ClinVar Genomic variation as it relates to human health
NM_000520.6(HEXA):c.1274_1277dup (p.Tyr427fs)
The aggregate germline classification for this variant, typically for a monogenic or Mendelian disorder as in the ACMG/AMP guidelines, or for response to a drug. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the aggregate classification.
Stars represent the aggregate review status, or the level of review supporting the aggregate germline classification for this VCV record. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the review status. The number of submissions which contribute to this review status is shown in parentheses.
No data submitted for somatic clinical impact
No data submitted for oncogenicity
Variant Details
- Identifiers
-
NM_000520.6(HEXA):c.1274_1277dup (p.Tyr427fs)
Variation ID: 3889 Accession: VCV000003889.137
- Type and length
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Duplication, 4 bp
- Location
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Cytogenetic: 15q23 15: 72346579-72346580 (GRCh38) [ NCBI UCSC ] 15: 72638921-72638924 (GRCh37) [ NCBI UCSC ]
- Timeline in ClinVar
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First in ClinVar Help The date this variant first appeared in ClinVar with each type of classification.
Last submission Help The date of the most recent submission for each type of classification for this variant.
Last evaluated Help The most recent date that a submitter evaluated this variant for each type of classification.
Germline Oct 5, 2015 Nov 24, 2024 Aug 20, 2024 - HGVS
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Nucleotide Protein Molecular
consequenceNM_000520.6:c.1274_1277dup MANE Select Help Transcripts from the Matched Annotation from the NCBI and EMBL-EBI (MANE) collaboration.
NP_000511.2:p.Tyr427fs frameshift NM_000520.4:c.1274_1277dupTATC NM_000520.5:c.1274_1277dupTATC NM_001318825.2:c.1307_1310dup NP_001305754.1:p.Tyr438fs frameshift NC_000015.10:g.72346580_72346583dup NC_000015.9:g.72638921_72638924dup NG_009017.2:g.34597_34600dup NG_009017.3:g.34431_34434dup - Protein change
- Y427fs, Y438fs
- Other names
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1278insTATC
+TATC1278
p.Tyr427Ilefs*5
- Canonical SPDI
- NC_000015.10:72346579:GATA:GATAGATA
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Functional
consequence HelpThe effect of the variant on RNA or protein function, based on experimental evidence from submitters.
- -
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Global minor allele
frequency (GMAF) HelpThe global minor allele frequency calculated by the 1000 Genomes Project. The minor allele at this location is indicated in parentheses and may be different from the allele represented by this VCV record.
- -
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Allele frequency
Help
The frequency of the allele represented by this VCV record.
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The Genome Aggregation Database (gnomAD) 0.00046
Trans-Omics for Precision Medicine (TOPMed) 0.00058
Exome Aggregation Consortium (ExAC) 0.00064
The Genome Aggregation Database (gnomAD), exomes 0.00080
NHLBI Exome Sequencing Project (ESP) Exome Variant Server 0.00104
- Links
Genes
Gene | OMIM | ClinGen Gene Dosage Sensitivity Curation |
Variation Viewer
Help
Links to Variation Viewer, a genome browser to view variation data from NCBI databases. |
Related variants | ||
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HI score
Help
The haploinsufficiency score for the gene, curated by ClinGen’s Dosage Sensitivity Curation task team. |
TS score
Help
The triplosensitivity score for the gene, curated by ClinGen’s Dosage Sensitivity Curation task team. |
Within gene
Help
The number of variants in ClinVar that are contained within this gene, with a link to view the list of variants. |
All
Help
The number of variants in ClinVar for this gene, including smaller variants within the gene and larger CNVs that overlap or fully contain the gene. |
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HEXA | - | - |
GRCh38 GRCh37 |
1141 | 1175 |
Conditions - Germline
Condition
Help
The condition for this variant-condition (RCV) record in ClinVar. |
Classification
Help
The aggregate germline classification for this variant-condition (RCV) record in ClinVar. The number of submissions that contribute to this aggregate classification is shown in parentheses. (# of submissions) |
Review status
Help
The aggregate review status for this variant-condition (RCV) record in ClinVar. This value is calculated by NCBI based on data from submitters. Read our rules for calculating the review status. |
Last evaluated
Help
