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Quisqualic acid

January 01, 1970

Quisqualic acid is an agonist of the AMPA, kainate, and group I metabotropic glutamate receptors. It is one of the most potent AMPA receptor agonists known.[2][3][4][5] It causes excitotoxicity and is used in neuroscience to selectively destroy neurons in the brain or spinal cord.[6][7][8] Quisqualic acid occurs naturally in the seeds of Quisqualis species.

Quisqualic acid
Names
IUPAC name
3-(3,5-Dioxo-1,2,4-oxadiazolidin-2-yl)-L-alanine
Systematic IUPAC name
(2S)-2-Amino-3-(3,5-dioxo-1,2,4-oxadiazolidin-2-yl)propanoic acid
Identifiers
  • 52809-07-1 Y
3D model (JSmol)
  • Interactive image
ChEMBL
  • ChEMBL279956 Y
ChemSpider
  • 37038 Y
DrugBank
  • DB02999 Y
ECHA InfoCard 100.164.809
EC Number
  • 637-070-2
  • 1372
  • 1370
KEGG
  • C08296 Y
MeSH Quisqualic+Acid
  • 40539
UNII
  • 8OC22C1B99 Y
  • DTXSID20896927
  • InChI=1S/C5H7N3O5/c6-2(3(9)10)1-8-4(11)7-5(12)13-8/h2H,1,6H2,(H,9,10)(H,7,11,12)/t2-/m0/s1 Y
    Key: ASNFTDCKZKHJSW-REOHCLBHSA-N Y
  • InChI=1/C5H7N3O5/c6-2(3(9)10)1-8-4(11)7-5(12)13-8/h2H,1,6H2,(H,9,10)(H,7,11,12)/t2-/m0/s1
    Key: ASNFTDCKZKHJSW-REOHCLBHBE
  • O=C1NC(=O)ON1C[C@H](N)C(=O)O
Properties
C5H7N3O5
Molar mass 189.126 g/mol
Melting point 187 to 188 °C (369 to 370 °F; 460 to 461 K) decomposes
Hazards
GHS labelling:[1]
Warning
H302, H312, H332
P261, P264, P270, P271, P280, P301+P317, P302+P352, P304+P340, P317, P321, P330, P362+P364, P501
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)

Research conducted by the USDA Agricultural Research Service, has demonstrated quisqualic acid is also present within the flower petals of zonal geranium (Pelargonium x hortorum) and is responsible for causing rigid paralysis of the Japanese beetle.[9][10] Quisqualic acid is thought to mimic L-glutamic acid, which is a neurotransmitter in the insect neuromuscular junction and mammalian central nervous system.[11]

History edit

Combretum indicum (Quisqualis indica var. villosa) is native to tropical Asia but is still doubt whether is indigenous from Africa or was introduced there. Since the amino acid that can be isolated from its fruits can nowadays be made in the lab, the plant is mostly cultivated as an ornamental plant.  

Its fruits are known for having anthelmintic effect, therefore they are used to treat ascariasis. The dried seeds are used to reduce vomiting and to stop diarrhoea, but an oil extracted from the seeds can have purgative properties. The roots are taken as a vermifuge and leaf juice, softened in oil, are applied to treat ulcers, parasitic skin infections or fever.  

The plant is used for pain relief, and in the Indian Ocean islands, a decoction of the leaves is used to bath children with eczema. In the Philippines, people chew the fruits to get rid of the cough and the crushed fruits and seeds are applied to ameliorate nephritis. In Vietnam, they use the root of the plant to treat rheumatism. In Papua New Guinea the plants are taken as a contraceptive medicine.  

However the plant does not have just medicinal use. In west Africa, the long and elastic stems are used for fish weir, fish traps and basketry. The flowers are edible, and they are added in salads to add color.  

The seed oil contains palmitic, oleic, stearic, linoleic, myristic and arachidonic acid. The flowers are rich in the flavonoid glycosides pelargonidin – 3 – glucoside and rutin. The leaves and stem bark are rich in tannins, while from the leafy stem several diphenylpropanoids were isolated.  

The active compound (quisqualic acid) resembles the action of the anthelmintic α-santonin, so in some countries the seeds of the plants are used to substitute for the drug. However, the acid has shown excitatory effects on cultured neurons, as well as in a variety of animal models, as it causes several types of limbic seizures and neuronal necrosis.[12]

The quisqualic acid can be now commercially synthesized, and it functions as an antagonist for its receptor, found in the mammalian central nervous system.[12]

Chemistry edit

Structure edit

It is an organic compound, associated with the class of L – alpha – amino acids. These compounds have the L configuration of the alpha carbon atom.  

