AMPA receptor positive allosteric modulator

CX-516, one of the earliest and a prototypical AMPAR PAM. It is a low-impact AMPAR PAM.

AMPA receptor positive allosteric modulators are positive allosteric modulators (PAMs) of the AMPA receptor (AMPR), a type of ionotropic glutamate receptor which mediates most fast synaptic neurotransmission in the central nervous system.^[1]

Medical applications

AMPAR PAMs have cognition- and memory-enhancing and antidepressant-like effects in preclinical models, and have potential medical applications in the treatment of cognitive impairment (e.g., cognitive symptoms in schizophrenia, mild cognitive impairment), dementia (e.g., Alzheimer's disease), depression, and for other indications.^[1]^[2] They can broadly be divided into low-impact and high-impact potentiators, with high-impact potentiators able to produce comparatively more robust increases in AMPAR activation.^[3] However, high-impact AMPAR PAMs can cause motor coordination disruptions, convulsions, and neurotoxicity at sufficiently high doses, similarly to orthosteric AMPAR activators (i.e., active/glutamate site agonists).^[2]

The AMPAR is one of the most highly expressed receptors in the brain, and is responsible for the majority of fast excitatory amino acid neurotransmission in the central nervous system (CNS).^[4] Considering the broad impact of the AMPARs in the CNS, selectively targeting AMPARs involved in disease is difficult, and it is thought that global enhancement of AMPARs may be associated with an intolerable level of toxicity.^[4]^[1] For this reason, doubt has been cast on the feasibility of AMPAR activators for use in medicine.^[1] However, low doses of AMPAR activators may nonetheless be useful, and AMPAR PAMs, which, unlike agonists, show selectivity for AMPAR subpopulations of different subunit compositions, may hold greater potential for medical applications.^[4]^[1]

Pharmacology

AMPAR PAMs bind to one or more allosteric sites on the AMPAR complex and potentiate the receptor.^[4] Unlike orthosteric (active/glutamate) site AMPAR activators, otherwise known as AMPAR agonists, AMPAR PAMs only potentiate AMPAR signaling in the presence of glutamate and hence do not activate the receptor directly/themselves.^[4] Moreover, whereas AMPAR agonists activate all AMPARs, AMPAR PAMs can show selectivity for specific subpopulations of AMPARs.^[4] This is because the AMPAR is composed of different combinations of various subunits, and the allosteric sites differ depending on the different subunit combinations.^[4]

AMPAR PAMs can be broadly grouped into two types based on their binding site and impact on AMPAR activation: low-impact (type I) and high-impact (type II).^[5] Low-impact AMPAR PAMs have the following criteria:^[5]

Have little or no effect on the half-width of the field excitatory postsynaptic potential (fEPSP); and
Do not substantially bind to the cyclothiazide site on the AMPAR complex; and
Do not induce the expression of brain-derived neurotrophic factor (BDNF)

While high-impact AMPAR PAMs have the following criteria:^[5]

Substantially alter/increase the half-width of the fEPSP; and/or
Substantially bind to the cyclothiazide site on the AMPAR complex; and
Induce the expression of BDNF

Low-impact AMPAR PAMs decrease AMPAR deactivation (channel closing) alone to augment synaptic currents while high-impact AMPAR PAMs decrease both deactivation and desensitization together to enhance and prolong synaptic currents.^[3] Low-impact AMPAR PAMs have only slight effects on AMPAR currents, whereas high-impact AMPAR PAMs have effects more similar to those of AMPAR agonists and can produce strong enhancement.^[6]^[7] Similarly to AMPAR agonists, high-impact AMPAR PAMs can cause convulsions and neurotoxicity in sufficiently high doses.^[2] Conversely, low-impact AMPAR PAMs have few adverse effects.^[6]

Classes and list of drugs

By chemical structure

There are several major chemical classes of AMPAR PAMs:^[8]^[4]

