Stylised depiction of an activated NMDAR. Glutamate is in the glutamate-binding site and glycine is in the glycine-binding site. Allosteric sites that would cause inhibition of the receptor are not occupied. NMDARs require the binding of two molecules of glutamate or aspartate and two of glycine.
[1]
The N-methyl-D-aspartate receptor (also known as the NMDA receptor or NMDAR), a glutamate receptor, is the predominant molecular device for controlling synaptic plasticity and memory function.[2]
The NMDAR is a specific type of ionotropic glutamate receptor. NMDA (N-methyl-D-aspartate) is the name of a selective agonist that binds to NMDA receptors but not to other glutamate receptors. Activation of NMDA receptors results in the opening of an ion channel that is nonselective to cations with an equilibrium potential near 0 mV. A property of the NMDA receptor is its voltage-dependent activation, a result of ion channel block by extracellular Mg2+ & Zn2+ ions. This allows the flow of Na+ and small amounts of Ca2+ ions into the cell and K+ out of the cell to be voltage-dependent.[3][4][5][6]
Calcium flux through NMDARs is thought to be critical in synaptic plasticity, a cellular mechanism for learning and memory. The NMDA receptor is distinct in two ways: first, it is both ligand-gated and voltage-dependent; second, it requires co-activation by two ligands: glutamate and either D-serine or glycine.[7]
Contents
- 1 Structure
- 2 Variants
- 2.1 GluN1
- 2.2 GluN2
- 2.3 NR2B to NR2C switch
- 3 Ligands
- 3.1 Agonists
- 3.2 Partial agonists
- 3.3 Antagonists
- 3.4 Modulators
- 4 Receptor modulation
- 5 Clinical significance
- 6 See also
- 7 External links
- 8 References
Structure
The NMDA receptor forms a heterotetramer between two GluN1 and two GluN2 subunits (the subunits were previously denoted as NR1 and NR2), two obligatory NR1 subunits and two regionally localized NR2 subunits. A related gene family of NR3 A and B subunits have an inhibitory effect on receptor activity. Multiple receptor isoforms with distinct brain distributions and functional properties arise by selective splicing of the NR1 transcripts and differential expression of the NR2 subunits.
Each receptor subunit has modular design and each structural module also represents a functional unit:
- The extracellular domain contains two globular structures: a modulatory domain and a ligand-binding domain. NR1 subunits bind the co-agonist glycine and NR2 subunits bind the neurotransmitter glutamate.
- The agonist-binding module links to a membrane domain, which consists of three trans-membrane segments and a re-entrant loop reminiscent of the selectivity filter of potassium channels.
- The membrane domain contributes residues to the channel pore and is responsible for the receptor's high-unitary conductance, high-calcium permeability, and voltage-dependent magnesium block.
- Each subunit has an extensive cytoplasmic domain, which contain residues that can be directly modified by a series of protein kinases and protein phosphatases, as well as residues that interact with a large number of structural, adaptor, and scaffolding proteins.
The glycine-binding modules of the NR1 and NR3 subunits and the glutamate-binding module of the NR2A subunit have been expressed as soluble proteins, and their three-dimensional structure has been solved at atomic resolution by x-ray crystallography. This has revealed a common fold with amino acid-binding bacterial proteins and with the glutamate-binding module of AMPA-receptors and kainate-receptors.
Variants
GluN1
There are eight variants of the NR1 subunit produced by alternative splicing of GRIN1:[8]
- NR1-1a, NR1-1b; NR1-1a is the most abundantly expressed form.
- NR1-2a, NR1-2b;
- NR1-3a, NR1-3b;
- NR1-4a, NR1-4b;
GluN2
NR2 subunit in vertebrates (left) and invertebrates (right). Ryan et al., 2008
While a single NR2 subunit is found in invertebrate organisms, four distinct isoforms of the NR2 subunit are expressed in vertebrates and are referred to with the nomenclature NR2A through D(coded by GRIN2A, GRIN2B, GRIN2C, GRIN2D). Strong evidence shows that the genes coding the NR2 subunits in vertebrates have undergone at least two rounds of gene duplication.[9] They contain the binding-site for the neurotransmitter glutamate. More importantly, each NR2 subunit has a different intracellular C-terminal domain that can interact with different sets of signalling molecules.[10] Unlike NR1 subunits, NR2 subunits are expressed differentially across various cell types and control the electrophysiological properties of the NMDA receptor. One particular subunit, NR2B, is mainly present in immature neurons and in extrasynaptic locations, and contains the binding-site for the selective inhibitor ifenprodil.