Quisqualic acid contains, in its structure a five membered, planar, conjugated, aromatic heterocyclic system, consisting of one oxygen atom and two nitrogen atoms at position 2 and 4 of the oxadiazole ring.   The 1,2,4–oxadiazole ring structure is present in many natural products of pharmacological importance. Quisqualic acid, which is extracted from the seeds of Quisqualis indica is a strong antagonist of the α–amino–3–hydroxy–5–methyl–4–isoxazolepropionic acid receptors.[13]

Reactivity and synthesis edit

Biosynthesis edit

L – quisqualic acid is a glutamate receptor agonist, acting at AMPA receptors and metabotropic glutamate receptors positively linked to phosphoinositide hydrolysis. It sensitizes neurons in hippocampus to depolarization by L-AP6.[14]

Being a 3, 5 disubstituted oxadiazole, quisqualic acid is a stable compound.[15]

One way of synthesizing quisqualic acid is by enzymatic synthesis. Therefore, cysteine synthase is purified from the leaves of Quisqualis indica var. villosa, showing two forms of this enzyme. Both isolated isoenzymes catalyse the formation of cysteine from O-acetyl-L-serine and hydrogen sulphide, but only one of them catalyses the formation of L – quisqualic acid.[16]

Industrial synthesis edit

Another way of synthesizing the product is by having L-serine as starting material.  

Initial step in synthesis is the conversion of L-serine to its N-t-butoxycarbonyl derivative. Amine group of serine has to be protected, so di-tert-butyldicarbonate in isopropanol and aqueous sodium hydroxide was added, at room temperature. The result of the reaction is the N-t-Boc protected acid. Acylation of this acid with O-benzylhydroxylamine hydrochloride followed. T-Boc protected serine was treated with one equivalent of isobutyl chloroformate and N-methylmorpholine in dry THF, resulting in mixed anhydride. This than reacts with O – benzylhydroxylamine to give the hydroxamate. The hydroxamate proceeds to be converted into β – lactam, which was hydrolyzed to the hydroxylamino acid (77) by treatment with one equivalent of sodium hydroxide. After acidification with saturated aqueous solution of citric acid, the final product, L-quisqualic acid, was isolated.[17]

Functions edit

Molecular mechanisms of action edit

Quisqualic acid is functionally similar to glutamate, which is an endogenous agonist of glutamate's receptors. It functions as a neurotransmitter in insect neuromuscular junction and CNS.  It passes the blood brain barrier and binds to cell surface receptors AMPA and Kainate receptors in the brain. 

AMPA receptor is a type of ionotropic glutamate receptor coupled to ion channels and when bound to a ligand, it modulates the excitability by gating the flow of calcium and sodium ions into the intracellular domain.[18] On the other hand, kainate receptors are less understood than AMPA receptors. Although, the function is somewhat similar: the ion channel permeates the flow of sodium and potassium ions, and to a lower extent the Calcium ions.[citation needed]

As mentioned, binding of quisqualic acid to these receptors leads to an influx of calcium and sodium ions into the neurons, which triggers downstream signaling cascades. Calcium signaling involves protein effectors such as kinases (CaMK, MAPK/ERKs), CREB-transcription factor and various phosphatases. It regulates gene expression and may modify the properties of the receptors.[19]

 Sodium and calcium ions together generate an excitatory postsynaptic potential (EPSP) that triggers action potentials. It's worthwhile to mention that overactivation of glutamate receptors and kainate receptors lead to excitotoxicity and neurological damage.[19]

A greater dose of quisqualic acid over activates these receptors that can induce seizures, due to prolonged action potentials firing the neurons. Quisqualic acid is also associated with various neurological disorders such as epilepsy and stroke.[20]

Metabotropic glutamate receptors, also known as mGluRs are a type of glutamate receptor which are members of the G-protein coupled receptors. These receptors are important in neural communication, memory formation, learning and regulation. Like Glutamate, quisqualic acid binds to this receptor and shows even a higher potency, mainly for mGlu1 and mGlu5 and exert its effects through a complex second messenger system.[21] Activation of these receptors leads to an increase in inositol triphosphate (IP3) and diacylglycerol (DAG) by the activation of phospholipase C (PLC). Eventually, IP3 diffuses to bind to IP3 receptors on the ER, which are calcium channels that eventually increase the Calcium concentration in the cell.[22]

Modulation of NMDA receptor edit

The effects of quisqualic acid depend on the location and context. These 2 receptors are known to potentiate the activity of N-methyl-D-aspartate receptors (NMDARs), a certain type of ion channel that is a neurotoxic. Excessive amounts of NMDA have been found to cause harm to the neurons in the presence of mGlu1 and mGlu5 receptors.[23]

Effects on plasticity edit

Activation of group 1 mGluRs are implicated in synaptic plasticity and contribute to both neurotoxicity and neuroprotection such as protection of the retina against NMDA toxicity, mentioned above.[24] It causes a reduction in ZENK expression, which leads to myopia in chicken.[25]

Role in disease  edit

Studies on mice have suggested that mGlu1 may be involved in the development of certain cancers.[26] Knowing that these types of receptors are mostly localized in the thalamus, hypothalamus and caudate nucleus regions of the brain, the overactivation of these receptors by quisqualic acid can suggest a potential role in movement disorders. 

