CHD2Chromodomain helicase DNA binding protein 2

SFARI Gene Score

High Confidence, Syndromic Criteria 1.1, Syndromic

Autism Reports / Total Reports

31 / 83

Rare Variants / Common Variants

214 / 0

EAGLE Score

Strong Learn More

Aliases

CHD2, EEOC

Associated Syndromes

Tourette syndrome

Chromosome Band

15q26.1

Associated Disorders

DD/NDD, ADHD, ID, EP, EPS, ASD

Genetic Category

Rare Single Gene Mutation, Syndromic, Functional

Relevance to Autism

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. TADA analyses in Sanders et al., 2015, Feliciano et al., 2019, and Satterstrom et al., 2020 have all identified CHD2 as a candidate gene with a false discovery rate (FDR) 0.01; novel de novo protein-truncating variants in CHD2 were also identified in the last two reports. A two-stage analysis of rare de novo and inherited coding variants in 42,607 ASD cases, including 35,130 new cases from the SPARK cohort, in Zhou et al., 2022 identified CHD2 as a gene reaching exome-wide significance (P < 2.5E-06). De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Molecular Function

The CHD family of proteins is characterized by the presence of chromo (chromatin organization modifier) domains and SNF2-related helicase/ATPase domains. CHD genes alter gene expression possibly by modification of chromatin structure thus altering access of the transcriptional apparatus to its chromosomal DNA template.

SFARI Genomic Platforms

GPF browser SFARI genome browser

Reports (83)
Variants (214)
Gene Score
Protein Interactions (25)

Reports related to CHD2 (83 Reports)

#	Type	Title	Author, Year	Autism Report	Associated Disorders
1	Support	-	Kulkarni S et al. (2008)	No	-
2	Support	Deletion of the RMGA and CHD2 genes in a child with epilepsy and mental deficiency	Capelli LP , et al. (2011)	No	DD
3	Support	Patterns and rates of exonic de novo mutations in autism spectrum disorders	Neale BM , et al. (2012)	Yes	-
4	Support	Range of genetic mutations associated with severe non-syndromic sporadic intellectual disability: an exome sequencing study	Rauch A , et al. (2012)	No	Epilepsy, ASD
5	Primary	Targeted resequencing in epileptic encephalopathies identifies de novo mutations in CHD2 and SYNGAP1	Carvill GL , et al. (2013)	No	ID, ASD, DD
6	Positive Association	De novo mutations in epileptic encephalopathies	Epi4K Consortium , et al. (2013)	No	IS, LGS, DD, ID, ASD, ADHD
7	Recent Recommendation	De novo loss-of-function mutations in CHD2 cause a fever-sensitive myoclonic epileptic encephalopathy sharing features with Dravet syndrome	Suls A , et al. (2013)	No	ASD, ADHD
8	Support	-	Lund C et al. (2014)	No	-
9	Support	Convergence of genes and cellular pathways dysregulated in autism spectrum disorders	Pinto D , et al. (2014)	Yes	-
10	Recent Recommendation	CHD2 haploinsufficiency is associated with developmental delay, intellectual disability, epilepsy and neurobehavioural problems	Chnier S , et al. (2014)	No	ASD, TS, ADHD
11	Support	De novo mutations in synaptic transmission genes including DNM1 cause epileptic encephalopathies	EuroEPINOMICS-RES Consortium , et al. (2014)	No	-
12	Support	De novo insertions and deletions of predominantly paternal origin are associated with autism spectrum disorder	Dong S , et al. (2014)	No	-
13	Support	De novo mutations in moderate or severe intellectual disability	Hamdan FF , et al. (2014)	No	Microcephaly
14	Support	Synaptic, transcriptional and chromatin genes disrupted in autism	De Rubeis S , et al. (2014)	Yes	-
15	Support	The contribution of de novo coding mutations to autism spectrum disorder	Iossifov I et al. (2014)	Yes	-
16	Support	Large-scale discovery of novel genetic causes of developmental disorders	Deciphering Developmental Disorders Study (2014)	No	-
17	Support	-	Thomas RH et al. (2015)	No	ASD, ADHD
18	Support	-	Trivisano M et al. (2015)	No	-
19	Recent Recommendation	Low load for disruptive mutations in autism genes and their biased transmission	Iossifov I , et al. (2015)	Yes	-
20	Support	Insights into Autism Spectrum Disorder Genomic Architecture and Biology from 71 Risk Loci	Sanders SJ , et al. (2015)	Yes	-
21	Support	-	Pinto AM et al. (2016)	Yes	-
22	Support	Meta-analysis of 2,104 trios provides support for 10 new genes for intellectual disability	Lelieveld SH et al. (2016)	No	-
23	Support	Genome-wide characteristics of de novo mutations in autism	Yuen RK et al. (2016)	Yes	-
24	Support	-	Gauthier-Vasserot A et al. (2017)	No	-
25	Support	De novo genic mutations among a Chinese autism spectrum disorder cohort	Wang T , et al. (2016)	Yes	-
26	Support	Clinical exome sequencing: results from 2819 samples reflecting 1000 families	Trujillano D , et al. (2016)	No	-