Whereas NR2B is predominant in the early postnatal brain, the number of NR2A subunits grows, and eventually NR2A subunits outnumber NR2B. This is called NR2B-NR2A developmental switch, and is notable because of the different kinetics each NR2 subunit lends to the receptor.[11] For instance, greater ratios of the NR2B subunit leads to NMDA receptors which remain open longer compared to those with more NR2A.[12] This may in part account for greater memory abilities in the immediate postnatal period compared to late in life, which is the principle behind genetically-altered 'doogie mice'.
There are three hypothetical models to describe this switch mechanism:
- Dramatic increase in synaptic NR2A along with decrease in NR2B
- Extrasynaptic displacement of NR2B away from the synapse with increase in NR2A
- Increase of NR2A diluting the number of NR2B without the decrease of the latter.
The NR2B and NR2A subunits also have differential roles in mediating excitotoxic neuronal death.[13] The developmental switch in subunit composition is thought to explain the developmental changes in NMDA neurotoxicity.[14] Disruption of the gene for NR2B in mice causes perinatal lethality, whereas the disruption of NR2A gene produces viable mice, although with impaired hippocampal plasticity.[15] One study suggests that reelin may play a role in the NMDA receptor maturation by increasing the NR2B subunit mobility.[16]
NR2B to NR2C switch
Granule cell precursors (GCPs) of the cerebellum, after undergoing symmetric cell division[17] in the external granule-cell layer (EGL), migrate into the internal granule-cell layer (IGL) where they downregulate NR2B and activate NR2C, a process that is independent of neuregulin beta signaling through ErbB2 and ErbB4 receptors.[18]
Ligands
Agonists
Activation of NMDA receptors requires binding of glutamate or aspartate (aspartate does not stimulate the receptors as strongly).[19] In addition, NMDARs also require the binding of the co-agonist glycine for the efficient opening of the ion channel, which is a part of this receptor.
D-serine has also been found to co-agonize the NMDA receptor with even greater potency than glycine.[20] D-serine is produced by serine racemase, and is enriched in the same areas as NMDA receptors. Removal of D-serine can block NMDA-mediated excitatory neurotransmission in many areas. Recently, it has been shown that D-serine can be released both by neurons and astrocytes to regulate NMDA receptors.
NMDA receptor (NMDAR)-mediated currents are directly related to membrane depolarization. NMDA agonists therefore exhibit fast Mg2+ unbinding kinetics, increasing channel open probability with depolarization. This property is fundamental to the role of the NMDA receptor in memory and learning, and it has been suggested that this channel is a biochemical substrate of Hebbian learning, where it can act as a coincidence detector for membrane depolarization and synaptic transmission.