Family Type Mechanism
AMPA ionotropic Increase membrane permeability for sodium, calcium, and potassium
Kainate ionotropic Increase membrane permeability for sodium and potassium
NMDA ionotropic Increase membrane permeability for calcium
Metabotropic Group 1 G-coupled proteins Activation of phospholipase C: increase of IP3 and DAG

Use/purpose, availability, efficacy, side effects/ adverse effects edit

Quisqualic acid is an excitatory amino acid (EAA) and a potent agonist of metabotropic glutamate receptors, where evidence shows that activation of these receptors may cause a long lasting sensitization of neurons to depolarization, a phenomenon called the “Quis effect ”.[27]

The first uses of quisqualic acid in research date back to 1975,[28] where the first description of the acid noted that it had strong excitatory effects in the spinal cords of frogs and rats as well as on the neuromuscular junction in crayfish.[17] Since then, its main use in research has been as template for excitotoxic models of spinal cord injury (SCI) studies. When injected into the spinal cord, quisqualic acid can cause excessive activation of glutamate receptors, leading to neuronal damage and loss.[29] This excitotoxic model has been used to study the mechanisms of SCI and to develop potential treatments for related conditions. Several studies have demonstrated experimentally the similarity between the pathology and symptoms of SCI induced by quisqualic acid injections and those observed in clinical spinal cord injuries.[29][30]

After administration of quis-injection, spinal neurons located close to areas of neuronal degeneration and cavitation exhibit a decrease in mechanical threshold, meaning they become more sensitive to mechanical stimuli. This heightened sensitivity is accompanied by prolonged after discharge responses. These results suggest that excitatory amino acid agonists can induce morphological changes in the spinal cord, which can lead to physiological changes in adjacent neurons, ultimately resulting in altered mechanosensitivity.[29][31]

There is evidence to suggest that excitatory amino acids like quisqualic acid play a significant role in the induction of cell death following stroke, hypoxia-ischemia, and traumatic brain injury .[29][32][33]

Studies involving the binding of quisqualic acid have indicated that the amino acid does not show selectivity for a singular specific receptor subtype, which was initially identified as the quisqualate receptor.[28] Instead, it demonstrates high affinity for other types of excitatory amino acid receptors, including kainate, AMPA, and metabotropic receptors, as well as some transport sites, such as the chloride-dependent L-AP4-sensitive sites. In addition, it also exhibits affinity for certain enzymes responsible for cleaving dipeptides, including the enzyme responsible for cleaving N-acetyl-aspartylglutamate (NAALADase) .[28][34]

Regarding bioavailability, no database information is present, as there is limited research on its pharmacokinetics. However, even though the bioavailability is not well established, studies in rats suggest that age may play a role in the presence of administered quisqualic acid effects. An experiment which was done on rats within two age groups (20-days-old and 60-days-old) showed that, when given quisqualic acid microinjections, 60-day-old rats had more seizures compared to the younger rats. Additionally, the rats were given the same amount of quisqualic acid, however the immature animals received a higher dosage per body weight, implying that the harm inflicted by the excitatory amino acid may have been comparatively lower in the younger animals.[35]

Quisqualic acid has not been used in clinical trials and currently has no medicinal use,[36] therefore no information about adverse or side effects has been reported. 

There has been a significant decrease in research done on quisqualic acid after the early 2000s, possibly attributed to a lack of specificity and/or lack of other clinical uses apart from SCI investigations, which have progressed with other methods of research.[36]

Metabolism/Biotransformation edit

Quisqualic acid enters the body through different routes, such as ingestion, inhalation, or injection. The ADME (absorption, distribution, metabolism and excretion) process has been studied by means of various animal models in the laboratory. 

Absorption: quisqualic acid is a small and lipophilic molecule, thus is expected to be rapid. It is predicted to be absorbed in the human intestine and from then it circulates to the blood brain barrier.[35] Analysis of amino acid transport systems is complex by the presence of multiple transporters with overlapping specificity. Since glutamate and quisqualic acid are similar, it is predicted that sodium/potassium transport in the gastrointestinal tract is the absorption site of the acid. 

Distribution: knowing the receptors it binds to, it can be readily predicted where the acid is present such as: hippocampus, basal ganglia, olfactory regions. 

Metabolism: quisqualic acid is thought to be metabolized in the liver by oxidative metabolism carried out by cytochrome P450 enzymes, Glutathione S-transferase (detoxifying agents). A study showed that the exposure to quisqualic acid revealed that P450, GST were involved.[37] It is also confirmed by using admetSAR tool to evaluate chemical ADMET properties.[35] Its metabolites are thought to be NMDA and quinolinic acid. 

Excretion: Mostly, as a rule of thumb, amino acids undergo transamination/deamination in the liver. Thus amino acids are converted into ammonia and keto acids, which are eventually excreted via the kidneys. 

It is worth mentioning that the pharmacokinetics of quisqualic acid has not been extensively studied and there is sparse information available on its ADME process. Therefore, more research is needed to fully understand the metabolism of the acid in the body. 