27	Support	Targeted sequencing identifies 91 neurodevelopmental-disorder risk genes with autism and developmental-disability biases	Stessman HA , et al. (2017)	Yes	-
28	Support	Whole genome sequencing resource identifies 18 new candidate genes for autism spectrum disorder	C Yuen RK et al. (2017)	Yes	-
29	Positive Association	De Novo Coding Variants Are Strongly Associated with Tourette Disorder	Willsey AJ , et al. (2017)	No	-
30	Support	Genomic diagnosis for children with intellectual disability and/or developmental delay	Bowling KM , et al. (2017)	Yes	ADHD, OCD
31	Support	Rates, distribution and implications of postzygotic mosaic mutations in autism spectrum disorder	Lim ET , et al. (2017)	Yes	-
32	Support	-	Bernardo P et al. (2017)	No	Autistic features
33	Support	Autism spectrum disorder recurrence, resulting of germline mosaicism for a CHD2 gene missense variant	Lebrun N , et al. (2017)	Yes	ID, epilepsy/seizures
34	Support	Integrative Analyses of De Novo Mutations Provide Deeper Biological Insights into Autism Spectrum Disorder	Takata A , et al. (2018)	Yes	-
35	Support	-	Caputo D et al. (2018)	No	-
36	Support	The first reported case of an inherited pathogenic CHD2 variant in a clinically affected mother and daughter	Petersen AK , et al. (2018)	No	-
37	Support	Autism-linked CHD gene expression patterns during development predict multi-organ disease phenotypes	Kasah S , et al. (2018)	No	-
38	Recent Recommendation	Chd2 Is Necessary for Neural Circuit Development and Long-Term Memory	Kim YJ , et al. (2018)	No	-
39	Support	Inherited and multiple de novo mutations in autism/developmental delay risk genes suggest a multifactorial model	Guo H , et al. (2018)	Yes	-
40	Support	The combination of whole-exome sequencing and copy number variation sequencing enables the diagnosis of rare neurological disorders	Jiao Q , et al. (2019)	No	DD
41	Support	Lessons Learned from Large-Scale, First-Tier Clinical Exome Sequencing in a Highly Consanguineous Population	Monies D , et al. (2019)	No	-
42	Support	-	Routier L et al. (2019)	Yes	-
43	Support	-	Yamamoto T et al. (2019)	No	Autistic features, ID
44	Support	Clinical utility of multigene panel testing in adults with epilepsy and intellectual disability	Borlot F , et al. (2019)	No	-
45	Support	Impact of on-site clinical genetics consultations on diagnostic rate in children and young adults with autism spectrum disorder	Munnich A , et al. (2019)	Yes	-
46	Support	Exome sequencing of 457 autism families recruited online provides evidence for autism risk genes	Feliciano P et al. (2019)	Yes	-
47	Support	CHD2-related epilepsy: novel mutations and new phenotypes	Chen J , et al. (2019)	No	DD, ID, Afs
48	Support	De Novo Damaging DNA Coding Mutations Are Associated With Obsessive-Compulsive Disorder and Overlap With Tourette's Disorder and Autism	Cappi C , et al. (2019)	No	-
49	Support	-	Poisson A et al. (2020)	No	-
50	Support	Large-Scale Exome Sequencing Study Implicates Both Developmental and Functional Changes in the Neurobiology of Autism	Satterstrom FK et al. (2020)	Yes	-
51	Support	-	Singh N et al. (2020)	Yes	-
52	Support	Rare genetic susceptibility variants assessment in autism spectrum disorder: detection rate and practical use	Husson T , et al. (2020)	Yes	-
53	Support	-	Mitta N et al. (2020)	No	-
54	Support	Large-scale targeted sequencing identifies risk genes for neurodevelopmental disorders	Wang T et al. (2020)	Yes	ID
55	Support	-	Brunet T et al. (2021)	No	-
56	Support	-	Zou D et al. (2021)	No	-
57	Support	-	Trakadis Y et al. (2021)	No	DD, epilepsy/seizures
58	Support	-	Mahjani B et al. (2021)	Yes	-
59	Support	-	De Maria B et al. (2021)	No	ASD or autistic features, ADHD
60	Support	-	Li D et al. (2022)	Yes	-
61	Support	-	Wang Q et al. (2022)	No	-
62	Support	-	Brea-FernÃÂ¡ndez AJ et al. (2022)	No	-
63	Support	-	Luo X et al. (2022)	No	DD, ID
64	Support	-	Chuan Z et al. (2022)	No	-
65	Support	-	Wang X et al. (2022)	No	-
66	Support	-	Feng W et al. (2022)	No	Autistic features
67	Support	-	Stenshorne I et al. (2022)	No	-
68	Support	-	Zhou X et al. (2022)	Yes	-
69	Support	-	Lewis EMA et al. (2022)	No	-
70	Support	-	Shimelis H et al. (2023)	No	-
71	Support	-	Yuan B et al. (2023)	Yes	-
72	Support	-	Lasser M et al. (2023)	Yes	-
73	Support	-	Sheth F et al. (2023)	Yes	DD, ID
74	Support	-	Atefeh Mir et al. (2024)	No	-
75	Support	-	Ana Karen Sandoval-Talamantes et al. (2023)	Yes	ID
76	Support	-	Eleni Angelopoulou et al. (2023)	No	-
77	Support	-	Luigi Vetri et al. (2024)	No	-
78	Support	-	Marketa Wayhelova et al. (2024)	No	-
79	Support	-	Magdalena Badura-Stronka et al. (2024)	No	ID
80	Support	-	Francesca Cogliati et al. ()	No	DD, epilepsy/seizures
81	Support	-	Lei Wan et al. (2024)	Yes	-
82	Support	-	Angela Clara-Hwang et al. (2024)	No	ASD, ADHD
83	Support	-	Axel Schmidt et al. (2024)	No	ID

