 has been mutated to exist in both and states.

Serotonin

Serotonin receptors

5-hydroxytryptamine (5-HT), Serotonin receptors are found on the membrane of neurons in the central nervous system and peripheral nervous system. These receptors allow for the body to respond to serotonin and regulate many biological pathways. Serotonin, also known as 5 hydroxytryptamine, is an endogenous neurotransmitter made from tryptophan and is largely found in the gastrointestinal tract. It is known to regulate mood, appetite, digestion, circadian rhythm, learning and internal temperature regulation. It is can be an inhibitory or excitatory neurotransmitter that is released into the synaptic space and can bind to receptors on the postsynaptic neuron or be taken back up into the presynaptic neuron via Serotonin re-uptake transporters.[23] 5-HT receptors are classified into 7 different subfamilies (5-HT1, 5-HT2, 5-HT3, etc.) by signaling mechanisms and homology of structure. All 5-HT receptors are known to have G-protein linked pathways except for the 5-HT3 receptor which acts as an ion channel. [24]

Serotonin receptors, main page

3D structures of Serotonin receptors

5-HT3A receptor

Serotonin Transporter

See also Serotonin N-acetyltransferase

Drag the structure with the mouse to rotate

ReferencesReferences

  1. Martin JL, Begun J, McLeish MJ, Caine JM, Grunewald GL. Getting the adrenaline going: crystal structure of the adrenaline-synthesizing enzyme PNMT. Structure. 2001 Oct;9(10):977-85. PMID:11591352
  2. Huang J, Chen S, Zhang JJ, Huang XY. Crystal structure of oligomeric beta1-adrenergic G protein-coupled receptors in ligand-free basal state. Nat Struct Mol Biol. 2013 Apr;20(4):419-25. doi: 10.1038/nsmb.2504. Epub 2013 Feb, 24. PMID:23435379 doi:10.1038/nsmb.2504
  3. Girault JA, Greengard P. The neurobiology of dopamine signaling. Arch Neurol. 2004 May;61(5):641-4. PMID:15148138 doi:10.1001/archneur.61.5.641
  4. Jones S, Kornblum JL, Kauer JA (August 2000). "Amphetamine blocks long-term synaptic depression in the ventral tegmental area". J. Neurosci. 20 (15): 5575–80. PMID 10908593. http://www.jneurosci.org/cgi/pmidlookup?view=long&pmid=10908593.
  5. Cruickshank, CC.; Dyer, KR. (Jul 2009). "A review of the clinical pharmacology of methamphetamine.". Addiction 104 (7): 1085–99. doi:10.1111/j.1360-0443.2009.02564.x. PMID 19426289.
  6. Cuena Boy R, Maciá Martínez MA (1998). "[Extrapyramidal toxicity caused by metoclopramide and clebopride: study of voluntary notifications of adverse effects to the Spanish Drug Surveillance System]" (in Spanish). Atencion Primaria 21 (5): 289–95. PMID 9608114. Free full text
  7. Pilla M, Perachon S, Sautel F, Garrido F, Mann A, Wermuth CG, Schwartz JC, Everitt BJ, Sokoloff P. Selective inhibition of cocaine-seeking behaviour by a partial dopamine D3 agonist. Nature. 1999;400:371–375.
  8. Miles EW. The tryptophan synthase alpha 2 beta 2 complex. Cleavage of a flexible loop in the alpha subunit alters allosteric properties. J Biol Chem. 1991 Jun 15;266(17):10715-8. PMID:1904055
  9. Burkhard P, Dominici P, Borri-Voltattorni C, Jansonius JN, Malashkevich VN. Structural insight into Parkinson's disease treatment from drug-inhibited DOPA decarboxylase. Nat Struct Biol. 2001 Nov;8(11):963-7. PMID:11685243 doi:http://dx.doi.org/10.1038/nsb1101-963