See also edit

References edit

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January 01, 1970
quisqualic, acid, agonist, ampa, kainate, group, metabotropic, glutamate, receptors, most, potent, ampa, receptor, agonists, known, causes, excitotoxicity, used, neuroscience, selectively, destroy, neurons, brain, spinal, cord, occurs, naturally, seeds, quisqu. Quisqualic acid is an agonist of the AMPA kainate and group I metabotropic glutamate receptors It is one of the most potent AMPA receptor agonists known 2 3 4 5 It causes excitotoxicity and is used in neuroscience to selectively destroy neurons in the brain or spinal cord 6 7 8 Quisqualic acid occurs naturally in the seeds of Quisqualis species Quisqualic acid Names IUPAC name 3 3 5 Dioxo 1 2 4 oxadiazolidin 2 yl L alanine Systematic IUPAC name 2S 2 Amino 3 3 5 dioxo 1 2 4 oxadiazolidin 2 yl propanoic acid Identifiers CAS Number 52809 07 1 Y 3D model JSmol Interactive image ChEMBL ChEMBL279956 Y ChemSpider 37038 Y DrugBank DB02999 Y ECHA InfoCard 100 164 809 EC Number 637 070 2 IUPHAR BPS 13721370 KEGG C08296 Y MeSH Quisqualic Acid PubChem CID 40539 UNII 8OC22C1B99 Y CompTox Dashboard EPA DTXSID20896927 InChI InChI 1S C5H7N3O5 c6 2 3 9 10 1 8 4 11 7 5 12 13 8 h2H 1 6H2 H 9 10 H 7 11 12 t2 m0 s1 YKey ASNFTDCKZKHJSW REOHCLBHSA N YInChI 1 C5H7N3O5 c6 2 3 9 10 1 8 4 11 7 5 12 13 8 h2H 1 6H2 H 9 10 H 7 11 12 t2 m0 s1Key ASNFTDCKZKHJSW REOHCLBHBE SMILES O C1NC O ON1C C H N C O O Properties Chemical formula C5H7N3O5 Molar mass 189 126 g mol Melting point 187 to 188 C 369 to 370 F 460 to 461 K decomposes Hazards GHS labelling 1 Pictograms Signal word Warning Hazard statements H302 H312 H332 Precautionary statements P261 P264 P270 P271 P280 P301 P317 P302 P352 P304 P340 P317 P321 P330 P362 P364 P501 Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa N verify what is Y N Infobox references Research conducted by the USDA Agricultural Research Service has demonstrated quisqualic acid is also present within the flower petals of zonal geranium Pelargonium x hortorum and is responsible for causing rigid paralysis of the Japanese beetle 9 10 Quisqualic acid is thought to mimic L glutamic acid which is a neurotransmitter in the insect neuromuscular junction and mammalian central nervous system 11 Contents 1 History 2 Chemistry 2 1 Structure 2 2 Reactivity and synthesis 2 2 1 Biosynthesis 2 2 2 Industrial synthesis 3 Functions 3 1 Molecular mechanisms of action 3 1 1 Modulation of NMDA receptor 3 1 2 Effects on plasticity 3 1 3 Role in disease 3 2 Use purpose availability efficacy side effects adverse effects 4 Metabolism Biotransformation 5 See also 6 ReferencesHistory editCombretum indicum Quisqualis indica var villosa is native to tropical Asia but is still doubt whether is indigenous from Africa or was introduced there Since the amino acid that can be isolated from its fruits can nowadays be made in the lab the plant is mostly cultivated as an ornamental plant Its fruits are known for having anthelmintic effect therefore they are used to treat ascariasis The dried seeds are used to reduce vomiting and to stop diarrhoea but an oil extracted from the seeds can have purgative properties The roots are taken as a vermifuge and leaf juice softened in oil are applied to treat ulcers parasitic skin infections or fever The plant is used for pain relief and in the Indian Ocean islands a decoction of the leaves is used to bath children with eczema In the Philippines people chew the fruits to get rid of the cough and the crushed fruits and seeds are applied to ameliorate nephritis In Vietnam they use the root of the plant to treat rheumatism In Papua New Guinea the plants are taken as a contraceptive medicine However the plant does not have just medicinal use In west Africa the long and elastic stems are used for fish weir fish traps and basketry The flowers are edible and they are added in salads to add color The seed oil contains palmitic oleic stearic linoleic myristic and arachidonic acid The flowers are rich in the flavonoid glycosides pelargonidin 3 glucoside and rutin The leaves and stem bark are rich in tannins while from the leafy stem several diphenylpropanoids were isolated The active compound quisqualic acid resembles the action of the anthelmintic a santonin so in some countries the seeds of the plants are used to substitute for the drug However the acid has shown excitatory effects on cultured neurons as well as in a variety of animal models as it causes several types of limbic seizures and neuronal necrosis 12 The quisqualic acid can be now commercially synthesized and it functions as an antagonist for its receptor found in the mammalian central nervous system 12 Chemistry editStructure edit It is an organic compound associated with the class of L alpha amino acids These compounds have the L configuration of the alpha carbon atom Quisqualic acid contains in its structure a five membered planar conjugated aromatic heterocyclic system consisting of one