Some known NMDA receptor agonists include:
- Aminocyclopropanecarboxylic acid
- D-Cycloserine
- cis-2,3-Piperidinedicarboxylic acid
- L-Aspartate
- Quinolinate
- Homocysterate
- D-Serine
- ACPL
- L-Alanine
Partial agonists
- N-Methyl-D-aspartic acid (NMDA)
- 3,5-dibromo-L-phenylalanine[21]
- GLYX-13
- NRX-1074
Glycine-site NMDA receptor partial agonists, such as GLYX-13 and NRX-1074, are now viewed with great interest for the development of new drugs with antidepressant and analgesic effects without obvious psychotomimetic activities.[22]
Antagonists
Main article: NMDA receptor antagonist
Antagonists of the NMDA receptor are used as anesthetics for animals and sometimes humans, and are often used as recreational drugs due to their hallucinogenic properties, in addition to their unique effects at elevated dosages such as dissociation. When certain NMDA receptor antagonists are given to rodents in large doses, they can cause a form of brain damage called Olney's lesions. NMDA receptor antagonists that have been shown to induce Olney's lesions include ketamine, phencyclidine, and dextrorphan (a metabolite of dextromethorphan), as well as some NMDA receptor antagonists used only in research environments. So far, the published research on Olney's lesions is inconclusive in its occurrence upon human or monkey brain tissues with respect to an increase in the presence of NMDA receptor antagonists.[23]
Common agents in which NMDA receptor antagonism is the primary mechanism of action:
- AP5
- Conantokins
- Dextromethorphan
- Dexanabinol
- Dizocilpine (MK-801)
- Ketamine
- Memantine
- Nitrous oxide
- Phencyclidine
- Xenon
Some common agents in which weak NMDA receptor antagonism is a secondary or additional action include:
- Amantadine[24]
- Atomoxetine[25]
- Dextropropoxyphene
- Ethanol
- Huperzine A
- Ibogaine
- Ketobemidone
- Methadone – an opioid analgesic
- Tramadol – an atypical analgesic
Kynurenic acid is an endogenous NMDA receptor antagonist.
Modulators
The NMDA receptor is modulated by a number of endogenous and exogenous compounds:[26]
- Mg2+ not only blocks the NMDA channel in a voltage-dependent manner but also potentiates NMDA-induced responses at positive membrane potentials. Treatment with forms magnesium glycinate and magnesium taurinate has been used to produce rapid recovery from depression.[27]
- Na+, K+ and Ca2+ not only pass through the NMDA receptor channel but also modulate the activity of NMDA receptors.
- Zn2+ and Cu2+ generally block NMDA current activity in a noncompetitive and a voltage-independent manner. However zinc may potentiate or inhibit the current depending on the neural activity. (Zinc and Copper Influence Excitability of Rat Olfactory Bulb Neurons by Multiple Mechanisms|http://jn.physiology.org/content/86/4/1652.short)
- Pb2+[28] is a potent NMDAR antagonist. Presynaptic deficits resulting from Pb2+ exposure during synaptogenesis are mediated by disruption of NMDAR-dependent BDNF signaling.
- It has been demonstrated that polyamines do not directly activate NMDA receptors, but instead act to potentiate or inhibit glutamate-mediated responses.
- Aminoglycosides have been shown to have a similar effect to polyamines, and this may explain their neurotoxic effect.
- The activity of NMDA receptors is also strikingly sensitive to the changes in H+ concentration, and partially inhibited by the ambient concentration of H+ under physiological conditions. [29] The level of inhibition by H+ is greatly reduced in receptors containing the NR1a subtype, which contains the positively charged insert Exon 5. The effect of this insert may be mimicked by positively charged polyamines and aminoglycosides, explaining their mode of action.
- NMDA receptor function is also strongly regulated by chemical reduction and oxidation, via the so-called "redox modulatory site."[30] Through this site, reductants dramatically enhance NMDA channel activity, whereas oxidants either reverse the effects of reductants or depress native responses. It is generally believed that NMDA receptors are modulated by endogenous redox agents such as glutathione, lipoic acid, and the essential nutrient pyrroloquinoline quinone.
- Src kinase enhances NMDA receptor currents.[31]
- Reelin modulates NMDA function through Src family kinases and DAB1.[32]significantly enhancing LTP in the hippocampus.
- CDK5 regulates the amount of NR2B-containing NMDA receptors on the synaptic membrane, thus affecting synaptic plasticity.[33][34]
- Proteins of the major histocompatibility complex class I are endogenous negative regulators of NMDAR-mediated currents in the adult hippocampus,[35] and are required for appropriate NMDAR-induced changes in AMPAR trafficking [35] and NMDAR-dependent synaptic plasticity and learning and memory.[36][37]
Receptor modulation
The NMDA receptor is a non-specific cation channel that can allow the passage of Ca2+ and Na+ into the cell and K+ out of the cell. The excitatory postsynaptic potential (EPSP) produced by activation of an NMDA receptor increases the concentration of Ca2+ in the cell. The Ca2+ can in turn function as a second messenger in various signaling pathways. However, the NMDA receptor cation channel is blocked by Mg2+ at resting membrane potential. To unblock the channel, the postsynaptic cell must be depolarized.[38]
Therefore, the NMDA receptor functions as a "molecular coincidence detector". Its ion channel opens only when the following two conditions are met simultaneously: glutamate is bound to the receptor, and the postsynaptic cell is depolarized (which removes the Mg2+ blocking the channel). This property of the NMDA receptor explains many aspects of long-term potentiation (LTP) and synaptic plasticity.[39]
NMDA receptors are modulated by a number of endogenous and exogenous compounds and play a key role in a wide range of physiological (e.g., memory) and pathological processes (e.g., excitotoxicity).
