RORARAR-related orphan receptor A
Autism Reports / Total Reports
8 / 26Rare Variants / Common Variants
25 / 1Aliases
RORA, RORalpha, ROR1, ROR2, ROR3, RZRA, NR1F1, MGC119326, MGC119329, RZR-ALPHA, DKFZp686M2414, RORAAssociated Syndromes
-Chromosome Band
15q22.2Associated Disorders
ASD, EP, EPSRelevance to Autism
Immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (Nguyen et al., 2010).
Molecular Function
A member of the nuclear hormone-receptor superfamily
External Links
SFARI Genomic Platforms
Reports related to RORA (26 Reports)
| # | Type | Title | Author, Year | Autism Report | Associated Disorders |
|---|---|---|---|---|---|
| 1 | Highly Cited | RORalpha coordinates reciprocal signaling in cerebellar development through sonic hedgehog and calcium-dependent pathways | Gold DA , et al. (2003) | No | - |
| 2 | Highly Cited | A functional genomics strategy reveals Rora as a component of the mammalian circadian clock | Sato TK , et al. (2004) | No | - |
| 3 | Recent Recommendation | The nuclear receptor ROR(alpha) exerts a bi-directional regulation of IL-6 in resting and reactive astrocytes | Journiac N , et al. (2009) | No | - |
| 4 | Recent Recommendation | RORalpha attenuates Wnt/beta-catenin signaling by PKCalpha-dependent phosphorylation in colon cancer | Lee JM , et al. (2010) | No | - |
| 5 | Recent Recommendation | Regulation of FGF21 expression and secretion by retinoic acid receptor-related orphan receptor alpha | Wang Y , et al. (2010) | No | - |
| 6 | Primary | Global methylation profiling of lymphoblastoid cell lines reveals epigenetic contributions to autism spectrum disorders and a novel autism candidate gene, RORA, whose protein product is reduced in autistic brain | Nguyen A , et al. (2010) | Yes | - |
| 7 | Recent Recommendation | Induction of early Purkinje cell dendritic differentiation by thyroid hormone requires ROR? | Boukhtouche F , et al. (2010) | No | - |
| 8 | Recent Recommendation | Characterization of the core mammalian clock component, NPAS2, as a REV-ERBalpha/RORalpha target gene | Crumbley C , et al. (2010) | No | - |
| 9 | Recent Recommendation | Sex hormones in autism: androgens and estrogens differentially and reciprocally regulate RORA, a novel candidate gene for autism | Sarachana T , et al. (2011) | No | - |
| 10 | Recent Recommendation | Genome-wide identification of transcriptional targets of RORA reveals direct regulation of multiple genes associated with autism spectrum disorder | Sarachana T and Hu VW (2013) | No | - |
| 11 | Recent Recommendation | Mature Purkinje cells require the retinoic acid-related orphan receptor-? (ROR?) to maintain climbing fiber mono-innervation and other adult characteristics | Chen XR , et al. (2013) | No | - |
| 12 | Recent Recommendation | A direct molecular link between the autism candidate gene RORa and the schizophrenia candidate MIR137 | Devanna P and Vernes SC (2014) | No | - |
| 13 | Recent Recommendation | Overlapping microdeletions involving 15q22.2 narrow the critical region for intellectual disability to NARG2 and RORA | Yamamoto T , et al. (2014) | No | Epilepsy/seizures, autistic features |
| 14 | Support | Synaptic, transcriptional and chromatin genes disrupted in autism | De Rubeis S , et al. (2014) | Yes | - |
| 15 | Positive Association | Retinoic acid-related orphan receptor alpha (RORA) variants are associated with autism spectrum disorder | Sayad A , et al. (2017) | Yes | - |
| 16 | Support | Using medical exome sequencing to identify the causes of neurodevelopmental disorders: Experience of 2 clinical units and 216 patients | Chrot E , et al. (2017) | No | Epilepsy, ataxia |
| 17 | Recent Recommendation | Dual Molecular Effects of Dominant RORA Mutations Cause Two Variants of Syndromic Intellectual Disability with Either Autism or Cerebellar Ataxia | Guissart C , et al. (2018) | No | ASD, cerebellar ataxia |
| 18 | Support | - | Yu H et al. (2022) | Yes | - |
| 19 | Support | - | Xiao L et al. (2022) | No | - |
| 20 | Support | - | Zhou X et al. (2022) | Yes | - |
| 21 | Support | - | Cirnigliaro M et al. (2023) | Yes | - |
| 22 | Support | - | Sanchis-Juan A et al. (2023) | No | - |
| 23 | Support | - | Lowther C et al. (2023) | Yes | - |
| 24 | Support | - | Jia Q et al. (2023) | Yes | - |
| 25 | Support | - | Axel Schmidt et al. (2024) | No | - |
| 26 | Highly Cited | Disruption of the nuclear hormone receptor RORalpha in staggerer mice | Hamilton BA , et al. (1996) | No | - |
Rare Variants (25)