Benzamide and related compounds (also known as ampakines or CX compounds; mostly benzoylpyrrolidines) – 1-BCP (BA-14), CX-516 (Ampalex, BDP-12, BA-74, ORG-24292, SPD-420), CX-546, CX-554 (BDP-20), CX-614, farampator (CX-691, ORG-24481, SCH-900460), CX-717, CX-929, CX-1501, tulrampator (S-47445, CX-1632), CX-1739, CX-1796, CX-1837, CX-1942, CX-2007, CX-2076, ORG-26576, S-70340
Benzothiadiazides – BIIR-777, cyclothiazide, diazoxide, hydrochlorothiazide (HCTZ), IDRA-21, S-18986
Biarylpropylsulfonamides and related compounds – LY-392098, LY-404187, LY-450108, mibampator (LY-451395), LY-4516146, LY-503430, PEPA, PF-04778574, pesampator (BIIB-104; PF-04958242), CMPDA, CMPDB, (R,R)-PIMSD
Racetam and related compounds (very weak) – aniracetam, piracetam, various others
Others: PF-04701475, pesampator (BIIB-104; PF-04958242), GVS-111, TAK-653^[9]

These classes have divergent properties, including allosteric site specificity, potency, impact (i.e., low versus high), and selectivity for AMPAR populations composed of different subunits.^[8]^[4] All of the biarylpropylsulfonamides are high-impact AMPAR PAMs, whereas the majority of the ampakines are low-impact AMPAR potentiators.^[10] The biarylpropylsulfonamides are highly potent, on the order of 1,000-fold more potent than the ampakines and cyclothiazide.^[10]

By impact

AMPAR PAMs can be broadly grouped by their impact on AMPAR activation:^[5]^[3]^[11]

Low-impact (type I): aniracetam, CX-516 (Ampalex, BDP-12, BA-74, ORG-24292, SPD-420), CX-614, CX-717, CX-929, CX-1739, farampator (CX-691, ORG-24481, SCH-900460), ORG-24448, piracetam
High-impact (type II): CX-701, CX-1837, CX-1846, LY-404187, LY-451646, mibampator (LY-451395), ORG-26576, pesampator (BIIB-104; PF-04958242), PF-4778574, tulrampator (S-47445, CX-1632)

References

^ ^a ^b ^c ^d ^e Lee K, Goodman L, Fourie C, Schenk S, Leitch B, Montgomery JM (2016). "AMPA Receptors as Therapeutic Targets for Neurological Disorders". Ion Channels as Therapeutic Targets, Part A. Advances in Protein Chemistry and Structural Biology. Vol. 103. pp. 203–61. doi:10.1016/bs.apcsb.2015.10.004. ISBN 9780128047941. PMID 26920691. {{cite book}}: |journal= ignored (help)
^ ^a ^b ^c Ranganathan M, DeMartinis N, Huguenel B, Gaudreault F, Bednar MM, Shaffer CL, et al. (November 2017). "Attenuation of ketamine-induced impairment in verbal learning and memory in healthy volunteers by the AMPA receptor potentiator PF-04958242". Molecular Psychiatry. 22 (11): 1633–1640. doi:10.1038/mp.2017.6. PMID 28242871. S2CID 3691566.
^ ^a ^b ^c Roberts BM, Holden DE, Shaffer CL, Seymour PA, Menniti FS, Schmidt CJ, et al. (September 2010). "Prevention of ketamine-induced working memory impairments by AMPA potentiators in a nonhuman primate model of cognitive dysfunction". Behavioural Brain Research. 212 (1): 41–8. doi:10.1016/j.bbr.2010.03.039. PMID 20347881. S2CID 9432930.
^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Black MD (April 2005). "Therapeutic potential of positive AMPA modulators and their relationship to AMPA receptor subunits. A review of preclinical data". Psychopharmacology. 179 (1): 154–63. doi:10.1007/s00213-004-2065-6. PMID 15672275. S2CID 5869366.
^ ^a ^b ^c ^d US 9700596, Carmichael, Stanley T & Clarkson, Andrew N, "Locally released growth factors to mediate motor recovery after stroke", issued 2017-06-21, assigned to The Regents of the University of California
^ ^a ^b Lorier AR, Funk GD, Greer JJ (January 2010). "Opiate-induced suppression of rat hypoglossal motoneuron activity and its reversal by ampakine therapy". PLOS ONE. 5 (1): e8766. Bibcode:2010PLoSO...5.8766L. doi:10.1371/journal.pone.0008766. PMC 2808240. PMID 20098731.
^ US 2010069377, Simmons, Danielle & Lynch, Gary, "Treatment of female sexual dysfunction by compounds that positively modulate ampa-type glutamate receptors", published 2010-03-18, assigned to The Regents of the University of California
^ ^a ^b Froestl W, Muhs A, Pfeifer A (2012). "Cognitive enhancers (nootropics). Part 1: drugs interacting with receptors". Journal of Alzheimer's Disease. 32 (4): 793–887. doi:10.3233/JAD-2012-121186. PMID 22886028.
^ Gudasheva TA, Grigoriev VV, Koliasnikova KN, Zamoyski VL, Seredenin SB (November 2016). "Neuropeptide cycloprolylglycine is an endogenous positive modulator of AMPA receptors". Doklady. Biochemistry and Biophysics. 471 (1): 387–389. doi:10.1134/s160767291606003x. PMID 28058675. S2CID 11453708.
^ ^a ^b Jordan GR (2007). Investigation of the Functional Effects of Two Novel Ampakines in the CNS (Ph.D. thesis). Edinburgh Medical School. hdl:1842/1946.
^ Monti B, Contestabile A (June 2009). "Memory-enhancing drugs: a molecular perspective". Mini Reviews in Medicinal Chemistry. 9 (7): 769–81. doi:10.2174/138955709788452621. PMID 19519502.