oxygen atom and two nitrogen atoms at position 2 and 4 of the oxadiazole ring The 1 2 4 oxadiazole ring structure is present in many natural products of pharmacological importance Quisqualic acid which is extracted from the seeds of Quisqualis indica is a strong antagonist of the a amino 3 hydroxy 5 methyl 4 isoxazolepropionic acid receptors 13 Reactivity and synthesis edit Biosynthesis edit L quisqualic acid is a glutamate receptor agonist acting at AMPA receptors and metabotropic glutamate receptors positively linked to phosphoinositide hydrolysis It sensitizes neurons in hippocampus to depolarization by L AP6 14 Being a 3 5 disubstituted oxadiazole quisqualic acid is a stable compound 15 One way of synthesizing quisqualic acid is by enzymatic synthesis Therefore cysteine synthase is purified from the leaves of Quisqualis indica var villosa showing two forms of this enzyme Both isolated isoenzymes catalyse the formation of cysteine from O acetyl L serine and hydrogen sulphide but only one of them catalyses the formation of L quisqualic acid 16 Industrial synthesis edit Another way of synthesizing the product is by having L serine as starting material Initial step in synthesis is the conversion of L serine to its N t butoxycarbonyl derivative Amine group of serine has to be protected so di tert butyldicarbonate in isopropanol and aqueous sodium hydroxide was added at room temperature The result of the reaction is the N t Boc protected acid Acylation of this acid with O benzylhydroxylamine hydrochloride followed T Boc protected serine was treated with one equivalent of isobutyl chloroformate and N methylmorpholine in dry THF resulting in mixed anhydride This than reacts with O benzylhydroxylamine to give the hydroxamate The hydroxamate proceeds to be converted into b lactam which was hydrolyzed to the hydroxylamino acid 77 by treatment with one equivalent of sodium hydroxide After acidification with saturated aqueous solution of citric acid the final product L quisqualic acid was isolated 17 Functions editMolecular mechanisms of action edit Quisqualic acid is functionally similar to glutamate which is an endogenous agonist of glutamate s receptors It functions as a neurotransmitter in insect neuromuscular junction and CNS It passes the blood brain barrier and binds to cell surface receptors AMPA and Kainate receptors in the brain AMPA receptor is a type of ionotropic glutamate receptor coupled to ion channels and when bound to a ligand it modulates the excitability by gating the flow of calcium and sodium ions into the intracellular domain 18 On the other hand kainate receptors are less understood than AMPA receptors Although the function is somewhat similar the ion channel permeates the flow of sodium and potassium ions and to a lower extent the Calcium ions citation needed As mentioned binding of quisqualic acid to these receptors leads to an influx of calcium and sodium ions into the neurons which triggers downstream signaling cascades Calcium signaling involves protein effectors such as kinases CaMK MAPK ERKs CREB transcription factor and various phosphatases It regulates gene expression and may modify the properties of the receptors 19 Sodium and calcium ions together generate an excitatory postsynaptic potential EPSP that triggers action potentials It s worthwhile to mention that overactivation of glutamate receptors and kainate receptors lead to excitotoxicity and neurological damage 19 A greater dose of quisqualic acid over activates these receptors that can induce seizures due to prolonged action potentials firing the neurons Quisqualic acid is also associated with various neurological disorders such as epilepsy and stroke 20 Metabotropic glutamate receptors also known as mGluRs are a type of glutamate receptor which are members of the G protein coupled receptors These receptors are important in neural communication memory formation learning and regulation Like Glutamate quisqualic acid binds to this receptor and shows even a higher potency mainly for mGlu1 and mGlu5 and exert its effects through a complex second messenger system 21 Activation of these receptors leads to an increase in inositol triphosphate IP3 and diacylglycerol DAG by the activation of phospholipase C PLC Eventually IP3 diffuses to bind to IP3 receptors on the ER which are calcium channels that eventually increase the Calcium concentration in the cell 22 Modulation of NMDA receptor edit The effects of quisqualic acid depend on the location and context These 2 receptors are known to potentiate the activity of N methyl D aspartate receptors NMDARs a certain type of ion channel that is a neurotoxic Excessive amounts of NMDA have been found to cause harm to the neurons in the presence of mGlu1 and mGlu5 receptors 23 Effects on plasticity edit Activation of group 1 mGluRs are implicated in synaptic plasticity and contribute to both neurotoxicity and neuroprotection such as protection of the retina against NMDA toxicity mentioned