Rare Variants (214)

Allele Change	Residue Change	Variant Type	Inheritance Pattern	Parental Transmission	Family Type	PubMed ID	Author, Year
-	-	stop_gained	De novo	-	-	31993582	Singh N et al. (2020)
-	-	translocation	De novo	-	-	18386809	Kulkarni S et al. (2008)
-	-	copy_number_loss	De novo	-	-	24834135	Chnier S , et al. (2014)
-	-	copy_number_loss	De novo	-	-	25672921	Thomas RH et al. (2015)
-	-	copy_number_loss	De novo	-	-	34713950	De Maria B et al. (2021)
-	-	frameshift_variant	De novo	-	-	28554332	Bowling KM , et al. (2017)
-	p.Arg121Ter	stop_gained	De novo	-	-	25672921	Thomas RH et al. (2015)
-	p.Gln909Ter	stop_gained	De novo	-	-	25672921	Thomas RH et al. (2015)
-	-	copy_number_loss	De novo	-	Multiplex	24768552	Pinto D , et al. (2014)
-	-	copy_number_loss	De novo	-	Simplex	22178256	Capelli LP , et al. (2011)
c.670C>T	p.Arg224Ter	stop_gained	De novo	-	-	35386198	Luo X et al. (2022)
c.327C>G	p.Val109%3D	stop_gained	Unknown	-	-	33004838	Wang T et al. (2020)
c.934A>T	p.Lys312Ter	stop_gained	Unknown	-	-	33004838	Wang T et al. (2020)
c.988C>T	p.Gln330Ter	stop_gained	De novo	-	-	33004838	Wang T et al. (2020)
-	p.Leu823Pro	missense_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
-	p.Trp548Arg	missense_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
c.5035C>T	p.Arg1679Ter	stop_gained	De novo	-	-	35386198	Luo X et al. (2022)
c.1345A>T	p.Asn449Tyr	stop_gained	De novo	-	-	33004838	Wang T et al. (2020)
c.1239T>G	p.Tyr413Ter	stop_gained	De novo	-	-	35982159	Zhou X et al. (2022)
c.2692C>T	p.Gln898Ter	stop_gained	De novo	-	-	35982159	Zhou X et al. (2022)
c.443+4del	-	splice_region_variant	De novo	-	-	35982159	Zhou X et al. (2022)
c.1810-2A>C	-	splice_site_variant	De novo	-	-	24207121	Suls A , et al. (2013)
c.214G>T	p.Gly72Cys	missense_variant	Unknown	-	-	34968013	Li D et al. (2022)
c.5035C>T	p.Arg1679Ter	stop_gained	De novo	-	-	35982159	Zhou X et al. (2022)
c.1396C>T	p.Arg466Ter	stop_gained	De novo	-	-	24207121	Suls A , et al. (2013)
c.4971G>A	p.Trp1657Ter	stop_gained	De novo	-	-	24207121	Suls A , et al. (2013)
c.4489G>T	p.Glu1497Ter	stop_gained	Unknown	-	-	32593896	Mitta N et al. (2020)
c.595C>T	p.Arg199Cys	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.667C>T	p.Arg223Cys	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.667C>T	p.Arg223Cys	missense_variant	De novo	-	-	35982159	Zhou X et al. (2022)
c.3937C>T	p.Arg1313Ter	stop_gained	Unknown	-	-	34615535	Mahjani B et al. (2021)
-	p.Leu1591Terfs	frameshift_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
c.361C>T	p.Arg121Ter	stop_gained	De novo	-	-	23708187	Carvill GL , et al. (2013)
-	-	copy_number_loss	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.4012A>C	p.Lys1338Gln	missense_variant	Unknown	-	-	35386198	Luo X et al. (2022)
c.1049A>C	p.Gln350Pro	missense_variant	De novo	-	-	33004838	Wang T et al. (2020)
c.1234G>A	p.Glu412Lys	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.2095C>T	p.Arg699Trp	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.2699G>A	p.Arg900Gln	missense_variant	De novo	-	-	33004838	Wang T et al. (2020)
c.2702C>G	p.Ala901Gly	missense_variant	De novo	-	-	33004838	Wang T et al. (2020)
c.2740C>T	p.Arg914Cys	missense_variant	De novo	-	-	33004838	Wang T et al. (2020)
c.1174A>G	p.Thr392Ala	missense_variant	De novo	-	-	35982159	Zhou X et al. (2022)
c.2096G>A	p.Arg699Gln	missense_variant	De novo	-	-	35982159	Zhou X et al. (2022)
c.2426G>A	p.Arg809Gln	missense_variant	De novo	-	-	35982159	Zhou X et al. (2022)
c.2672C>A	p.Pro891His	missense_variant	De novo	-	-	36881370	Yuan B et al. (2023)
c.4636G>T	p.Arg1546Ter	stop_gained	Unknown	-	-	34363551	Trakadis Y et al. (2021)
c.3029C>G	p.Ser1010Ter	stop_gained	Unknown	-	-	36475376	Shimelis H et al. (2023)
c.3346C>T	p.Arg1116Cys	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.4034G>A	p.Arg1345Gln	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.4483G>A	p.Val1495Met	missense_variant	De novo	-	-	33004838	Wang T et al. (2020)
c.4507C>T	p.Arg1503Trp	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.4516C>T	p.Leu1506%3D	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.4555G>A	p.Ala1519Thr	missense_variant	De novo	-	-	33004838	Wang T et al. (2020)
c.5071C>T	p.Pro1691Ser	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.5129G>A	p.Arg1710Gln	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.5362C>T	p.Arg1788Cys	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.5369C>A	p.Pro1790His	missense_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.4602G>T	p.Trp1534Cys	missense_variant	De novo	-	-	35982159	Zhou X et al. (2022)
c.522del	p.Val175Ter	frameshift_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.2506-2A>G	-	splice_site_variant	De novo	-	Simplex	30564305	Guo H , et al. (2018)
c.1053-1G>C	-	splice_site_variant	Unknown	-	Unknown	35266334	Wang Q et al. (2022)
c.1809+1G>T	-	splice_site_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.3595+1G>T	-	splice_site_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.1693A>G	p.Ile565Val	missense_variant	Unknown	-	-	35571021	Chuan Z et al. (2022)
c.4278+1del	-	frameshift_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.*2273G>A	-	3_prime_UTR_variant	De novo	-	Simplex	27525107	Yuen RK et al. (2016)
c.3782G>A	p.Trp1261Ter	stop_gained	De novo	-	-	31452935	Feliciano P et al. (2019)
c.1390A>T	p.Arg464Ter	stop_gained	De novo	-	-	35979408	Stenshorne I et al. (2022)
c.1250G>A	p.Trp417Ter	stop_gained	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.1417C>T	p.Gln473Ter	stop_gained	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.5054G>A	p.Arg1685His	missense_variant	De novo	-	-	27824329	Wang T , et al. (2016)
c.3947A>G	p.Tyr1316Cys	missense_variant	De novo	-	-	30945278	Jiao Q , et al. (2019)
c.5120G>A	p.Arg1707Gln	missense_variant	De novo	-	-	31677157	Chen J , et al. (2019)
c.5053C>T	p.Arg1685Cys	missense_variant	Unknown	-	-	35571021	Chuan Z et al. (2022)
c.1809+1del	-	frameshift_variant	De novo	-	Simplex	23020937	Rauch A , et al. (2012)
-	p.Gly1575ValfsTer	frameshift_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
c.4921C>T	p.Gln1641Ter	stop_gained	De novo	-	-	28191889	Stessman HA , et al. (2017)
c.3571C>T	p.Gln1191Ter	stop_gained	Unknown	-	-	39039281	Axel Schmidt et al. (2024)