[pmid26920691-1] Lee K, Goodman L, Fourie C, Schenk S, Leitch B, Montgomery JM (2016). "AMPA Receptors as Therapeutic Targets for Neurological Disorders". Ion Channels as Therapeutic Targets, Part A. Advances in Protein Chemistry and Structural Biology. Vol. 103. pp. 203–61. doi:10.1016/bs.apcsb.2015.10.004. ISBN 9780128047941. PMID 26920691. {{cite book}}: |journal= ignored (help)

[pmid28242871-2] Ranganathan M, DeMartinis N, Huguenel B, Gaudreault F, Bednar MM, Shaffer CL, et al. (November 2017). "Attenuation of ketamine-induced impairment in verbal learning and memory in healthy volunteers by the AMPA receptor potentiator PF-04958242". Molecular Psychiatry. 22 (11): 1633–1640. doi:10.1038/mp.2017.6. PMID 28242871. S2CID 3691566.

[pmid20347881-3] Roberts BM, Holden DE, Shaffer CL, Seymour PA, Menniti FS, Schmidt CJ, et al. (September 2010). "Prevention of ketamine-induced working memory impairments by AMPA potentiators in a nonhuman primate model of cognitive dysfunction". Behavioural Brain Research. 212 (1): 41–8. doi:10.1016/j.bbr.2010.03.039. PMID 20347881. S2CID 9432930.

[pmid15672275-4] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Black MD (April 2005). "Therapeutic potential of positive AMPA modulators and their relationship to AMPA receptor subunits. A review of preclinical data". Psychopharmacology. 179 (1): 154–63. doi:10.1007/s00213-004-2065-6. PMID 15672275. S2CID 5869366.

[US9700596-5] US 9700596, Carmichael, Stanley T & Clarkson, Andrew N, "Locally released growth factors to mediate motor recovery after stroke", issued 2017-06-21, assigned to The Regents of the University of California

[pmid20098731-6] Lorier AR, Funk GD, Greer JJ (January 2010). "Opiate-induced suppression of rat hypoglossal motoneuron activity and its reversal by ampakine therapy". PLOS ONE. 5 (1): e8766. Bibcode:2010PLoSO...5.8766L. doi:10.1371/journal.pone.0008766. PMC 2808240. PMID 20098731.

[US20100069377-7] US 2010069377, Simmons, Danielle & Lynch, Gary, "Treatment of female sexual dysfunction by compounds that positively modulate ampa-type glutamate receptors", published 2010-03-18, assigned to The Regents of the University of California

[pmid22886028-8] Froestl W, Muhs A, Pfeifer A (2012). "Cognitive enhancers (nootropics). Part 1: drugs interacting with receptors". Journal of Alzheimer's Disease. 32 (4): 793–887. doi:10.3233/JAD-2012-121186. PMID 22886028.