Clinical significance
Memantine is approved by the U.S. F.D.A and the European Medicines Agency for treatment of moderate-to-severe Alzheimer's disease,[40] and has now received a limited recommendation by the UK's National Institute for Health and Care Excellence for patients who fail other treatment options.[41]
Cochlear NMDARs are the target of intense research to find pharmacological solutions to treat tinnitus. Recently, NMDARs were associated with a rare autoimmune disease, anti-NMDAR encephalitis, that usually occurs due to cross reactivity of antibodies produced by the immune system against ectopic brain tissues, such as those found in teratoma.
NMDAR modulators, including esketamine, GLYX-13, NRX-1074, and CERC-301, are under development for the treatment of mood disorders, including major depressive disorder and treatment-resistant depression.[42] In addition, ketamine is already employed for this purpose as an off-label therapy in some clinics.[43][44]
Compared to dopaminergic stimulants, phencyclidine can produce a wider range of symptoms that resemble schizophrenia in healthy volunteers, in what has led to the glutamate hypothesis of schizophrenia.[45] Experiments in which rodents are treated with NMDA receptor antagonist are today the most common model when it comes to testing of novel schizophrenia therapies or exploring the exact mechanism of drugs already approved for treatment of schizophrenia.
See also
- Long-term potentiation and depression
- Category: NMDA receptor antagonists
- NMDA
- AMPA
- AMPA receptor
- Calcium/calmodulin-dependent protein kinases
- Anti-glutamate receptor antibodies
- Anti-NMDA receptor encephalitis
External links
- Media related to NMDA receptor at Wikimedia Commons
- NMDA receptor pharmacology
- Motor Discoordination Results from Combined Gene Disruption of the NMDA Receptor NR2A and NR2C Subunits, But Not from Single Disruption of the NR2A or NR2C Subunit
- A schematic diagram summarizes three potential models for the switching of NR2A and NR2B subunits at developing synapses. - a figure from Liu et al., 2004[46]
- Drosophila NMDA receptor 1 - The Interactive Fly
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Ion channel, cell surface receptor: ligand-gated ion channels
|
|
Cys-loop receptors |
5-HT/serotonin
|
|
|
GABA
|
- GABAA
- α1
- α2
- α3
- α4
- α5
- α6
- β1
- β2
- β3
- γ1
- γ2
- γ3
- δ
- ε
- π
- θ
- GABAA-ρ
|
|
Glycine
|
|
|
Nicotinic acetylcholine
|
- monomers: α1
- α2
- α3
- α4
- α5
- α6
- α7
- α9
- α10
- β1
- β2
- β3
- β4
- δ
- ε
- pentamers: (α3)2(β4)3
- (α4)2(β2)3
- (α7)5
- (α1)2(β4)3 - Ganglion type
- (α1)2β1δε - Muscle type
|
|
Zinc
|
|
|
|
Ionotropic glutamates |
Ligand-gated only
|
|
|
Voltage- and ligand-gated
|
- NMDA
- 1
- 2A
- 2B
- 2C
- 2D
- 3A
- 3B
- L1A
- L1B
|
|
‘Orphan’
|
|
|
|
ATP-gated channels |
|
|
B trdu: iter (nrpl/grfl/cytl/horl), csrc (lgic, enzr, gprc, igsr, intg, nrpr/grfr/cytr), itra (adap, gbpr, mapk), calc, lipd; path (hedp, wntp, tgfp+mapp, notp, jakp, fsap, hipp, tlrp)
|
|
Glutamatergics
|
|
Ionotropic |
AMPA
|
- Agonists: 5-Fluorowillardiine
- AMPA
- Domoic acid
- Quisqualic acid; Positive allosteric modulators: Aniracetam
- Cyclothiazide
- CX-516
- CX-546