above 24 It causes a reduction in ZENK expression which leads to myopia in chicken 25 Role in disease edit Studies on mice have suggested that mGlu1 may be involved in the development of certain cancers 26 Knowing that these types of receptors are mostly localized in the thalamus hypothalamus and caudate nucleus regions of the brain the overactivation of these receptors by quisqualic acid can suggest a potential role in movement disorders Family Type Mechanism AMPA ionotropic Increase membrane permeability for sodium calcium and potassium Kainate ionotropic Increase membrane permeability for sodium and potassium NMDA ionotropic Increase membrane permeability for calcium Metabotropic Group 1 G coupled proteins Activation of phospholipase C increase of IP3 and DAG Use purpose availability efficacy side effects adverse effects edit Quisqualic acid is an excitatory amino acid EAA and a potent agonist of metabotropic glutamate receptors where evidence shows that activation of these receptors may cause a long lasting sensitization of neurons to depolarization a phenomenon called the Quis effect 27 The first uses of quisqualic acid in research date back to 1975 28 where the first description of the acid noted that it had strong excitatory effects in the spinal cords of frogs and rats as well as on the neuromuscular junction in crayfish 17 Since then its main use in research has been as template for excitotoxic models of spinal cord injury SCI studies When injected into the spinal cord quisqualic acid can cause excessive activation of glutamate receptors leading to neuronal damage and loss 29 This excitotoxic model has been used to study the mechanisms of SCI and to develop potential treatments for related conditions Several studies have demonstrated experimentally the similarity between the pathology and symptoms of SCI induced by quisqualic acid injections and those observed in clinical spinal cord injuries 29 30 After administration of quis injection spinal neurons located close to areas of neuronal degeneration and cavitation exhibit a decrease in mechanical threshold meaning they become more sensitive to mechanical stimuli This heightened sensitivity is accompanied by prolonged after discharge responses These results suggest that excitatory amino acid agonists can induce morphological changes in the spinal cord which can lead to physiological changes in adjacent neurons ultimately resulting in altered mechanosensitivity 29 31 There is evidence to suggest that excitatory amino acids like quisqualic acid play a significant role in the induction of cell death following stroke hypoxia ischemia and traumatic brain injury 29 32 33 Studies involving the binding of quisqualic acid have indicated that the amino acid does not show selectivity for a singular specific receptor subtype which was initially identified as the quisqualate receptor 28 Instead it demonstrates high affinity for other types of excitatory amino acid receptors including kainate AMPA and metabotropic receptors as well as some transport sites such as the chloride dependent L AP4 sensitive sites In addition it also exhibits affinity for certain enzymes responsible for cleaving dipeptides including the enzyme responsible for cleaving N acetyl aspartylglutamate NAALADase 28 34 Regarding bioavailability no database information is present as there is limited research on its pharmacokinetics However even though the bioavailability is not well established studies in rats suggest that age may play a role in the presence of administered quisqualic acid effects An experiment which was done on rats within two age groups 20 days old and 60 days old showed that when given quisqualic acid microinjections 60 day old rats had more seizures compared to the younger rats Additionally the rats were given the same amount of quisqualic acid however the immature animals received a higher dosage per body weight implying that the harm inflicted by the excitatory amino acid may have been comparatively lower in the younger animals 35 Quisqualic acid has not been used in clinical trials and currently has no medicinal use 36 therefore no information about adverse or side effects has been reported There has been a significant decrease in research done on quisqualic acid after the early 2000s possibly attributed to a lack of specificity and or lack of other clinical uses apart from SCI investigations which have progressed with other methods of research 36 Metabolism Biotransformation editQuisqualic acid enters the body through different routes such as ingestion inhalation or injection The ADME absorption distribution metabolism and excretion process has been studied by means of various animal models in the laboratory Absorption quisqualic acid is a small and lipophilic molecule thus is expected to be rapid It is predicted to be absorbed in the human intestine and from then it circulates to the blood brain barrier 35 Analysis of amino acid transport systems is complex by the