[9] Gudasheva TA, Grigoriev VV, Koliasnikova KN, Zamoyski VL, Seredenin SB (November 2016). "Neuropeptide cycloprolylglycine is an endogenous positive modulator of AMPA receptors". Doklady. Biochemistry and Biophysics. 471 (1): 387–389. doi:10.1134/s160767291606003x. PMID 28058675. S2CID 11453708.

[Jordan2007-10] Jordan GR (2007). Investigation of the Functional Effects of Two Novel Ampakines in the CNS (Ph.D. thesis). Edinburgh Medical School. hdl:1842/1946.

[pmid19519502-11] Monti B, Contestabile A (June 2009). "Memory-enhancing drugs: a molecular perspective". Mini Reviews in Medicinal Chemistry. 9 (7): 769–81. doi:10.2174/138955709788452621. PMID 19519502.

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v t e Ionotropic glutamate receptor modulators
AMPARTooltip α-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor	Agonists: Main site agonists: 5-Fluorowillardiine Acromelic acid (acromelate) AMPA BOAA Domoic acid Glutamate Ibotenic acid Proline Quisqualic acid Willardiine; Positive allosteric modulators: Aniracetam Cyclothiazide CX-516 CX-546 CX-614 Farampator (CX-691, ORG-24448) CX-717 CX-1739 CX-1942 Diazoxide Hydrochlorothiazide (HCTZ) IDRA-21 LY-392098 LY-395153 LY-404187 LY-451646 LY-503430 Mibampator (LY-451395) Nooglutyl ORG-26576 Oxiracetam PEPA Pesampator (BIIB-104, PF-04958242) Piracetam Pramiracetam S-18986 Tulrampator (S-47445, CX-1632) Antagonists: ACEA-1011 ATPO Becampanel Caroverine CNQX Dasolampanel DNQX Fanapanel (MPQX) GAMS Kaitocephalin Kynurenic acid Kynurenine Licostinel (ACEA-1021) NBQX PNQX Selurampanel Tezampanel Theanine Topiramate YM90K Zonampanel; Negative allosteric modulators: Barbiturates (e.g., pentobarbital, sodium thiopental) Cyclopropane Enflurane Ethanol (alcohol) Evans blue GYKI-52466 GYKI-53655 Halothane Irampanel Isoflurane Perampanel Pregnenolone sulfate Sevoflurane Talampanel; Unknown/unsorted antagonists: Minocycline
KARTooltip Kainate receptor	Agonists: Main site agonists: 5-Bromowillardiine 5-Iodowillardiine Acromelic acid (acromelate) AMPA ATPA Domoic acid Glutamate Ibotenic acid Kainic acid LY-339434 Proline Quisqualic acid SYM-2081; Positive allosteric modulators: Cyclothiazide Diazoxide Enflurane Halothane Isoflurane Antagonists: ACEA-1011 CNQX Dasolampanel DNQX GAMS Kaitocephalin Kynurenic acid Licostinel (ACEA-1021) LY-382884 NBQX NS102 Selurampanel Tezampanel Theanine Topiramate UBP-302; Negative allosteric modulators: Barbiturates (e.g., pentobarbital, sodium thiopental) Enflurane Ethanol (alcohol) Evans blue NS-3763 Pregnenolone sulfate
NMDARTooltip N-Methyl-D-aspartate receptor	Agonists: Main site agonists: AMAA Aspartate Glutamate Homocysteic acid (L-HCA) Homoquinolinic acid Ibotenic acid NMDA Proline Quinolinic acid Tetrazolylglycine Theanine; Glycine site agonists: β-Fluoro-D-alanine ACBD ACC (ACPC) ACPD AK-51 Apimostinel (NRX-1074) B6B21 CCG D-Alanine D-Cycloserine D-Serine DHPG Dimethylglycine Glycine HA-966 L-687414 L-Alanine L-Serine Milacemide Neboglamine (nebostinel) Rapastinel (GLYX-13) Sarcosine; Polyamine