- CX-614
- CX-691
- CX-717
- Diazoxide
- HCTZ
- IDRA-21
- LY-392,098
- LY-404,187
- LY-451,395
- LY-451,646
- LY-503,430
- Org 26576
- Oxiracetam
- PEPA
- Piracetam
- Pramiracetam
- S-18986
- Sunifiram
- Unifiram
Antagonists: ATPO
- Barbiturates
- BGG492
- Caroverine
- CNQX
- DNQX
- GYKI-52466
- NBQX
- Perampanel
- Talampanel
- Tezampanel
- Topiramate; Negative allosteric modulators: GYKI-53,655
|
|
NMDA
|
- Agonists: Glutamate/active site competitive agonists: Aspartate
- Glutamate
- Homoquinolinic acid
- Ibotenic acid
- NMDA
- Quinolinic acid
- Tetrazolylglycine; Glycine site agonists: ACBD
- ACPC
- ACPD
- Alanine
- CCG
- Cycloserine
- DHPG
- Fluoroalanine
- Glycine
- GLYX-13
- HA-966
- L-687,414
- Milacemide
- NRX-1074
- Sarcosine
- Serine
- Tetrazolylglycine; Polyamine site agonists: Acamprosate
- Spermidine
- Spermine
Antagonists: Competitive antagonists: AP5 (APV)
- AP7
- CGP-37849
- CGP-39551
- CGP-39653
- CGP-40116
- CGS-19755
- CPP
- LY-233,053
- LY-235,959
- LY-274,614
- MDL-100,453
- Midafotel (d-CPPene)
- NPC-12,626
- NPC-17,742
- PBPD
- PEAQX
- Perzinfotel
- PPDA
- SDZ-220581
- Selfotel; Noncompetitive antagonists: ARR-15,896
- Caroverine
- Dexanabinol
- FPL-12495
- FR-115,427
- Hodgkinsine
- Magnesium
- MDL-27,266
- NPS-1506
- Psychotridine
- Zinc; Uncompetitive pore blockers: 2-MDP
- 3-MeO-PCP
- 8A-PDHQ
- Alaproclate
- Amantadine
- Aptiganel
- ARL-12,495
- ARL-15,896-AR
- ARL-16,247
- Budipine
- Delucemine
- Dexoxadrol
- Dextrallorphan
- Dieticyclidine
- Dizocilpine
- Endopsychosin
- Esketamine
- Etoxadrol
- Eticyclidine
- Gacyclidine
- Ibogaine
- Indantadol
- Ketamine
- Ketobemidone
- Lanicemine
- Loperamide
- Memantine
- Methadone (Levomethadone)
- Methorphan (Dextromethorphan
- Levomethorphan)
- Methoxetamine
- Milnacipran
- Morphanol (Dextrorphan
- Levorphanol)
- NEFA
- Neramexane
- Nitromemantine
- Nitrous oxide
- Noribogaine
- Orphenadrine
- PCPr
- Pethidine (meperidine)
- Phencyclamine
- Phencyclidine
- Propoxyphene
- Remacemide
- Rhynchophylline
- Rimantadine
- Rolicyclidine
- Sabeluzole
- Tenocyclidine
- Tiletamine
- Tramadol
- Xenon; Glycine site antagonists: ACEA-1021
- ACEA-1328
- ACC
- Carisoprodol
- CGP-39653
- CKA
- DCKA
- Felbamate
- Gavestinel
- GV-196,771
- Kynurenic acid
- L-689,560
- L-701,324
- Licostinel
- LU-73,068
- MDL-105,519
- Meprobamate
- MRZ 2/576
- PNQX
- ZD-9379; NR2B subunit antagonists: Besonprodil
- CERC-301 (MK-0657)
- CO-101,244 (PD-174,494)
- Eliprodil
- Haloperidol
- Ifenprodil
- Isoxsuprine
- Nylidrin
- Ro8-4304
- Ro25-6981
- Traxoprodil; Polyamine site antagonists: Arcaine
- Co 101676
- Diaminopropane
- Acamprosate
- Diethylenetriamine
- Huperzine A
- Putrescine
- Ro 25-6981; Unclassified/unsorted antagonists: Chloroform
- Diethyl ether
- Diphenidine
- Enflurane
- Ethanol (alcohol)
- Halothane
- Isoflurane
- Methoxyflurane
- Toluene
- Trichloroethane
- Trichloroethanol
- Trichloroethylene
- Xylene
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Kainate
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- Agonists: 5-Iodowillardiine
- ATPA
- Domoic acid
- Kainic acid
- LY-339,434
- SYM-2081
Antagonists: BGG492
- CNQX
- DNQX
- LY-382,884
- NBQX
- NS102
- Tezampanel
- Topiramate