c.3782G>A	p.Trp1261Ter	stop_gained	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.4636C>T	p.Arg1546Ter	stop_gained	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.3782G>A	p.Trp1261Ter	stop_gained	De novo	-	Simplex	35982159	Zhou X et al. (2022)
c.4921C>T	p.Gln1641Ter	stop_gained	De novo	-	Simplex	35982159	Zhou X et al. (2022)
c.2410C>T	p.Arg804Ter	stop_gained	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.1861C>T	p.Arg621Trp	missense_variant	De novo	-	-	31170314	Routier L et al. (2019)
-	p.Gly491ValfsTer13	frameshift_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
c.693-1G>T	-	splice_site_variant	De novo	-	Simplex	29346770	Takata A , et al. (2018)
c.4636C>T	p.Arg1546Ter	stop_gained	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.5007G>A	p.Trp1669Ter	stop_gained	De novo	-	Simplex	31677157	Chen J , et al. (2019)
-	p.Arg1644LysfsTer22	frameshift_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
-	p.Glu1412GlyfsTer64	frameshift_variant	De novo	-	-	25672921	Thomas RH et al. (2015)
c.693-1G>T	-	splice_site_variant	De novo	-	Simplex	31171384	Yamamoto T et al. (2019)
c.2716C>T	p.Gln906Ter	stop_gained	Unknown	-	Simplex	28263302	C Yuen RK et al. (2017)
c.2173C>T	p.Gln725Ter	stop_gained	De novo	-	Simplex	29346770	Takata A , et al. (2018)
c.335C>G	p.Ser112Ter	stop_gained	De novo	-	Simplex	25356899	Hamdan FF , et al. (2014)
c.2352+1G>A	-	splice_site_variant	De novo	-	Simplex	31406558	Munnich A , et al. (2019)
c.1642T>C	p.Trp548Arg	missense_variant	De novo	-	-	23708187	Carvill GL , et al. (2013)
c.2468T>C	p.Leu823Pro	missense_variant	De novo	-	-	23708187	Carvill GL , et al. (2013)
c.2663A>G	p.Asp888Gly	missense_variant	De novo	-	-	38256219	Luigi Vetri et al. (2024)
-	p.Gly491ValfsTer13	frameshift_variant	De novo	-	-	23708187	Carvill GL , et al. (2013)
c.2727+46A>G	-	intron_variant	De novo	-	Simplex	31981491	Satterstrom FK et al. (2020)
-	-	copy_number_loss	Unknown	-	Simplex	38328757	Magdalena Badura-Stronka et al. (2024)
c.272A>G	p.Glu91Gly	missense_variant	De novo	-	Simplex	28714951	Lim ET , et al. (2017)
c.4003G>T	p.Glu1335Ter	stop_gained	De novo	-	Simplex	31914951	Poisson A et al. (2020)
c.1562C>A	p.Ser521Ter	stop_gained	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.2963C>G	p.Ser988Ter	stop_gained	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.2699G>A	p.Arg900Gln	missense_variant	De novo	-	-	27479843	Lelieveld SH et al. (2016)
c.2699G>A	p.Arg900Gln	missense_variant	De novo	-	-	28191889	Stessman HA , et al. (2017)
c.1809G>T	p.Lys603Asn	missense_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.1934C>T	p.Thr645Met	missense_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.2095C>T	p.Arg699Trp	missense_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.2291A>G	p.His764Arg	missense_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.2593C>T	p.Leu865Phe	missense_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.2005G>T	p.Glu669Ter	nonsynonymous_variant	De novo	-	-	29529558	Caputo D et al. (2018)
c.4909C>T	p.Arg1637Ter	stop_gained	De novo	-	Simplex	25363768	Iossifov I et al. (2014)
c.3931C>T	p.Gln1311Ter	stop_gained	De novo	-	Simplex	31171384	Yamamoto T et al. (2019)
c.3937C>T	p.Arg1313Ter	stop_gained	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.5035C>T	p.Arg1679Ter	stop_gained	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.2999G>A	p.Arg1000Gln	missense_variant	De novo	-	-	25363760	De Rubeis S , et al. (2014)
c.3521G>A	p.Gly1174Asp	missense_variant	De novo	-	-	25363760	De Rubeis S , et al. (2014)
c.3782G>C	p.Trp1261Ser	missense_variant	Unknown	-	-	39039281	Axel Schmidt et al. (2024)
c.2068C>T	p.His690Tyr	missense_variant	De novo	-	-	27848944	Trujillano D , et al. (2016)
c.2416dup	p.Arg806LysfsTer20	frameshift_variant	De novo	-	-	35386198	Luo X et al. (2022)
c.11_14del	p.Asn4ArgfsTer89	frameshift_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.3237G>T	p.Lys1079Asn	missense_variant	De novo	-	Simplex	30564305	Guo H , et al. (2018)
c.3781T>C	p.Trp1261Arg	missense_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.2537G>A	p.Arg846Gln	missense_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.2609G>A	p.Gly870Asp	missense_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.2644G>T	p.Val882Phe	missense_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.2740C>T	p.Arg914Cys	missense_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.4173dup	p.Gln1392ThrfsTer17	frameshift_variant	Unknown	-	-	34145886	Zou D et al. (2021)
c.4173dup	p.Gln1392ThrfsTer17	frameshift_variant	De novo	-	-	35386198	Luo X et al. (2022)
c.1265del	p.Tyr422PhefsTer40	frameshift_variant	Unknown	-	-	33004838	Wang T et al. (2020)
c.390C>T	p.Ser130%3D	splice_site_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.1566C>G	p.Phe522Leu	missense_variant	De novo	-	Simplex	31771860	Cappi C , et al. (2019)
c.727_728del	p.Asp243Ter	stop_gained	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.4033C>T	p.Arg1345Trp	missense_variant	Familial	Paternal	-	33004838	Wang T et al. (2020)
c.4173dup	p.Gln1392ThrfsTer17	frameshift_variant	De novo	-	-	24614520	Lund C et al. (2014)
c.3455+2_3455+3insTG	-	splice_site_variant	De novo	-	Simplex	35627293	Wang X et al. (2022)
c.3454C>G	p.Arg1152Gly	missense_variant	De novo	-	Simplex	33619735	Brunet T et al. (2021)
c.2567A>G	p.Asp856Gly	missense_variant	De novo	-	Simplex	22495311	Neale BM , et al. (2012)
c.2636C>T	p.Ala879Val	missense_variant	De novo	-	Unknown	31130284	Monies D , et al. (2019)
c.1809_1809+1delinsTT	-	splice_site_variant	De novo	-	Simplex	35627293	Wang X et al. (2022)
c.5153+2T>C	-	splice_site_variant	Familial	Paternal	Simplex	31677157	Chen J , et al. (2019)
c.2095C>T	p.Arg699Trp	missense_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.2387T>C	p.Leu796Ser	missense_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.2698C>G	p.Arg900Gly	missense_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.4921C>T	p.Gln1641Ter	stop_gained	De novo	-	Simplex	31981491	Satterstrom FK et al. (2020)
c.3783G>A	p.Trp1261Ter	stop_gained	Familial	Maternal	Simplex	35627293	Wang X et al. (2022)
c.3455+2_345+3insTG	p.?	splice_site_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.3787dup	p.Val1263GlyfsTer4	frameshift_variant	Unknown	-	-	31273778	Borlot F , et al. (2019)