site agonists: Neomycin Spermidine Spermine; Other positive allosteric modulators: 24S-Hydroxycholesterol DHEATooltip Dehydroepiandrosterone (prasterone) DHEA sulfate (prasterone sulfate) Epipregnanolone sulfate Plazinemdor Pregnenolone sulfate SAGE-201 SAGE-301 SAGE-718 Antagonists: Competitive antagonists: AP5 (APV) AP7 CGP-37849 CGP-39551 CGP-39653 CGP-40116 CGS-19755 CPP Kaitocephalin LY-233053 LY-235959 LY-274614 MDL-100453 Midafotel (d-CPPene) NPC-12626 NPC-17742 PBPD PEAQX Perzinfotel PPDA SDZ-220581 Selfotel; Glycine site antagonists: 4-Cl-KYN (AV-101) 5,7-DCKA 7-CKA ACC ACEA-1011 ACEA-1328 Apimostinel (NRX-1074) AV-101 Carisoprodol CGP-39653 CNQX D-Cycloserine DNQX Felbamate Gavestinel GV-196771 Harkoseride Kynurenic acid Kynurenine L-689560 L-701324 Licostinel (ACEA-1021) LU-73068 MDL-105519 Meprobamate MRZ 2/576 PNQX Rapastinel (GLYX-13) ZD-9379; Polyamine site antagonists: Arcaine Co 101676 Diaminopropane Diethylenetriamine Huperzine A Putrescine; Uncompetitive pore blockers (mostly dizocilpine site): 2-MDP 3-HO-PCP 3-MeO-PCE 3-MeO-PCMo 3-MeO-PCP 4-MeO-PCP 8A-PDHQ 18-MC α-Endopsychosin Alaproclate Alazocine (SKF-10047) Amantadine Aptiganel Argiotoxin-636 Arketamine ARL-12495 ARL-15896-AR ARL-16247 Budipine Coronaridine Delucemine (NPS-1506) Dexoxadrol Dextrallorphan Dextromethadone Dextromethorphan Dextrorphan Dieticyclidine Diphenidine Dizocilpine Ephenidine Esketamine Etoxadrol Eticyclidine Fluorolintane Gacyclidine Ibogaine Ibogamine Indantadol Ketamine Ketobemidone Lanicemine Levomethadone Levomethorphan Levomilnacipran Levorphanol Loperamide Memantine Methadone Methorphan Methoxetamine Methoxphenidine Milnacipran Morphanol NEFA Neramexane Nitromemantine Noribogaine Norketamine Orphenadrine PCPr PD-137889 Pethidine (meperidine) Phencyclamine Phencyclidine Propoxyphene Remacemide Rhynchophylline Rimantadine Rolicyclidine Sabeluzole Tabernanthine Tenocyclidine Tiletamine Tramadol; Ifenprodil (NR2B) site antagonists: Besonprodil Buphenine (nylidrin) CO-101244 (PD-174494) Eliprodil Haloperidol Isoxsuprine Radiprodil (RGH-896) Rislenemdaz (CERC-301, MK-0657) Ro 8-4304 Ro 25-6981 Safaprodil Traxoprodil (CP-101606); NR2A-selective antagonists: MPX-004 MPX-007 TCN-201 TCN-213; Cations: Hydrogen Magnesium Zinc; Alcohols/volatile anesthetics/related: Benzene Butane Chloroform Cyclopropane Desflurane Diethyl ether Enflurane Ethanol (alcohol) Halothane Hexanol Isoflurane Methoxyflurane Nitrous oxide Octanol Sevoflurane Toluene Trichloroethane Trichloroethanol Trichloroethylene Urethane Xenon Xylene; Unknown/unsorted antagonists: ARR-15896 Bumetanide Caroverine Conantokin D-αAA Dexanabinol Flufenamic acid Flupirtine FPL-12495 FR-115427 Furosemide Hodgkinsine Ipenoxazone (MLV-6976) MDL-27266 Metaphit Minocycline MPEP Niflumic acid Pentamidine Pentamidine isethionate Piretanide Psychotridine Transcrocetin (saffron) Unsorted: Allosteric modulators: AGN-241751
See also: Receptor/signaling modulators Metabotropic glutamate receptor modulators Glutamate metabolism/transport modulators