presence of multiple transporters with overlapping specificity Since glutamate and quisqualic acid are similar it is predicted that sodium potassium transport in the gastrointestinal tract is the absorption site of the acid Distribution knowing the receptors it binds to it can be readily predicted where the acid is present such as hippocampus basal ganglia olfactory regions Metabolism quisqualic acid is thought to be metabolized in the liver by oxidative metabolism carried out by cytochrome P450 enzymes Glutathione S transferase detoxifying agents A study showed that the exposure to quisqualic acid revealed that P450 GST were involved 37 It is also confirmed by using admetSAR tool to evaluate chemical ADMET properties 35 Its metabolites are thought to be NMDA and quinolinic acid Excretion Mostly as a rule of thumb amino acids undergo transamination deamination in the liver Thus amino acids are converted into ammonia and keto acids which are eventually excreted via the kidneys It is worth mentioning that the pharmacokinetics of quisqualic acid has not been extensively studied and there is sparse information available on its ADME process Therefore more research is needed to fully understand the metabolism of the acid in the body See also editQuisqualamine Non proteinogenic amino acidsReferences edit Quisqualic acid pubchem ncbi nlm nih gov Jin R Horning M Mayer ML Gouaux E December 2002 Mechanism of activation and selectivity in a ligand gated ion channel structural and functional studies of GluR2 and quisqualate Biochemistry 41 52 15635 15643 doi 10 1021 bi020583k PMID 12501192 Kuang D Hampson DR June 2006 Ion dependence of ligand binding to metabotropic glutamate receptors Biochemical and Biophysical Research Communications 345 1 1 6 doi 10 1016 j bbrc 2006 04 064 PMID 16674916 Zhang W Robert A Vogensen SB Howe JR August 2006 The relationship between agonist potency and AMPA receptor kinetics Biophysical Journal 91 4 1336 1346 Bibcode 2006BpJ 91 1336Z doi 10 1529 biophysj 106 084426 PMC 1518651 PMID 16731549 Bigge CF Boxer PA Ortwine DF August 1996 AMPA Kainate Receptors Current Pharmaceutical Design 2 4 397 412 doi 10 2174 1381612802666220925204342 S2CID 252560966 Muir JL Page KJ Sirinathsinghji DJ Robbins TW Everitt BJ November 1993 Excitotoxic lesions of basal forebrain cholinergic neurons effects on learning memory and attention Behavioural Brain Research 57 2 123 131 doi 10 1016 0166 4328 93 90128 d PMID 7509608 S2CID 3994174 Giovannelli L Casamenti F Pepeu G 4 November 1998 C fos expression in the rat nucleus basalis upon excitotoxic lesion with quisqualic acid a study in adult and aged animals Journal of Neural Transmission 105 8 9 935 948 doi 10 1007 s007020050103 PMID 9869327 S2CID 24942954 Lee JW Furmanski O Castellanos DA Daniels LA Hama AT Sagen J July 2008 Prolonged nociceptive responses to hind paw formalin injection in rats with a spinal cord injury Neuroscience Letters 439 2 212 215 doi 10 1016 j neulet 2008 05 030 PMC 2680189 PMID 18524486 Flores A March 2010 Geraniums and Begonias New Research on Old Garden Favorites Agricultural Research Magazine Ranger CM Winter RE Singh AP Reding ME Frantz JM Locke JC Krause CR January 2011 Rare excitatory amino acid from flowers of zonal geranium responsible for paralyzing the Japanese beetle Proceedings of the National Academy of Sciences of the United States of America 108 4 1217 1221 Bibcode 2011PNAS 108 1217R doi 10 1073 pnas 1013497108 PMC 3029778 PMID 21205899 Usherwood PN 1 January 1994 Insect Glutamate Receptors Advances in Insect Physiology 24 309 341 doi 10 1016 S0065 2806 08 60086 7 ISBN 9780120242245 a b Gurib Fakim A 2012 Combretum indicum L DeFilipps In Schmelzer GH Gurib Fakim A eds Prota 11 Medicinal plants Plantes medicinales Wageningen Netherlands Pl ntUse Retrieved 2023 03 19 Ram VJ Sethi A Nath M Pratap R 2017 Chapter 5 Five Membered Heterocycles The Chemistry of Heterocycles Nomenclature and Chemistry of Three to Five Membered Heterocycles Netherlands Elsevier ISBN 978 0 08 101033 4 Harris EW 1995 Subtypes of glutamate Receptors Pharmacological Classification In Stone TW ed CNS neurotransmitters and neuromodulators glutamate Boca Raton CRC Press p 104 ISBN 978 0 8493 7631 3 Jochims JC 1996 01 01 1 2 4 Oxadiazoles In Katritzky AR Rees CW Scriven EF eds 4 04 1 2 4 Oxadiazoles Oxford Pergamon pp 179 228 doi 10 1016 B978 008096518 5 00082 4 ISBN 978 0 08 096518 5 Retrieved 2023 03 19 a href Template Cite book html title Template Cite book cite book a work ignored help Murakoshi I Kaneko M Koide C Ikegami F 1986 01 01 Enzymatic synthesis of the neuroexcitatory amino acid quisqualic acid by cysteine synthase Phytochemistry 25 12 2759 2763 Bibcode 1986PChem 25 2759M doi 10 1016 S0031 9422 00 83736 X a b Fu H Zhang J Tepper PG Bunch L Jensen AA Poelarends GJ September 2018 Chemoenzymatic Synthesis and Pharmacological Characterization of Functionalized Aspartate Analogues As Novel Excitatory Amino Acid Transporter Inhibitors Journal