GRIK2glutamate ionotropic receptor kainate type subunit 2
Autism Reports / Total Reports
13 / 22Rare Variants / Common Variants
21 / 10Aliases
GRIK2, EAA4, GLR6, GLUR6, MGC74427Associated Syndromes
-Chromosome Band
6q16.3Associated Disorders
-Relevance to Autism
Studies have found genetic association between the GRIK2 gene and autism. Positive associations have been found in the Chinese Han population among others. No association between GRIK2 and autism was found in an Indian population sample, however.
Molecular Function
Glutamate receptors are the predominant excitatory neurotransmitter receptors in the mammalian brain and are activated in a variety of normal neurophysiologic processes. This gene product belongs to the kainate family of glutamate receptors, which are composed of four subunits and function as ligand-activated ion channels. The subunit encoded by this gene is subject to RNA editing at multiple sites within the first and second transmembrane domains, which is thought to alter the structure and function of the receptor complex. Mutations in this gene have been associated with autosomal recessive cognitive disability.
External Links
SFARI Genomic Platforms
Reports related to GRIK2 (22 Reports)
| # | Type | Title | Author, Year | Autism Report | Associated Disorders |
|---|---|---|---|---|---|
| 1 | Primary | Linkage and association of the glutamate receptor 6 gene with autism | Jamain S , et al. (2002) | Yes | - |
| 2 | Positive Association | Family-based association study between autism and glutamate receptor 6 gene in Chinese Han trios | Shuang M , et al. (2004) | Yes | - |
| 3 | Recent Recommendation | Glutamate receptor agonist kainate enhances primary dendrite number and length from immature mouse cortical neurons in vitro | Monnerie H and Le Roux PD (2006) | No | - |
| 4 | Recent Recommendation | Interdomain interactions in AMPA and kainate receptors regulate affinity for glutamate | Weston MC , et al. (2006) | No | - |
| 5 | Negative Association | Glutamate receptor 6 gene (GluR6 or GRIK2) polymorphisms in the Indian population: a genetic association study on autism spectrum disorder | Dutta S , et al. (2007) | Yes | - |
| 6 | Positive Association | Linkage and candidate gene studies of autism spectrum disorders in European populations | Holt R , et al. (2010) | Yes | - |
| 7 | Support | Exome sequencing of ion channel genes reveals complex profiles confounding personal risk assessment in epilepsy | Klassen T , et al. (2011) | No | - |
| 8 | Support | A discovery resource of rare copy number variations in individuals with autism spectrum disorder | Prasad A , et al. (2013) | Yes | - |
| 9 | Support | Expanding the spectrum of Grik2 mutations: intellectual disability, behavioural disorder, epilepsy and dystonia | Crdoba M , et al. (2014) | No | - |
| 10 | Positive Association | A candidate gene association study further corroborates involvement of contactin genes in autism | Poot M (2014) | Yes | - |
| 11 | Positive Association | Phenome-wide association study (PheWAS) in EMR-linked pediatric cohorts, genetically links PLCL1 to speech language development and IL5-IL13 to Eosinophilic Esophagitis | Namjou B , et al. (2014) | Yes | - |
| 12 | Recent Recommendation | Integrated systems analysis reveals a molecular network underlying autism spectrum disorders | Li J , et al. (2015) | Yes | - |
| 13 | Support | Mutations in Human Accelerated Regions Disrupt Cognition and Social Behavior | Doan RN , et al. (2016) | Yes | - |
| 14 | Support | A gain-of-function mutation in the GRIK2 gene causes neurodevelopmental deficits | Guzmn YF , et al. (2017) | No | Microcephaly, hypotonia, ataxia, stereotypic behav |
| 15 | Support | Leveraging blood serotonin as an endophenotype to identify de novo and rare variants involved in autism | Chen R , et al. (2017) | Yes | - |
| 16 | Support | Both rare and common genetic variants contribute to autism in the Faroe Islands | Leblond CS , et al. (2019) | Yes | - |
| 17 | Support | Damaging coding variants within kainate receptor channel genes are enriched in individuals with schizophrenia, autism and intellectual disabilities | Koromina M , et al. (2019) | No | - |
| 18 | Recent Recommendation | - | Stolz JR et al. (2021) | No | ASD, ID, epilepsy/seizures |
| 19 | Support | - | Woodbury-Smith M et al. (2022) | Yes | - |
| 20 | Support | - | Zhou X et al. (2022) | Yes | - |