The most recent date that a submitter evaluated this variant for the condition. |
Variation/condition record
Help
The RCV accession number, with most recent version number, for the variant-condition record, with a link to the RCV web page. |
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Pathogenic (23) |
criteria provided, multiple submitters, no conflicts
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Jan 28, 2024 | RCV000004093.115 | |
Pathogenic (7) |
criteria provided, multiple submitters, no conflicts
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Aug 20, 2024 | RCV000224443.38 | |
Pathogenic (1) |
criteria provided, single submitter
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Dec 27, 2021 | RCV000623223.10 | |
Uncertain significance (1) |
no assertion criteria provided
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Jan 1, 2019 | RCV001252517.8 | |
Pathogenic (1) |
criteria provided, single submitter
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- | RCV001250227.7 | |
HEXA-related disorder
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Pathogenic (1) |
no assertion criteria provided
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Jul 16, 2024 | RCV004755708.1 |
Submissions - Germline
Classification
Help
The submitted germline classification for each SCV record. (Last evaluated) |
Review status
Help
Stars represent the review status, or the level of review supporting the submitted (SCV) record. This value is calculated by NCBI based on data from the submitter. Read our rules for calculating the review status. This column also includes a link to the submitter’s assertion criteria if provided, and the collection method. (Assertion criteria) |
Condition
Help
The condition for the classification, provided by the submitter for this submitted (SCV) record. This column also includes the affected status and allele origin of individuals observed with this variant. |
Submitter
Help
The submitting organization for this submitted (SCV) record. This column also includes the SCV accession and version number, the date this SCV first appeared in ClinVar, and the date that this SCV was last updated in ClinVar. |
More information
Help
This column includes more information supporting the classification, including citations, the comment on classification, and detailed evidence provided as observations of the variant by the submitter. |
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Pathogenic
(Aug 15, 2014)
|
criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
Affected status: yes
Allele origin:
germline
|
Genetic Services Laboratory, University of Chicago
Accession: SCV000247559.1
First in ClinVar: Oct 05, 2015 Last updated: Oct 05, 2015 |
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Pathogenic
(Jun 04, 2015)
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criteria provided, single submitter
Method: clinical testing
|
not provided
Affected status: not provided
Allele origin:
germline
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Center for Pediatric Genomic Medicine, Children's Mercy Hospital and Clinics
Accession: SCV000281445.1
First in ClinVar: Jun 09, 2016 Last updated: Jun 09, 2016 |
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Pathogenic
(Sep 26, 2015)
|
criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: no
Allele origin:
germline
|
Knight Diagnostic Laboratories, Oregon Health and Sciences University
Study: CSER-NextGen
Accession: SCV000538041.1 First in ClinVar: Apr 03, 2017 Last updated: Apr 03, 2017 |
Comment:
The c.1274_1277dupTATC, (p.Tyr427Ilefs*5) is a known frameshift variant that has been shown to result in the absence of mRNA. To that effect, the majority of … (more)
The c.1274_1277dupTATC, (p.Tyr427Ilefs*5) is a known frameshift variant that has been shown to result in the absence of mRNA. To that effect, the majority of pathogenic variants in the Ashkenazi Jewish TSD are null alleles, making it a common mechanism of disease. Moreover, this 4 basepair insertion variant has been reported in the majority of affected individuals of Ashkenazi Jewish ancestry (Myerowitz and Costigan, 1988), and has not been seen in the normal population databases (1000 Genomes, ExAc, and Exome Sequencing Project [ESP]). In summary, this variant is best classified as a recessive pathogenic variant for Tay-Sachs disease. (less)
|
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Pathogenic
(Jul 10, 2014)
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criteria provided, single submitter
Method: research
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Tay-Sachs disease
Affected status: yes
Allele origin:
unknown,
paternal
|