c.3782G>C	p.Trp1261Ser	missense_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.4528G>A	p.Gly1510Arg	missense_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.1566C>G	p.Phe522Leu	missense_variant	De novo	-	Simplex	28472652	Willsey AJ , et al. (2017)
c.1503G>A	p.Lys501=	splice_site_variant	De novo	-	-	23934111	Epi4K Consortium , et al. (2013)
c.1730_1731dup	p.Glu578MetfsTer11	frameshift_variant	De novo	-	-	35386198	Luo X et al. (2022)
c.2843G>A	p.Arg948Gln	missense_variant	Familial	Both parents	-	33004838	Wang T et al. (2020)
c.4216A>G	p.Ser1406Gly	missense_variant	De novo	-	Multiplex	28263302	C Yuen RK et al. (2017)
c.4987dup	p.His1663ProfsTer4	frameshift_variant	Unknown	-	-	34713950	De Maria B et al. (2021)
c.1570dup	p.Ser524PhefsTer30	frameshift_variant	De novo	-	-	37877434	Atefeh Mir et al. (2024)
c.947dup	p.Tyr316Ter	stop_gained	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.3682del	p.Glu1228SerfsTer21	frameshift_variant	Unknown	-	-	36475376	Shimelis H et al. (2023)
c.3787dup	p.Val1263GlyfsTer4	frameshift_variant	De novo	-	-	28554332	Bowling KM , et al. (2017)
c.4459G>A	p.Asp1487Asn	missense_variant	De novo	-	Simplex	28191889	Stessman HA , et al. (2017)
c.4003G>T	p.Glu1335Ter	stop_gained	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.1778dup	p.Thr594AsnfsTer4	frameshift_variant	Unknown	-	Simplex	31677157	Chen J , et al. (2019)
c.628G>T	p.Glu210Ter	stop_gained	Familial	Maternal	Simplex	29740950	Petersen AK , et al. (2018)
c.4459G>A	p.Asp1487Asn	missense_variant	De novo	-	Simplex	31981491	Satterstrom FK et al. (2020)
c.3734dup	p.Tyr1246IlefsTer13	frameshift_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.4164dup	p.Lys1389GlufsTer20	frameshift_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.1820G>A	p.Gly607Asp	missense_variant	Familial	Paternal	Simplex	37543562	Sheth F et al. (2023)
c.3734dup	p.Tyr1246IlefsTer13	frameshift_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.4173dup	p.Gln1392ThrfsTer17	frameshift_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.3998dup	p.Gly1334TrpfsTer29	frameshift_variant	Familial	Maternal	-	33004838	Wang T et al. (2020)
c.937_938del	p.Gly313LeufsTer11	frameshift_variant	De novo	-	Simplex	35982159	Zhou X et al. (2022)
c.4036G>C	p.Val1346Leu	missense_variant	Familial	Paternal	Multiplex	35774528	Feng W et al. (2022)
c.1903_1906del	p.Asp635SerfsTer8	frameshift_variant	De novo	-	-	27479843	Lelieveld SH et al. (2016)
c.2660_2661del	p.Ser887Ter	stop_gained	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.1540G>C	p.Gly514Arg	missense_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.1934C>A	p.Thr645Lys	missense_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.2612G>A	p.Gly871Asp	missense_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.2707A>G	p.Arg903Gly	missense_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.4233_4236del	p.Glu1412GlyfsTer64	frameshift_variant	De novo	-	-	23708187	Carvill GL , et al. (2013)
c.4931_4932del	p.Arg1644LysfsTer22	frameshift_variant	De novo	-	-	23708187	Carvill GL , et al. (2013)
c.580C>T	p.Gln194Ter	stop_gained	Familial	Maternal	Multiplex	38385826	Francesca Cogliati et al. ()
c.3787dup	p.Val1263GlyfsTer4	frameshift_variant	De novo	-	-	38321498	Marketa Wayhelova et al. (2024)
c.3112C>T	p.Arg1038Cys	missense_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.3497C>T	p.Ser1166Leu	missense_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.1961_1962del	p.Lys654ArgfsTer15	frameshift_variant	De novo	-	Simplex	35774528	Feng W et al. (2022)
c.2892_2895del	p.Asn964LysfsTer4	frameshift_variant	De novo	-	Simplex	25284784	Dong S , et al. (2014)
c.4949dup	p.Gly1651TrpfsTer16	frameshift_variant	De novo	-	Simplex	25363768	Iossifov I et al. (2014)
c.4164del	p.Met1388IlefsTer18	frameshift_variant	De novo	-	Simplex	28910737	Bernardo P et al. (2017)
c.4173del	p.Lys1391AsnfsTer15	frameshift_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.995_999del	p.Val332GlyfsTer25	frameshift_variant	Unknown	-	Simplex	32094338	Husson T , et al. (2020)
c.4256del	p.Lys1419SerfsTer58	frameshift_variant	De novo	-	Simplex	26262932	Trivisano M et al. (2015)
c.630_632del	p.Glu210del	inframe_deletion	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.767del	p.Gln256ArgfsTer12	frameshift_variant	De novo	-	-	35322241	Brea-FernÃÂ¡ndez AJ et al. (2022)
c.4052_4053del	p.Lys1351SerfsTer11	frameshift_variant	De novo	-	Simplex	31677157	Chen J , et al. (2019)
c.1994C>T	p.Pro665Leu	missense_variant	Unknown	-	-	38003033	Ana Karen Sandoval-Talamantes et al. (2023)
c.561del	p.Lys188AsnfsTer61	frameshift_variant	Unknown	Not maternal	-	34713950	De Maria B et al. (2021)
c.4771_4772del	p.Leu1591AspfsTer32	frameshift_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.1008_1009delinsT	p.Lys336AsnfsTer3	frameshift_variant	De novo	-	Simplex	34713950	De Maria B et al. (2021)
c.1199del	p.Ala400ValfsTer62	frameshift_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.5232G>A	p.Met1744Ile	missense_variant	Familial	Paternal	Multi-generational	31677157	Chen J , et al. (2019)
c.4156dup	p.Ser1386LysfsTer23	frameshift_variant	De novo	-	Multi-generational	31677157	Chen J , et al. (2019)
c.4173dup	p.Gln1392ThrfsTer17	frameshift_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.5041dup	p.Met1681AsnfsTer21	frameshift_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.390C>T	p.Ser130=	splice_site_variant	De novo	-	Simplex	25262651	EuroEPINOMICS-RES Consortium , et al. (2014)
c.1934C>T	p.Thr645Met	missense_variant	De novo (germline mosaicism)	-	Multiplex	28960266	Lebrun N , et al. (2017)
c.4937_4940dup	p.Tyr1648GlnfsTer20	frameshift_variant	De novo	-	Simplex	39035822	Angela Clara-Hwang et al. (2024)
c.5094dup	p.Pro1699AlafsTer3	frameshift_variant	Unknown	Not maternal	-	27615324	Gauthier-Vasserot A et al. (2017)
c.1942C>T	p.Pro648Ser	missense_variant	De novo	-	Simplex	25533962	Deciphering Developmental Disorders Study (2014)
c.5035C>T	p.Arg1679Ter	stop_gained	Familial	Maternal	Multi-generational	38125503	Eleni Angelopoulou et al. (2023)
c.4173dup	p.Gln1392ThrfsTer17	frameshift_variant	De novo	-	Multiplex (monozygotic twins)	26754451	Pinto AM et al. (2016)
c.4797_4812del	p.His1599GlnfsTer210	frameshift_variant	De novo	-	Simplex	25533962	Deciphering Developmental Disorders Study (2014)