| 21 | Highly Cited | Genotypes at the GluR6 kainate receptor locus are associated with variation in the age of onset of Huntington disease | Rubinsztein DC , et al. (1997) | No | - |
| 22 | Highly Cited | Altered synaptic physiology and reduced susceptibility to kainate-induced seizures in GluR6-deficient mice | Mulle C , et al. (1998) | No | - |
Rare Variants (21)
| Status | Allele Change | Residue Change | Variant Type | Inheritance Pattern | Parental Transmission | Family Type | PubMed ID | Author, Year |
|---|---|---|---|---|---|---|---|---|
| insA | - | intergenic_variant | - | - | Unknown | 27667684 | Doan RN , et al. (2016) | |
| - | - | copy_number_gain | Unknown | - | Unknown | 23275889 | Prasad A , et al. (2013) | |
| - | - | copy_number_loss | Unknown | - | Unknown | 23275889 | Prasad A , et al. (2013) | |
| - | - | nonsynonymous_variant | Unknown | - | Unknown | 25549968 | Li J , et al. (2015) | |
| c.493C>T | p.Gln165Ter | stop_gained | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.898C>T | p.Arg300Ter | stop_gained | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.851C>T | p.Thr284Ile | missense_variant | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.2156A>G | p.Lys719Arg | missense_variant | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.1969G>A | p.Ala657Thr | missense_variant | De novo | - | - | 34375587 | Stolz JR et al. (2021) | |
| c.1979C>A | p.Thr660Lys | missense_variant | De novo | - | - | 34375587 | Stolz JR et al. (2021) | |
| c.1979C>G | p.Thr660Arg | missense_variant | De novo | - | - | 34375587 | Stolz JR et al. (2021) | |
| c.2003T>C | p.Ile668Thr | missense_variant | De novo | - | - | 34375587 | Stolz JR et al. (2021) | |
| c.2563-2515C>T | - | intron_variant | Unknown | - | - | 35205252 | Woodbury-Smith M et al. (2022) | |
| c.1969G>A | p.Ala657Thr | missense_variant | De novo | - | - | 28180184 | Guzmn YF , et al. (2017) | |
| - | p.Lys525Glu | missense_variant | Unknown | - | Unknown | 31844109 | Koromina M , et al. (2019) | |
| C>A | p.Asn654Lys | missense_variant | Unknown | - | Unknown | 21703448 | Klassen T , et al. (2011) | |
| c.2156A>G | p.Lys719Arg | missense_variant | De novo | - | Simplex | 28344757 | Chen R , et al. (2017) | |
| c.1261C>T | p.Pro421Ser | missense_variant | Unknown | - | Unknown | 21703448 | Klassen T , et al. (2011) | |
| c.2663T>G | p.Leu888Ter | stop_gained | Familial | Maternal | Simplex | 30675382 | Leblond CS , et al. (2019) | |
| c.2663T>G | p.Leu888Ter | stop_gained | Familial | Paternal | Simplex | 30675382 | Leblond CS , et al. (2019) | |
| c.592C>T | p.Arg198Ter | stop_gained | Familial | Both parents | Multiplex | 25039795 | Crdoba M , et al. (2014) |
Common Variants (10)
| Status | Allele Change | Residue Change | Variant Type | Inheritance Pattern | Paternal Transmission | Family Type | PubMed ID | Author, Year |
|---|---|---|---|---|---|---|---|---|
| c.2424G>A;c.2277G>A;c.1809G>A;c.1863G>A | p.(=) | synonymous_variant | - | - | - | 15389769 | Shuang M , et al. (2004) | |
| c.2312-9C>T;c.2165-9C>T;c.1697-9C>T;c.1751-9C>T | N/A | intron_variant | - | - | - | 15389769 | Shuang M , et al. (2004) | |
| c.-1660G>A;c.-293-1367G>A | Minor allele, A | intron_variant, 2KB_upstream_variant | - | - | - | 25477900 | Namjou B , et al. (2014) | |
| c.116-52158T>C | - | intron_variant | - | - | - | 25337070 | Poot M (2014) | |
| C/T | N/A | intron_variant | - | - | - | 11920157 | Jamain S , et al. (2002) | |
| G/A | p.(=) | synonymous_variant | - | - | - | 11920157 | Jamain S , et al. (2002) | |
| c.724-219G>A;c.577-219G>A | A/G | intron_variant | - | - | - | 25337070 | Poot M (2014) | |
| c.951+23586G>T;c.804+23586G>T | - | intron_variant | - | - | - | 25337070 | Poot M (2014) | |
| c.2601G>A | p.Met867Ile | missense_variant | - | - | - | 11920157 | Jamain S , et al. (2002) | |
| c.116-88046T>C;c.116-88047T>C | - | intron_variant | - | - | - | 20442744 | Holt R , et al. (2010) |
SFARI Gene score
Strong Candidate
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
Score Delta: Score remained at 2
criteria met
See SFARI Gene'scoring criteriaWe considered a rigorous statistical comparison between cases and controls, yielding genome-wide statistical significance, with independent replication, to be the strongest possible evidence for a gene. These criteria were relaxed slightly for category 2.