- UBP-302; Negative allosteric modulators: NS-3763
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Metabotropic |
Group I
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- Agonists: Non-selective: ACPD
- DHPG
- Quisqualic acid; mGlu1-selective: Ro01-6128
- Ro67-4853
- Ro67-7476
- VU-71; mGlu5-selective: ADX-47273
- CDPPB
- CHPG
- DFB
- VU-1545
Antagonists: Non-selective: MCPG
- NPS-2390; mGlu1-selective: BAY 36-7620
- CPCCOEt
- LY-367,385
- LY-456,236; mGlu5-selective: CTEP
- DMeOB
- LY-344,545
- Mavoglurant
- SIB-1757
- SIB-1893; Negative allosteric modulators:
- Basimglurant
- Dipraglurant
- Fenobam
- GRN-529
- MPEP
- MTEP
- Raseglurant
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Group II
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- Agonists: Non-selective: CBiPES
- DCG-IV
- Eglumegad
- LY-379,268
- LY-404,039
- LY-487,379
- MGS-0028; mGlu2-selective: BINA
- LY-566,332
Antagonists: Non-selective: APICA
- EGLU
- HYDIA
- LY-307,452
- LY-341,495
- MCPG
- MGS-0039; mGlu2-selective: PCCG-4
- mGlu3-selective: CECXG; Negative allosteric modulators: Decoglurant
- RO4491533
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Group III
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- Agonists: Non-selective: L-AP4; mGlu4-selective: PHCCC
- VU-001,171
- VU-0155,041; mGlu7-selective: AMN082; mGlu8-selective: DCPG
Antagonists: Non-selective: CPPG
- MAP4
- MSOP
- MPPG
- MTPG
- UBP-1112; mGlu7-selective: MMPIP
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Transporter
inhibitors |
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Others |
Precursors
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Cofactors
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- α-Ketoglutaric acid
- Iron
- Sulfur
- Vitamin B2 (as FAD and FMN)
- Vitamin B3 (as NADPH)
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Others
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- N-Acetylcysteine
- L-Theanine
- Riluzole
- Tianeptine
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Neuroethology
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Concepts |
- Feedforward
- Coincidence detector
- Umwelt
- Instinct
- Feature detection
- Central pattern generator (CPG)
- NMDA receptor
- Lateral inhibition
- Fixed action pattern
- Krogh's Principle
- Hebbian theory
- Anti-Hebbian learning
- Sound localization
- Ultrasound avoidance in insects
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People |
- Theodore Holmes Bullock
- Walter Heiligenberg
- Niko Tinbergen
- Konrad Lorenz
- Donald Griffin
- Donald Kennedy
- Karl von Frisch
- Erich von Holst
- Jörg-Peter Ewert
- Franz Huber
- Bernhard Hassenstein
- Werner E. Reichardt
- Eric Knudsen
- Eric Kandel
- Nobuo Suga
- Masakazu Konishi
- Fernando Nottebohm
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Methods |
- Patch clamp
- Slice preparation
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Systems |
- Animal echolocation
- Waggle dance
- Jamming avoidance response
- Vision in toads
- Frog hearing and communication
- Infrared sensing in snakes
- Caridoid escape reaction
- Vocal learning
- Surface wave detection
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