of Medicinal Chemistry 61 17 7741 7753 doi 10 1021 acs jmedchem 8b00700 PMC 6139576 PMID 30011368 Ates Alagoz Z Adejare A 2017 Physicochemical Properties for Potential Alzheimer s Disease Drugs Drug Discovery Approaches for the Treatment of Neurodegenerative Disorders Elsevier pp 59 82 a b Marambaud P Dreses Werringloer U Vingtdeux V May 2009 Calcium signaling in neurodegeneration Molecular Neurodegeneration 4 1 20 doi 10 1186 1750 1326 4 20 PMC 2689218 PMID 19419557 Choi DW Rothman SM 1990 The role of glutamate neurotoxicity in hypoxic ischemic neuronal death Annual Review of Neuroscience 13 171 182 doi 10 1146 annurev ne 13 030190 001131 PMID 1970230 Zhang J Qu L Wu L Tang X Luo F Xu W et al August 2021 Structural insights into the activation initiation of full length mGlu1 Protein amp Cell 12 8 662 667 doi 10 1007 s13238 020 00808 5 PMC 8310541 PMID 33278019 Gilman AG June 1987 G proteins transducers of receptor generated signals Annual Review of Biochemistry 56 1 615 649 doi 10 1146 annurev bi 56 070187 003151 PMID 3113327 Bruno V Copani A Knopfel T Kuhn R Casabona G Dell Albani P et al August 1995 Activation of metabotropic glutamate receptors coupled to inositol phospholipid hydrolysis amplifies NMDA induced neuronal degeneration in cultured cortical cells Neuropharmacology 34 8 1089 1098 doi 10 1016 0028 3908 95 00077 J PMID 8532158 S2CID 23848439 Siliprandi R Lipartiti M Fadda E Sautter J Manev H August 1992 Activation of the glutamate metabotropic receptor protects retina against N methyl D aspartate toxicity European Journal of Pharmacology 219 1 173 174 doi 10 1016 0014 2999 92 90598 X PMID 1397046 Bitzer M Schaeffel F February 2004 Effects of quisqualic acid on retinal ZENK expression induced by imposed defocus in the chick eye Optometry and Vision Science 81 2 127 136 doi 10 1097 00006324 200402000 00011 PMID 15127932 S2CID 41195101 Namkoong J Shin SS Lee HJ Marin YE Wall BA Goydos JS Chen S March 2007 Metabotropic glutamate receptor 1 and glutamate signaling in human melanoma Cancer Research 67 5 2298 2305 doi 10 1158 0008 5472 CAN 06 3665 PMID 17332361 Littman L Chase LA Renzi M Garlin AB Koerner JF Johnson RL Robinson MB August 1995 Effects of quisqualic acid analogs on metabotropic glutamate receptors coupled to phosphoinositide hydrolysis in rat hippocampus Neuropharmacology 34 8 829 841 doi 10 1016 0028 3908 95 00070 m PMID 8532164 S2CID 46482078 a b c Biscoe TJ Evans RH Headley PM Martin M Watkins JC May 1975 Domoic and quisqualic acids as potent amino acid excitants of frog and rat spinal neurones Nature 255 5504 166 167 Bibcode 1975Natur 255 166B doi 10 1038 255166a0 PMID 1128682 S2CID 4203697 a b c d Yezierski RP Park SH July 1993 The mechanosensitivity of spinal sensory neurons following intraspinal injections of quisqualic acid in the rat Neuroscience Letters 157 1 115 119 doi 10 1016 0304 3940 93 90656 6 PMID 8233021 S2CID 44590170 Yezierski PR Liu S Ruenes LG Kajander JK Brewer LK March 1998 Excitotoxic spinal cord injury behavioral and morphological characteristics of a central pain model Pain 75 1 141 155 doi 10 1016 s0304 3959 97 00216 9 PMID 9539683 S2CID 28700511 Saroff D Delfs J Kuznetsov D Geula C April 2000 Selective vulnerability of spinal cord motor neurons to non NMDA toxicity NeuroReport 11 5 1117 1121 doi 10 1097 00001756 200004070 00041 PMID 10790892 S2CID 9793535 McDonald JW Schoepp DD May 1992 The metabotropic excitatory amino acid receptor agonist 1S 3R ACPD selectively potentiates N methyl D aspartate induced brain injury European Journal of Pharmacology 215 2 3 353 354 doi 10 1016 0014 2999 92 90058 c PMID 1383003 Cha JH Greenamyre JT Nielsen EO Penney JB Young AB August 1988 Properties of quisqualate sensitive L 3H glutamate binding sites in rat brain as determined by quantitative autoradiography Journal of Neurochemistry 51 2 469 478 doi 10 1111 j 1471 4159 1988 tb01062 x hdl 2027 42 65464 PMID 2899133 S2CID 17583816 Holmes GL Thurber SJ Liu Z Stafstrom CE Gatt A Mikati MA October 1993 Effects of quisqualic acid and glutamate on subsequent learning emotionality and seizure susceptibility in the immature and mature animal Brain Research 623 2 325 328 doi 10 1016 0006 8993 93 91447 z PMID 8106123 S2CID 10109959 a b c Quisqualic acid go drugbank com Retrieved 2023 03 19 a b Alizadeh A Dyck SM Karimi Abdolrezaee S 2019 03 22 Traumatic Spinal Cord Injury An Overview of Pathophysiology Models and Acute Injury Mechanisms Frontiers in Neurology 10 282 doi 10 3389 fneur 2019 00282 PMC 6439316 PMID 30967837 Wang H Lu Z Li M Fang Y Qu J Mao T et al July 2020 Responses of detoxification enzymes in the midgut of Bombyx mori after exposure to low dose of acetamiprid Chemosphere 251 126438 Bibcode 2020Chmsp 251l6438W doi 10 1016 j chemosphere 2020 126438 PMID 32169693 S2CID 212709003 Retrieved from https en wikipedia org w index php title Quisqualic acid amp oldid 1182436580, wikipedia, wiki, book, books, library,

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