1/1/2020
Score remained at 2
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
10/1/2019
Decreased from 3 to 2
New Scoring Scheme
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
Reports Added
[New Scoring Scheme]1/1/2019
Decreased from 3 to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
4/1/2017
Decreased from 3 to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
Reports Added
[Linkage and association of the glutamate receptor 6 gene with autism.2002] [Family-based association study between autism and glutamate receptor 6 gene in Chinese Han trios.2004] [Glutamate receptor 6 gene (GluR6 or GRIK2) polymorphisms in the Indian population: a genetic association study on autism spectrum disorder.2007] [Linkage and candidate gene studies of autism spectrum disorders in European populations.2010] [A discovery resource of rare copy number variations in individuals with autism spectrum disorder.2013] [A candidate gene association study further corroborates involvement of contactin genes in autism.2014] [Phenome-wide association study (PheWAS) in EMR-linked pediatric cohorts, genetically links PLCL1 to speech language development and IL5-IL13 to Eos...2014] [Integrated systems analysis reveals a molecular network underlying autism spectrum disorders.2015] [Exome sequencing of ion channel genes reveals complex profiles confounding personal risk assessment in epilepsy.2011] [Expanding the spectrum of Grik2 mutations: intellectual disability, behavioural disorder, epilepsy and dystonia.2014] [Genotypes at the GluR6 kainate receptor locus are associated with variation in the age of onset of Huntington disease.1997] [Altered synaptic physiology and reduced susceptibility to kainate-induced seizures in GluR6-deficient mice.1998] [Glutamate receptor agonist kainate enhances primary dendrite number and length from immature mouse cortical neurons in vitro.2006] [Interdomain interactions in AMPA and kainate receptors regulate affinity for glutamate.2006] [Mutations in Human Accelerated Regions Disrupt Cognition and Social Behavior.2016] [A gain-of-function mutation in the GRIK2 gene causes neurodevelopmental deficits.2017] [Leveraging blood serotonin as an endophenotype to identify de novo and rare variants involved in autism.2017]1/1/2017
Decreased from 3 to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
10/1/2016
Decreased from 3 to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
1/1/2015
Decreased from 3 to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
10/1/2014
Decreased from 3 to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
7/1/2014
Increased from No data to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
Reports Added
[Genotypes at the GluR6 kainate receptor locus are associated with variation in the age of onset of Huntington disease.1997] [Altered synaptic physiology and reduced susceptibility to kainate-induced seizures in GluR6-deficient mice.1998] [Linkage and association of the glutamate receptor 6 gene with autism.2002] [Family-based association study between autism and glutamate receptor 6 gene in Chinese Han trios.2004] [Glutamate receptor agonist kainate enhances primary dendrite number and length from immature mouse cortical neurons in vitro.2006] [Interdomain interactions in AMPA and kainate receptors regulate affinity for glutamate.2006] [Glutamate receptor 6 gene (GluR6 or GRIK2) polymorphisms in the Indian population: a genetic association study on autism spectrum disorder.2007] [Linkage and candidate gene studies of autism spectrum disorders in European populations.2010] [Exome sequencing of ion channel genes reveals complex profiles confounding personal risk assessment in epilepsy.2011] [A discovery resource of rare copy number variations in individuals with autism spectrum disorder.2013] [Expanding the spectrum of Grik2 mutations: intellectual disability, behavioural disorder, epilepsy and dystonia.2014]4/1/2014
Increased from No data to 3
Description
There are multiple association results that do not reach genome-wide significance to date. There are associations with other diseases, such as schizophrenia and obsessive-compulsive disorder, which boost the gene from category 4 to category 3.
Krishnan Probability Score
Score 0.61345831236162
Ranking 142/25841 scored genes
[Show Scoring Methodology]
ExAC Score
Score 0.9945679541127
Ranking 1555/18225 scored genes
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Sanders TADA Score
Score 0.92004157452794
Ranking 9111/18665 scored genes
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Larsen Cumulative Evidence Score
Score 7
Ranking 243/461 scored genes
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Zhang D Score
Score 0.34717213279251
Ranking 2055/20870 scored genes
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External PIN Data
Interactome
- Protein Binding
- DNA Binding
- RNA Binding
- Protein Modification
- Direct Regulation
- ASD-Linked Genes
Interaction Table
| Interactor Symbol | Interactor Name | Interactor Organism | Interactor Type | Entrez ID | Uniprot ID |
|---|---|---|---|---|---|
| GRIK4 | glutamate receptor, ionotropic, kainate 4 | Mouse | Protein Binding | 110637 | Q8BMF5 |
| LIN7A | lin-7 homolog A (C. elegans) | Mouse | Protein Binding | 108030 | Q8JZS0 |