Common Variants

No common variants reported.

Current Score
Scoring History
3rd Party Scoring

SFARI Gene score

High Confidence, Syndromic

Score Delta: Score remained at 1S

criteria met

See SFARI Gene'scoring criteria

High Confidence

See all Category 1 Genes

We 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.

Syndromic

See all Category S Genes

The syndromic category includes mutations that are associated with a substantial degree of increased risk and consistently linked to additional characteristics not required for an ASD diagnosis. If there is independent evidence implicating a gene in idiopathic ASD, it will be listed as "#S" (e.g., 2S, 3S, etc.). If there is no such independent evidence, the gene will be listed simply as "S."

1/1/2021

Score remained at 1

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Disruption of chromodomain helicase DNA binding protein 2 (CHD2) causes scoliosis2008] [CHD2 mutations in Lennox-Gastaut syndrome2014] [CHD2 myoclonic encephalopathy is frequently associated with self-induced seizures2015] [CHD2 mutations are a rare cause of generalized epilepsy with myoclonic-atonic seizures2015] [Exome sequencing analysis in a pair of monozygotic twins re-evaluates the genetics behind their intellectual disability and reveals a CHD2 mutation2016] [Application of whole-exome sequencing to unravel the molecular basis of undiagnosed syndromic congenital neutropenia with intellectual disability2017] [CHD2 mutations: Only epilepsy? Description of cognitive and behavioral profile in a case with a new mutation2017] [CHD2-epilepsy: Polygraphic documentation of self-induced seizures due to fixation-off sensitivity2018] [Exome sequencing findings in 27 patients with myoclonic-atonic epilepsy: Is there a major genetic factor?2019] [Genomic backgrounds of Japanese patients with undiagnosed neurodevelopmental disorders2019] [Chromatin remodeling dysfunction extends the etiological spectrum of schizophrenia: a case report2020] [Juvenile myoclonic epilepsy mimic associated with CHD2 gene mutation2020] [Genotype-phenotype correlates of infantile-onset developmental & epileptic encephalopathy syndromes in South India: A single centre experience2020] [De novo variants in neurodevelopmental disorders-experiences from a tertiary care center2021]

10/1/2020

Score remained at 1

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Large-scale targeted sequencing identifies risk genes for neurodevelopmental disorders2020]

1/1/2020

Score remained at 1

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Insights into Autism Spectrum Disorder Genomic Architecture and Biology from 71 Risk Loci.2015] [De Novo Damaging DNA Coding Mutations Are Associated With Obsessive-Compulsive Disorder and Overlap With Tourette's Disorder and Autism.2019] [Large-Scale Exome Sequencing Study Implicates Both Developmental and Functional Changes in the Neurobiology of Autism2020] [Rare genetic susceptibility variants assessment in autism spectrum disorder: detection rate and practical use.2020]

10/1/2019

Score remained at 1

New Scoring Scheme

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Exome sequencing of 457 autism families recruited online provides evidence for autism risk genes2019] [CHD2-related epilepsy: novel mutations and new phenotypes.2019] [New Scoring Scheme]

7/1/2019

Score remained at 1S

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Lessons Learned from Large-Scale, First-Tier Clinical Exome Sequencing in a Highly Consanguineous Population.2019] [Clinical utility of multigene panel testing in adults with epilepsy and intellectual disability.2019] [Impact of on-site clinical genetics consultations on diagnostic rate in children and young adults with autism spectrum disorder.2019]

4/1/2019

Score remained at 1S

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[The combination of whole-exome sequencing and copy number variation sequencing enables the diagnosis of rare neurological disorders.2019]

1/1/2019

Score remained at 1S

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Inherited and multiple de novo mutations in autism/developmental delay risk genes suggest a multifactorial model.2018]

10/1/2018

Score remained at 1S

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

Reports Added

[Autism-linked CHD gene expression patterns during development predict multi-organ disease phenotypes.2018] [Chd2 Is Necessary for Neural Circuit Development and Long-Term Memory.2018]

7/1/2018

Decreased from 2S to 1S

Description

Three de novo loss-of-function (LoF) variants in the CHD2 gene were identified in ASD probands from the Simons Simplex Collection (Dong et al., 2014; Iossifov et al., 2014). De novo LoF and missense variants in CHD2 have also been identified in ASD probands from the Autism Sequencing Consortium, the Autism Clinical and Genetic Resources in China (ACGC) cohort, the Autism Genetic Resource Exchange, and the Autism Simplex Collection (De Rubeis et al., 2014; Wang et al., 2016; Stessman et al., 2017).Two additional de novo LoF variants in CHD2 were recently identified in ASD probands from a cohort of 262 Japanese trios in Takata et al., 2018; TADA-Denovo analysis demonstrated that this gene was significantly enriched for damaging de novo mutations in the Japanese ASD cohort, as well as in a combined dataset consisting of previously published cohorts from the Simons Simplex Collection and the Autism Sequencing Consortium in addition to the Japanese ASD cohort. De novo loss-of-function and missense variants in the CHD2 gene had previously been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (Rauch et al., 2012; Carvill et al., 2013; Epi4K Consortium 2013; Suls et al., 2013); two cases with de novo LoF CHD2 variants from these reports also presented with ASD. De novo deletions affecting CHD2 had also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (Chenier et al., 2014).