HudsonAlpha Institute for Biotechnology, HudsonAlpha Institute for Biotechnology
Study: CSER-HudsonAlpha
Accession: SCV000584094.1 First in ClinVar: Jul 08, 2017 Last updated: Jul 08, 2017 |
Observation 1:
Number of individuals with the variant: 1
Observation 2:
Number of individuals with the variant: 1
Observation 3:
Number of individuals with the variant: 1
|
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Pathogenic
(Aug 21, 2017)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
germline
|
Women's Health and Genetics/Laboratory Corporation of America, LabCorp
Accession: SCV000697162.1
First in ClinVar: Dec 26, 2017 Last updated: Dec 26, 2017 |
Comment:
Variant summary: This c.1274_1277dupTATC (p.Tyr427Ilefs) results in a premature termination codon, predicted to cause a truncated or absent HEXA protein due to nonsense mediated decay, … (more)
Variant summary: This c.1274_1277dupTATC (p.Tyr427Ilefs) results in a premature termination codon, predicted to cause a truncated or absent HEXA protein due to nonsense mediated decay, which are commonly known mechanisms for disease. One functional study found less than 5% b-Hexosaminidase activity in leukocytes from a patient with Tay-Sachs disease carrying this variant in compound heterozygosity with p.R510H (not in our internal database)(Udwadia-Hedge_2017). This variant was found in the large control database ExAC in 92/121426 control chromosomes at a frequency of 0.0007577, which does not exceed the maximal expected frequency of a pathogenic allele (0.0013975) in this gene. This variant has been reported as a common pathogenic variant found especially in Ashkenazi Jews population with consistent clinical and genetic data (Myerowitz_1988, Jamali_2014, Zampieri_2012). Multiple clinical labs as well as reputable databases have classified this variant as pathogenic. Taken together, this variant has been classified as pathogenic. (less)
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Pathogenic
(Apr 13, 2015)
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criteria provided, single submitter
Method: clinical testing
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not provided
Affected status: unknown
Allele origin:
germline
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Eurofins Ntd Llc (ga)
Accession: SCV000225230.4
First in ClinVar: Jun 28, 2015 Last updated: Jul 31, 2019 |
Number of individuals with the variant: 7
Sex: mixed
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Pathogenic
(May 18, 2017)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
(Autosomal recessive inheritance)
Affected status: not provided
Allele origin:
germline
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Laboratory for Molecular Medicine, Mass General Brigham Personalized Medicine
Accession: SCV000712205.1
First in ClinVar: Apr 09, 2018 Last updated: Apr 09, 2018 |
Comment:
The p.Tyr427IlefsX5 (NM_000520.4 c.1274_1277dupTATC) variant in HEXA is a common pathogenic variant that has been reported in many compound heterozygous and hom ozygous individuals with … (more)
The p.Tyr427IlefsX5 (NM_000520.4 c.1274_1277dupTATC) variant in HEXA is a common pathogenic variant that has been reported in many compound heterozygous and hom ozygous individuals with Tay-Sachs disease (Myerowitz 1988, Montalvo 2005, Scott 2010, Gort 2012, Zampieri 2012, Jamail 2014). It has been reported in ClinVar ( Variation ID#3889) as pathogenic by multiple laboratories. This variant has been identified in 1.3% (135/10152) of Ashkenazi Jewish chromosomes and 0.03% (48/12 6682) of European chromosomes by the Genome Aggregation Database (gnomAD, http:/ /gnomad.broadinstitute.org; dbSNP rs387906309). Although this variant has been s een in the general population, its frequency is low enough to be consistent with a recessive carrier frequency. This variant is predicted to cause a frameshift, which alters the protein?s amino acid sequence beginning at position 427 and le ads to a premature termination codon 5 amino acids downstream. This alteration i s then predicted to lead to a truncated or absent protein. Biallelic loss of fun ction in the HEXA gene is an established disease mechanism for Tay-Sachs disease . In summary, this variant meets criteria to be classified as pathogenic for Ta y-Sachs disease in an autosomal recessive manner based upon a predicted null eff ect and its biallelic occurrence in individuals with this disease. (less)
Number of individuals with the variant: 1
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Pathogenic
(Oct 18, 2019)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
unknown
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Myriad Genetics, Inc.