| Status | Allele Change | Residue Change | Variant Type | Inheritance Pattern | Parental Transmission | Family Type | PubMed ID | Author, Year |
|---|---|---|---|---|---|---|---|---|
| - | - | copy_number_loss | De novo | - | - | 24525055 | Yamamoto T , et al. (2014) | |
| - | - | copy_number_loss | Unknown | - | - | 24525055 | Yamamoto T , et al. (2014) | |
| - | - | copy_number_gain | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| - | - | copy_number_loss | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| - | - | copy_number_loss | De novo | - | Simplex | 37595579 | Lowther C et al. (2023) | |
| c.137G>A | p.Ser46Asn | missense_variant | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.1498C>T | p.Leu500= | stop_gained | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.517C>G | p.Arg173Gly | missense_variant | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.1248G>T | p.Gly416%3D | synonymous_variant | De novo | - | - | 35982159 | Zhou X et al. (2022) | |
| c.269G>C | p.Cys90Ser | missense_variant | Unknown | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.275G>C | p.Gly92Ala | missense_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.281A>G | p.Lys94Arg | missense_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.1225A>C | p.Asn409His | missense_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.1385G>A | p.Arg462Gln | missense_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.1484G>A | p.Arg495Gln | missense_variant | De novo | - | - | 25363760 | De Rubeis S , et al. (2014) | |
| c.393_395del | p.Arg132del | inframe_deletion | De novo | - | Simplex | 35982159 | Zhou X et al. (2022) | |
| c.1118del | p.Arg373ProfsTer17 | frameshift_variant | De novo | - | - | 28708303 | Chrot E , et al. (2017) | |
| - | - | copy_number_loss | Familial | Paternal | Multi-generational | 24525055 | Yamamoto T , et al. (2014) | |
| - | - | copy_number_loss | Familial | Maternal | Multi-generational | 29656859 | Guissart C , et al. (2018) | |
| c.997del | p.Ile333LeufsTer11 | frameshift_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.1396C>A | p.Arg466Ser | missense_variant | Unknown | - | Simplex | 37541188 | Sanchis-Juan A et al. (2023) | |
| c.425-1G>A | p.Ala142_Leu273del | splice_site_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.781_782del | p.Ile261GlnfsTer10 | frameshift_variant | De novo | - | - | 29656859 | Guissart C , et al. (2018) | |
| c.966_975dup | p.Glu326IlefsTer20 | frameshift_variant | De novo | - | - | 39039281 | Axel Schmidt et al. (2024) | |
| c.100_103del | p.Ser34ProfsTer19 | frameshift_variant | Familial | Maternal | Multiplex (monozygotic twins) | 37506195 | Cirnigliaro M et al. (2023) |
Common Variants (1)
| Status | Allele Change | Residue Change | Variant Type | Inheritance Pattern | Paternal Transmission | Family Type | PubMed ID | Author, Year |
|---|---|---|---|---|---|---|---|---|
| c.166+54254G>A;c.-328+54254G>A | - | intron_variant | - | - | - | 28608249 | Sayad A , et al. (2017) |
SFARI Gene score
Syndromic
Immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (Nguyen et al., 2010). A major isoform of RORA protein in human brain, RORA1, was shown by ChIP analysis in human neuronal cells to be recruited to the promoter regions of over 2,500 genes, with subsequent gene ontology analysis showing statistically significant enrichment in biological processes relevant to ASD (Sarachana and Hu, 2013). In the same report, RORA1 was confirmed to bind to the promoter regions of several ASD candidate genes whose expression levels were reduced in RORA1-repressed human neuronal cells and in ASD prefrontal cortex tissues. De novo and inherited 15q22.2 deletions involving the RORA gene were identified in five individuals from DECIPHER presenting with intellectual disability, epilepsy, and, in one case, autistic features (Yamamoto et al., 2014). Overrepresentation of the T allele of the RORA SNP rs4774388 was observed in a cohort of 518 Iranian ASD patients compared to 472 controls in Sayad et al., 2017; the rs4774388-TT genotype was also significantly higher in ASD patients compared with controls and was associated with ASD risk in a dominant inheritance model in this report. The phenotypes observed in 16 individuals from 13 families with dominant RORA mutations in Guissart et al., 2018 included developmental delay/intellectual disability (15/16), seizures (11/16), ASD (5/16), and cerebellar ataxia (4/16).
Score Delta: Score remained at S
criteria met
See SFARI Gene'scoring criteriaThe 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."