  10. Miles EW. The tryptophan synthase alpha 2 beta 2 complex. Cleavage of a flexible loop in the alpha subunit alters allosteric properties. J Biol Chem. 1991 Jun 15;266(17):10715-8. PMID:1904055
  11. 11.0 11.1 Jin R, Clark S, Weeks AM, Dudman JT, Gouaux E, Partin KM. Mechanism of positive allosteric modulators acting on AMPA receptors. J Neurosci. 2005 Sep 28;25(39):9027-36. PMID:16192394 doi:25/39/9027
  12. Sobolevsky AI, Rosconi MP, Gouaux E. X-ray structure, symmetry and mechanism of an AMPA-subtype glutamate receptor. Nature. 2009 Dec 10;462(7274):745-56. Epub . PMID:19946266 doi:10.1038/nature08624
  13. Traynelis SF, Wollmuth LP, McBain CJ, Menniti FS, Vance KM, Ogden KK, Hansen KB, Yuan H, Myers SJ, Dingledine R. Glutamate receptor ion channels: structure, regulation, and function. Pharmacol Rev. 2010 Sep;62(3):405-96. doi: 10.1124/pr.109.002451. PMID:20716669 doi:http://dx.doi.org/10.1124/pr.109.002451
  14. Millar RP, Newton CL. The year in G protein-coupled receptor research. Mol Endocrinol. 2010 Jan;24(1):261-74. Epub 2009 Dec 17. PMID:20019124 doi:10.1210/me.2009-0473
  15. Gui X, Carraway RE. Enhancement of jejunal absorption of conjugated bile acid by neurotensin in rats. Gastroenterology. 2001 Jan;120(1):151-60. PMID:11208724
  16. Selivonenko VG. [The interrelationship between electrolytes and phase analysis of systole in toxic goiter]. Probl Endokrinol (Mosk). 1975 Jan-Feb;21(1):19-23. PMID:1173461
  17. Fang Y, Lahiri J, Picard L. G protein-coupled receptor microarrays for drug discovery. Drug Discov Today. 2004 Dec 15;9(24 Suppl):S61-7. PMID:23573662
  18. 18.0 18.1 18.2 White JF, Noinaj N, Shibata Y, Love J, Kloss B, Xu F, Gvozdenovic-Jeremic J, Shah P, Shiloach J, Tate CG, Grisshammer R. Structure of the agonist-bound neurotensin receptor. Nature. 2012 Oct 25;490(7421):508-13. doi: 10.1038/nature11558. Epub 2012 Oct 10. PMID:23051748 doi:http://dx.doi.org/10.1038/nature11558
  19. Liang Y, Boules M, Li Z, Williams K, Miura T, Oliveros A, Richelson E. Hyperactivity of the dopaminergic system in NTS1 and NTS2 null mice. Neuropharmacology. 2010 Jun;58(8):1199-205. doi:, 10.1016/j.neuropharm.2010.02.015. Epub 2010 Mar 6. PMID:20211191 doi:http://dx.doi.org/10.1016/j.neuropharm.2010.02.015
  20. Carraway RE, Plona AM. Involvement of neurotensin in cancer growth: evidence, mechanisms and development of diagnostic tools. Peptides. 2006 Oct;27(10):2445-60. Epub 2006 Aug 2. PMID:16887236 doi:http://dx.doi.org/10.1016/j.peptides.2006.04.030
  21. Griebel G, Holsboer F. Neuropeptide receptor ligands as drugs for psychiatric diseases: the end of the beginning? Nat Rev Drug Discov. 2012 May 18;11(6):462-78. doi: 10.1038/nrd3702. PMID:22596253 doi:http://dx.doi.org/10.1038/nrd3702
  22. Krumm BE, White JF, Shah P, Grisshammer R. Structural prerequisites for G-protein activation by the neurotensin receptor. Nat Commun. 2015 Jul 24;6:7895. doi: 10.1038/ncomms8895. PMID:26205105 doi:http://dx.doi.org/10.1038/ncomms8895
  23. Goodsell D. Serotonin Receptor. RCSB PDB-101 (2013) DOI: 10.2210/rcsb_pdb/mom_2013_8
  24. Wang C, Jiang Y, Ma J, Wu H, Wacker D, Katritch V, Han GW, Liu W, Huang XP, Vardy E, McCorvy JD, Gao X, Zhou EZ, Melcher K, Zhang C, Bai F, Yang H, Yang L, Jiang H, Roth BL, Cherezov V, Stevens RC, Xu HE. Structural Basis for Molecular Recognition at Serotonin Receptors. Science. 2013 May 3; 340(6132): 610–614. PMID:3644373 [1]

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