Accession: SCV001193865.2
First in ClinVar: Apr 06, 2020 Last updated: Jul 06, 2020 |
Comment:
NM_000520.4(HEXA):c.1274_1277dupTATC(Y427Ifs*5) is classified as pathogenic in the context of hexosaminidase A deficiency. Please note that the Y427Ifs*5 variant is associated with Tay-Sachs disease. Sources cited … (more)
NM_000520.4(HEXA):c.1274_1277dupTATC(Y427Ifs*5) is classified as pathogenic in the context of hexosaminidase A deficiency. Please note that the Y427Ifs*5 variant is associated with Tay-Sachs disease. Sources cited for classification include the following: PMID 2848800, 1307230, 1830584, 11463833, and 14727180. Classification of NM_000520.4(HEXA):c.1274_1277dupTATC(Y427Ifs*5) is based on the following criteria: The variant causes a premature termination codon that is expected to be targeted by nonsense-mediated mRNA decay and is reported in individuals with the relevant phenotype. Please note: this variant was assessed in the context of healthy population screening. (less)
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Pathogenic
(Jun 07, 2021)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
inherited
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New York Genome Center
Study: CSER-NYCKidSeq
Accession: SCV002506704.1 First in ClinVar: May 16, 2022 Last updated: May 16, 2022 |
Clinical Features:
Seizure (present)
Secondary finding: no
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Pathogenic
(May 30, 2022)
|
criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: no
Allele origin:
unknown
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Institute of Human Genetics, University Hospital Muenster
Accession: SCV002526129.1
First in ClinVar: Jun 18, 2022 Last updated: Jun 18, 2022 |
Comment:
ACMG categories: PVS1,PS4,PP5,BS1
Number of individuals with the variant: 1
Age: 20-29 years
Sex: female
Tissue: blood
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Pathogenic
(Aug 22, 2022)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
maternal
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Daryl Scott Lab, Baylor College of Medicine
Accession: SCV002567942.1
First in ClinVar: Aug 29, 2022 Last updated: Aug 29, 2022 |
Number of individuals with the variant: 1
|
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Pathogenic
(Dec 03, 2021)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: yes
Allele origin:
germline
|
MGZ Medical Genetics Center
Accession: SCV002579636.1
First in ClinVar: Oct 15, 2022 Last updated: Oct 15, 2022
Comment:
ACMG criteria applied: PVS1, PM3, PM2_SUP
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Number of individuals with the variant: 1
Sex: female
|
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Pathogenic
(Nov 18, 2021)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
germline
|
Revvity Omics, Revvity
Accession: SCV002024978.3
First in ClinVar: Nov 29, 2021 Last updated: Feb 04, 2024 |
|
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Pathogenic
(Jan 28, 2024)
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criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
germline
|
Labcorp Genetics (formerly Invitae), Labcorp
Accession: SCV000218958.11
First in ClinVar: Mar 29, 2015 Last updated: Feb 20, 2024 |
Comment:
This sequence change creates a premature translational stop signal (p.Tyr427Ilefs*5) in the HEXA gene. It is expected to result in an absent or disrupted protein … (more)
This sequence change creates a premature translational stop signal (p.Tyr427Ilefs*5) in the HEXA gene. It is expected to result in an absent or disrupted protein product. Loss-of-function variants in HEXA are known to be pathogenic (PMID: 1833974, 8490625). This variant is present in population databases (rs387906309, gnomAD 1.3%), and has an allele count higher than expected for a pathogenic variant. This premature translational stop signal has been observed in individuals with Tay-Sachs disease (PMID: 2848800, 16352452, 20301397, 24518553, 25287655). It is commonly reported in individuals of Ashkenazi Jewish ancestry (PMID: 2848800, 22975760). This variant is also known as c.1277_1278insTATC. ClinVar contains an entry for this variant (Variation ID: 3889). Algorithms developed to predict the effect of sequence changes on RNA splicing suggest that this variant may disrupt the consensus splice site. For these reasons, this variant has been classified as Pathogenic. (less)