10/1/2017

Decreased from 2S to 2S

Description

De novo loss-of-function and missense variants in the CHD2 gene have been identified in a total of 11 patients presenting with epilepsy and developmental delay/intellectual disability from four reports (PMIDs 23020937, 23708187, 23934111, and 24207121). Two cases with de novo LoF CHD2 variants also presented with ASD (PMIDs 23708187 and 24207121). De novo deletions affecting CHD2 have also been identified in 4 patients with recurrent clinical symptoms such as epilepsy, developmental delay/intellectual disability, and behavioral problem, including ASD in one case (PMID 24834135). Two additional de novo LoF variants in the CHD2 gene (one nonsense, one frameshift) were recently identified in ASD probands from the Simons Simplex Collection (PMID 25363768).

Reports Added

[Autism spectrum disorder recurrence, resulting of germline mosaicism for a CHD2 gene missense variant.2017]

7/1/2017

Decreased from 2S to 2S

Description

Reports Added

[Rates, distribution and implications of postzygotic mosaic mutations in autism spectrum disorder.2017]

4/1/2017

Decreased from 2S to 2S

Description

Reports Added

[Patterns and rates of exonic de novo mutations in autism spectrum disorders.2012] [Convergence of genes and cellular pathways dysregulated in autism spectrum disorders.2014] [The contribution of de novo coding mutations to autism spectrum disorder2014] [CHD2 haploinsufficiency is associated with developmental delay, intellectual disability, epilepsy and neurobehavioural problems.2014] [Large-scale discovery of novel genetic causes of developmental disorders.2014] [Deletion of the RMGA and CHD2 genes in a child with epilepsy and mental deficiency.2011] [Targeted resequencing in epileptic encephalopathies identifies de novo mutations in CHD2 and SYNGAP1.2013] [De novo mutations in epileptic encephalopathies.2013] [De novo loss-of-function mutations in CHD2 cause a fever-sensitive myoclonic epileptic encephalopathy sharing features with Dravet syndrome.2013] [Range of genetic mutations associated with severe non-syndromic sporadic intellectual disability: an exome sequencing study.2012] [De novo insertions and deletions of predominantly paternal origin are associated with autism spectrum disorder.2014] [Low load for disruptive mutations in autism genes and their biased transmission.2015] [Synaptic, transcriptional and chromatin genes disrupted in autism.2014] [Meta-analysis of 2,104 trios provides support for 10 new genes for intellectual disability2016] [Genome-wide characteristics of de novo mutations in autism2016] [De novo genic mutations among a Chinese autism spectrum disorder cohort.2016] [Clinical exome sequencing: results from 2819 samples reflecting 1000 families.2016] [Targeted sequencing identifies 91 neurodevelopmental-disorder risk genes with autism and developmental-disability biases.2017] [Whole genome sequencing resource identifies 18 new candidate genes for autism spectrum disorder2017] [De novo mutations in moderate or severe intellectual disability.2014] [De Novo Coding Variants Are Strongly Associated with Tourette Disorder.2017] [Genomic diagnosis for children with intellectual disability and/or developmental delay.2017]

1/1/2017

Decreased from 2S to 2S

Description

Reports Added

[Targeted sequencing identifies 91 neurodevelopmental-disorder risk genes with autism and developmental-disability biases.2017]

10/1/2016

Decreased from 2S to 2S

Description

Reports Added

[De novo genic mutations among a Chinese autism spectrum disorder cohort.2016] [Clinical exome sequencing: results from 2819 samples reflecting 1000 families.2016]

7/1/2016

Decreased from 2S to 2S

Description

Reports Added

[Meta-analysis of 2,104 trios provides support for 10 new genes for intellectual disability2016] [Genome-wide characteristics of de novo mutations in autism2016]

1/1/2016

Decreased from 2S to 2S

Description

Reports Added

1/1/2015

Decreased from 2S to 2S

Description

Reports Added

[Large-scale discovery of novel genetic causes of developmental disorders.2014]

10/1/2014

Decreased from 3S to 2S

Description

Reports Added

[De novo insertions and deletions of predominantly paternal origin are associated with autism spectrum disorder.2014] [The contribution of de novo coding mutations to autism spectrum disorder2014]

7/1/2014

No data

Increased from No data to 3S

Description

4/1/2014

No data

Increased from No data to 3S

Description

Reports Added

[CHD2 haploinsufficiency is associated with developmental delay, intellectual disability, epilepsy and neurobehavioural problems.2014] [Convergence of genes and cellular pathways dysregulated in autism spectrum disorders.2014]

Krishnan Probability Score

Score 0.47577089053778

Ranking 8536/25841 scored genes

[Show Scoring Methodology]

Krishnan and colleagues generated probability scores genome-wide by using a machine learning approach on a human brain-specific gene network. The method was first presented in Nat Neurosci 19, 1454-1462 (2016), and scores for more than 25,000 RefSeq genes can be accessed in column G of supplementary table 3 (see: http://www.nature.com/neuro/journal/v19/n11/extref/nn.4353-S5.xlsx). A searchable browser, with the ability to view networks of associated ASD risk genes, can be found at asd.princeton.edu.

Original Source

ExAC Score

Score 0.99999999884542

Ranking 100/18225 scored genes

[Show Scoring Methodology]

The Exome Aggregation Consortium (ExAC) is a summary database of 60,706 exomes that has been widely used to estimate 'constraint' on mutation for individual genes. It was introduced by Lek et al. Nature 536, 285-291 (2016), and the ExAC browser can be found at exac.broadinstitute.org. The pLI score was developed as measure of intolerance to loss-of- function mutation. A pLI > 0.9 is generally viewed as highly constrained, and thus any loss-of- function mutations in autism in such a gene would be more likely to confer risk. For a full list of pLI scores see: ftp://ftp.broadinstitute.org/pub/ExAC_release/release0.3.1/functional_gene_constraint/fordist_cle aned_exac_nonTCGA_z_pli_rec_null_data.txt

Original Source

Iossifov Probability Score

Score 0.997

Ranking 12/239 scored genes

[Show Scoring Methodology]

Supplementary dataset S2 in the paper by Iossifov et al. (PNAS 112, E5600-E5607 (2015)) lists 239 genes with a probability of at least 0.8 of being associated with autism risk (column I). This probability metric combines the evidence from de novo likely-gene- disrupting and missense mutations and assesses it against the background mutation rate in unaffected individuals from the University of Washingtonâs Exome Variant Sequence database (evs.gs.washington.edu/EVS/). The list of probability scores can be found here: www.pnas.org/lookup/suppl/doi:10.1073/pnas.1516376112/- /DCSupplemental/pnas.1516376112.sd02.xlsx