10/1/2019
Score remained at S
New Scoring Scheme
Description
Immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (Nguyen et al., 2010). A major isoform of RORA protein in human brain, RORA1, was shown by ChIP analysis in human neuronal cells to be recruited to the promoter regions of over 2,500 genes, with subsequent gene ontology analysis showing statistically significant enrichment in biological processes relevant to ASD (Sarachana and Hu, 2013). In the same report, RORA1 was confirmed to bind to the promoter regions of several ASD candidate genes whose expression levels were reduced in RORA1-repressed human neuronal cells and in ASD prefrontal cortex tissues. De novo and inherited 15q22.2 deletions involving the RORA gene were identified in five individuals from DECIPHER presenting with intellectual disability, epilepsy, and, in one case, autistic features (Yamamoto et al., 2014). Overrepresentation of the T allele of the RORA SNP rs4774388 was observed in a cohort of 518 Iranian ASD patients compared to 472 controls in Sayad et al., 2017; the rs4774388-TT genotype was also significantly higher in ASD patients compared with controls and was associated with ASD risk in a dominant inheritance model in this report. The phenotypes observed in 16 individuals from 13 families with dominant RORA mutations in Guissart et al., 2018 included developmental delay/intellectual disability (15/16), seizures (11/16), ASD (5/16), and cerebellar ataxia (4/16).
Reports Added
[New Scoring Scheme]7/1/2018
Decreased from 5 to S
Description
Immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (Nguyen et al., 2010). A major isoform of RORA protein in human brain, RORA1, was shown by ChIP analysis in human neuronal cells to be recruited to the promoter regions of over 2,500 genes, with subsequent gene ontology analysis showing statistically significant enrichment in biological processes relevant to ASD (Sarachana and Hu, 2013). In the same report, RORA1 was confirmed to bind to the promoter regions of several ASD candidate genes whose expression levels were reduced in RORA1-repressed human neuronal cells and in ASD prefrontal cortex tissues. De novo and inherited 15q22.2 deletions involving the RORA gene were identified in five individuals from DECIPHER presenting with intellectual disability, epilepsy, and, in one case, autistic features (Yamamoto et al., 2014). Overrepresentation of the T allele of the RORA SNP rs4774388 was observed in a cohort of 518 Iranian ASD patients compared to 472 controls in Sayad et al., 2017; the rs4774388-TT genotype was also significantly higher in ASD patients compared with controls and was associated with ASD risk in a dominant inheritance model in this report. The phenotypes observed in 16 individuals from 13 families with dominant RORA mutations in Guissart et al., 2018 included developmental delay/intellectual disability (15/16), seizures (11/16), ASD (5/16), and cerebellar ataxia (4/16).
7/1/2017
Decreased from 5 to 5
Description
While there are no apparent human genetic studies on the RORA gene, immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (PMID 20375269).
1/1/2016
Decreased from 5 to 5
Description
While there are no apparent human genetic studies on the RORA gene, immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (PMID 20375269).
Reports Added
[Global methylation profiling of lymphoblastoid cell lines reveals epigenetic contributions to autism spectrum disorders and a novel autism candidat...2010] [Overlapping microdeletions involving 15q22.2 narrow the critical region for intellectual disability to NARG2 and RORA.2014] [Disruption of the nuclear hormone receptor RORalpha in staggerer mice.1996] [RORalpha coordinates reciprocal signaling in cerebellar development through sonic hedgehog and calcium-dependent pathways.2003] [A functional genomics strategy reveals Rora as a component of the mammalian circadian clock.2004] [The nuclear receptor ROR(alpha) exerts a bi-directional regulation of IL-6 in resting and reactive astrocytes.2009] [RORalpha attenuates Wnt/beta-catenin signaling by PKCalpha-dependent phosphorylation in colon cancer.2010] [Regulation of FGF21 expression and secretion by retinoic acid receptor-related orphan receptor alpha.2010] [Induction of early Purkinje cell dendritic differentiation by thyroid hormone requires ROR.2010] [Characterization of the core mammalian clock component, NPAS2, as a REV-ERBalpha/RORalpha target gene.2010] [Sex hormones in autism: androgens and estrogens differentially and reciprocally regulate RORA, a novel candidate gene for autism.2011] [Genome-wide identification of transcriptional targets of RORA reveals direct regulation of multiple genes associated with autism spectrum disorder.2013] [Mature Purkinje cells require the retinoic acid-related orphan receptor- (ROR) to maintain climbing fiber mono-innervation and other adult charac...2013] [A direct molecular link between the autism candidate gene RORa and the schizophrenia candidate MIR137.2014] [Synaptic, transcriptional and chromatin genes disrupted in autism.2014]7/1/2014
Increased from No data to 5
Description
While there are no apparent human genetic studies on the RORA gene, immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (PMID 20375269).
4/1/2014
Increased from No data to 5
Description
While there are no apparent human genetic studies on the RORA gene, immunohistochemical analyses of tissue arrays containing slices of the cerebellum and frontal cortex of autistic and age- and sex-matched control subjects revealed decreased expression of RORA in the autistic brain (PMID 20375269).
Krishnan Probability Score
Score 0.48981494308819
Ranking 6355/25841 scored genes
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ExAC Score
Score 0.95319654970805
Ranking 2627/18225 scored genes
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Sanders TADA Score
Score 0.76929695341897
Ranking 1765/18665 scored genes
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Zhang D Score
Score 0.23829250980896
Ranking 3646/20870 scored genes
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