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Pathogenic
(Nov 08, 2017)
|
criteria provided, single submitter
Method: clinical testing
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Tay-Sachs disease
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
maternal
|
Institute of Human Genetics Munich, Klinikum Rechts Der Isar, TU München
Accession: SCV000680255.1
First in ClinVar: Dec 26, 2017 Last updated: Dec 26, 2017 |
Sex: female
Tissue: blood
|
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Pathogenic
(Aug 29, 2018)
|
criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
Affected status: unknown
Allele origin:
germline
|
Illumina Laboratory Services, Illumina
Accession: SCV000914692.1
First in ClinVar: May 27, 2019 Last updated: May 27, 2019 |
Comment:
The HEXA c.1274_1277dupTATC (p.Tyr427IlefsTer5) variant results in a frameshift and is predicted to result in premature termination of the protein. Across a selection of the … (more)
The HEXA c.1274_1277dupTATC (p.Tyr427IlefsTer5) variant results in a frameshift and is predicted to result in premature termination of the protein. Across a selection of the available literature, the p.Tyr427IlefsTer5 variant has been identified in eight probands in a homozygous state, two probands in a compound heterozygous state and in five probands with unknown zygosity (Myerowitz et al. 1988; McDowell et al. 1992; Jamali et al. 2014; Sheth et al. 2014). The c.1274_1277dupTATC (p.Tyr427IlefsTer5) the most common HEXA variant in the Ashkenazi Jewish population and accounts for approximately 80% of variant HEXA alleles in this population (Kaback et al. 2011). Segregation of the variant with the disease has been shown in at least two families (Myerowitz et al. 1988). The variant was found in 69 of 2238 controls in a heterozygous state and is reported at a frequency of 0.00157 in the European American population of the Exome Sequencing Project. Due to the potential impact of frameshift variants, the p.Tyr427IlefsTer5 variant is classified as pathogenic for hexosaminidase A deficiency. This variant was observed by ICSL as part of a predisposition screen in an ostensibly healthy population. (less)
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Pathogenic
(-)
|
criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
Tay-Sachs disease, variant AB
Affected status: yes
Allele origin:
germline
|
Centogene AG - the Rare Disease Company
Accession: SCV001424435.1
First in ClinVar: Jul 27, 2020 Last updated: Jul 27, 2020 |
|
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Pathogenic
(Mar 31, 2022)
|
criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
(Autosomal recessive inheritance)
Affected status: unknown
Allele origin:
germline
|
Victorian Clinical Genetics Services, Murdoch Childrens Research Institute
Additional submitter:
Shariant Australia, Australian Genomics
Accession: SCV002768489.1
First in ClinVar: Dec 24, 2022 Last updated: Dec 24, 2022 |
Comment:
Based on the classification scheme VCGS_Germline_v1.3.4, this variant is classified as Pathogenic. Following criteria are met: 0102 - Loss of function is a known mechanism … (more)