Original Source

Sanders TADA Score

Score 6.7367674090958E-6

Ranking 7/18665 scored genes

[Show Scoring Methodology]

The TADA score ('Transmission and De novo Association') was introduced by He et al. PLoS Genet 9(8):e1003671 (2013), and is a statistic that integrates evidence from both de novo and transmitted mutations. It forms the basis for the claim of 65 individual genes being strongly associated with autism risk at a false discovery rate of 0.1 (Sanders et al. Neuron 87, 1215-1233 (2015)). The calculated TADA score for 18,665 RefSeq genes can be found in column P of Supplementary Table 6 in the Sanders et al. paper (the column headed 'tadaFdrAscSscExomeSscAgpSmallDel'), which represents a combined analysis of exome data and small de novo deletions (see www.cell.com/cms/attachment/2038545319/2052606711/mmc7.xlsx).

Original Source

Larsen Cumulative Evidence Score

Score 63

Ranking 24/461 scored genes

[Show Scoring Methodology]

Larsen and colleagues generated gene scores based on the sum of evidence for all available ASD-associated variants in a gene, with assessments based on mode of inheritance, effect size, and variant frequency in the general population. The approach was first presented in Mol Autism 7:44 (2016), and scores for 461 genes can be found in column I in supplementary table 4 from that paper.

Original Source

Zhang D Score

Score 0.57451349814661

Ranking 156/20870 scored genes

[Show Scoring Methodology]

The DAMAGES score (disease-associated mutation analysis using gene expression signatures), or D score, was developed to combine evidence from de novo loss-of- function mutation with evidence from cell-type- specific gene expression in the mouse brain (specifically translational profiles of 24 specific mouse CNS cell types isolated from 6 different brain regions). Genes with positive D scores are more likely to be associated with autism risk, with higher-confidence genes having higher D scores. This statistic was first presented by Zhang & Shen (Hum Mutat 38, 204- 215 (2017), and D scores for more than 20,000 RefSeq genes can be found in column M in supplementary table 2 from that paper.

Original Source

External PIN Data

BioGRID Human Protein Reference Database

Interaction Table

Interactor Symbol	Interactor Name	Interactor Organism	Interactor Type	Entrez ID	Uniprot ID
ADARB2	adenosine deaminase, RNA-specific, B2	Human	Protein Binding	105	Q9NS39
ARID5B	AT rich interactive domain 5B (MRF1-like)	Human	Protein Binding	84159	Q14865
BCKDK	branched chain ketoacid dehydrogenase kinase	Human	Protein Binding	10295	A8MY43
BEND7	BEN domain containing 7	Human	Protein Binding	222389	Q8N7W2
CENPV	centromere protein V	Human	Protein Binding	201161	Q7Z7K6
FAM120C	family with sequence similarity 120C	Human	Protein Binding	54954	Q9NX05
INO80B	INO80 complex subunit B	Human	Protein Binding	83444	Q9C086
Myl3	myosin, light chain 3, alkali; ventricular, skeletal, slow	Mouse	Direct Regulation	17897	P09542
Myod1	myogenic differentiation 1	Mouse	Protein Binding	17927	P10085
Myog	myogenin (myogenic factor 4)	Mouse	Direct Regulation	17928	P12979
PARP1	poly (ADP-ribose) polymerase 1	Human	Protein Binding	142	P09874
RBAK	RB-associated KRAB zinc finger	Human	Protein Binding	57786	Q9NYW8
RREB1	ras responsive element binding protein 1	Human	Protein Binding	6239	Q92766
SPATA12	spermatogenesis associated 12	Human	Protein Binding	353324	Q7Z6I5
THAP1	THAP domain containing, apoptosis associated protein 1	Human	Protein Binding	NM_018105	Q9NVV9
WDR33	WD repeat domain 33	Human	Protein Binding	55339	Q9C0J8
ZC3HAV1	zinc finger CCCH-type, antiviral 1	Human	Protein Binding	56829	Q7Z2W4
ZMYND11	zinc finger, MYND-type containing 11	Human	Protein Binding	10771	Q5BJG6
ZNF174	zinc finger protein 174	Human	Protein Binding	7727	Q15697
ZNF317	zinc finger protein 317	Human	Protein Binding	57693	Q96PQ6
ZNF462	zinc finger protein 462	Human	Protein Binding	58499	Q96JM2
ZNF592	zinc finger protein 592	Human	Protein Binding	9640	Q92610
ZNF687	zinc finger protein 687	Human	Protein Binding	57592	Q8N1G0
ZNF768	zinc finger protein 768	Human	Protein Binding	79724	Q9H5H4
ZSCAN12	zinc finger and SCAN domain containing 12	Human	Protein Binding	9753	O43309

Human Gene Module / Chromosome 15 / CHD2

CHD2Chromodomain helicase DNA binding protein 2

SFARI Gene Score

Autism Reports / Total Reports

Rare Variants / Common Variants

EAGLE Score

Aliases

Associated Syndromes

Chromosome Band

Associated Disorders

Genetic Category

Relevance to Autism

Molecular Function

External Links

Human

Mouse

Zebrafish

SFARI Genomic Platforms

Reports related to CHD2 (83 Reports)

Rare Variants (214)

Common Variants

SFARI Gene score

High Confidence, Syndromic

Score Delta: Score remained at 1S

criteria met

High Confidence

Syndromic

1/1/2021

Score remained at 1

Description

Reports Added

10/1/2020

Score remained at 1

Description

Reports Added

1/1/2020

Score remained at 1

Description

Reports Added

10/1/2019

Score remained at 1

New Scoring Scheme

Description

Reports Added

7/1/2019

Score remained at 1S

Description

Reports Added

4/1/2019

Score remained at 1S

Description

Reports Added

1/1/2019

Score remained at 1S

Description

Reports Added

10/1/2018

Score remained at 1S

Description

Reports Added

7/1/2018

Decreased from 2S to 1S

Description

10/1/2017

Decreased from 2S to 2S

Description

Reports Added

7/1/2017

Decreased from 2S to 2S

Description

Reports Added

4/1/2017

Decreased from 2S to 2S

Description

Reports Added

1/1/2017

Decreased from 2S to 2S

Description

Reports Added

10/1/2016