Based on the classification scheme VCGS_Germline_v1.3.4, this variant is classified as Pathogenic. Following criteria are met: 0102 - Loss of function is a known mechanism of disease in this gene and is associated with Tay-Sachs disease (MIM#272800). (I) 0106 - This gene is associated with autosomal recessive disease. (I) 0201 - Variant is predicted to cause nonsense-mediated decay (NMD) and loss of protein (premature termination codon is located at least 54 nucleotides upstream of the final exon-exon junction). (SP) 0251 - This variant is heterozygous. (I) 0305 - Variant is present in gnomAD (v2) >=0.01 and <0.03 for a recessive condition (210 heterozygotes, 0 homozygotes). (I) 0701 - Other NMD-predicted variants comparable to the one identified in this case have very strong previous evidence for pathogenicity. These variants have been reported many times as pathogenic (DECIPHER). (SP) 0801 - This variant has strong previous evidence of pathogenicity in unrelated individuals. It is one of the most common variants to cause Tay-Sachs disease in the Ashkenazi Jewish population (ClinVar). (SP) 1208 - Inheritance information for this variant is not currently available in this individual. (I) Legend: (SP) - Supporting pathogenic, (I) - Information, (SB) - Supporting benign (less)
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Pathogenic
(May 27, 2022)
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criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
Affected status: unknown
Allele origin:
unknown
|
Baylor Genetics
Accession: SCV000328765.2
First in ClinVar: Jan 31, 2016 Last updated: Mar 11, 2023 |
|
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Pathogenic
(Mar 29, 2023)
|
criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
Affected status: yes
Allele origin:
germline
|
Institute of Human Genetics, Clinical Exome/Genome Diagnostics Group, University Hospital Bonn
Accession: SCV004032467.1
First in ClinVar: Sep 09, 2023 Last updated: Sep 09, 2023 |
|
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Pathogenic
(Jan 02, 2024)
|
criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
unknown
|
Institute of Human Genetics, University of Leipzig Medical Center
Accession: SCV004242410.1
First in ClinVar: Feb 14, 2024 Last updated: Feb 14, 2024 |
Comment:
Criteria applied: PVS1,PM3_VSTR,PM2_SUP
Clinical Features:
Obesity (present) , Dysphagia (present) , Movement disorder (present) , Poor head control (present) , Developmental regression (present) , Short stature (present) , Hypotonia (present) … (more)
Obesity (present) , Dysphagia (present) , Movement disorder (present) , Poor head control (present) , Developmental regression (present) , Short stature (present) , Hypotonia (present) , Multifocal seizures (present) , Severe global developmental delay (present) (less)
Sex: male
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Pathogenic
(Dec 27, 2021)
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criteria provided, single submitter
Method: clinical testing
|
Inborn genetic diseases
Affected status: unknown
Allele origin:
germline
|
Ambry Genetics
Accession: SCV000743019.5
First in ClinVar: Apr 15, 2018 Last updated: May 01, 2024 |
Comment:
The c.1274_1277dupTATC (p.Y427Ifs*5) alteration, located in coding exon 11 of the HEXA gene, consists of a duplication of TATC at position 1274, causing a translational … (more)
The c.1274_1277dupTATC (p.Y427Ifs*5) alteration, located in coding exon 11 of the HEXA gene, consists of a duplication of TATC at position 1274, causing a translational frameshift with a predicted alternate stop codon after 5 amino acids. This alteration is expected to result in loss of function by premature protein truncation or nonsense-mediated mRNA decay. Based on data from gnomAD, this allele has an overall frequency of 0.07% (210/282850) total alleles studied. The highest observed frequency was 1.29% (134/10370) of Ashkenazi Jewish alleles. This mutation is the most common Tay-Sachs disease alteration found in the Ashkenazi Jewish population (Myerowitz, 1988) and has been shown to account for approximately 80% of all mutant HEXA Ashkenazi Jewish alleles (Kaback, 1993; Scott, 2010). Based on the available evidence, this alteration is classified as pathogenic. (less)
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Pathogenic
(Aug 20, 2024)
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criteria provided, single submitter
Method: clinical testing
|
Not Provided
Affected status: yes
Allele origin:
germline
|
GeneDx
Accession: SCV000565056.6
First in ClinVar: Jun 09, 2016 Last updated: Sep 16, 2024 |
Comment:
Common pathogenic variant in the HEXA gene found in the Ashkenazi Jewish population and associated with infantile onset Tay-Sachs disease (PMID: 20301397); Frameshift variant predicted … (more)
Common pathogenic variant in the HEXA gene found in the Ashkenazi Jewish population and associated with infantile onset Tay-Sachs disease (PMID: 20301397); Frameshift variant predicted to result in protein truncation or nonsense mediated decay in a gene for which loss of function is a known mechanism of disease; This variant is associated with the following publications: (PMID: 8352284, 2848800, 30609409, 22975760, 25287655, 14727180, 8488832, 1830584, 2294750, 27033294, 1307230, 28503624, 21228398, 27959697, 29352662, 28333917, 30548430, 31076878, 31980526, 33083013, 33240792, 1387685, 37267771, 35586607, 35848209, 34554397, 33831955, 20301397) (less)
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Pathogenic
(May 20, 2023)
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criteria provided, single submitter
Method: clinical testing
|
Tay-Sachs disease
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
germline
|
Neuberg Centre For Genomic Medicine, NCGM
Accession: SCV005042632.2
First in ClinVar: May 12, 2024 Last updated: Oct 08, 2024 |
Comment:
The frameshift c.1274_1277dup (p.Tyr427IlefsTer5) variant in the HEXA gene has been observed in individuals with Tay-Sachs disease (Vallance, Hilary et al.,2006). This variant is also … (more)
The frameshift c.1274_1277dup (p.Tyr427IlefsTer5) variant in the HEXA gene has been observed in individuals with Tay-Sachs disease (Vallance, Hilary et al.,2006). This variant is also known as c.1277_1278insTATC. It is commonly reported in individuals of Ashkenazi Jewish ancestry (Lazarin, Gabriel A et al.,2013). The p.Tyr427IlefsTer5 variant has been reported with allele frequency of 0.07% in gnomAD Exomes. This variant has been reported to the ClinVar database as Pathogenic (multiple submissions). This variant causes a frameshift starting with codon Tyrosine 427, changes this amino acid to Isoleucine residue, and creates a premature Stop codon at position 5 of the new reading frame, denoted p.Tyr427IlefsTer5. This variant is predicted to cause loss of normal protein function through protein truncation. Loss of function variants have been previously reported to be disease causing. For these reasons, this variant has been classified as Pathogenic. Enzyme analysis is recommended. (less)
Clinical Features:
Abnormality of metabolism/homeostasis (present)
|
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Pathogenic
(Aug 01, 2024)
|
criteria provided, single submitter
Method: clinical testing
|
not provided
Affected status: yes
Allele origin:
germline
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CeGaT Center for Human Genetics Tuebingen
Accession: SCV001747734.20
First in ClinVar: Jul 10, 2021 Last updated: Oct 20, 2024 |
Comment:
HEXA: PVS1, PM2, PM3
Number of individuals with the variant: 3
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Pathogenic
(Jan 31, 2024)
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criteria provided, single submitter
Method: clinical testing
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Not provided
Affected status: unknown
Allele origin:
germline
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Mayo Clinic Laboratories, Mayo Clinic
Accession: SCV005414291.1
First in ClinVar: Nov 24, 2024 Last updated: Nov 24, 2024 |
Number of individuals with the variant: 3
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Pathogenic
(Sep 11, 2014)
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no assertion criteria provided
Method: research
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Tay-Sachs disease
(Autosomal recessive inheritance)
Affected status: yes
Allele origin:
germline
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Foundation for Research in Genetics and Endocrinology, FRIGE's Institute of Human Genetics
Accession: SCV000494223.1
First in ClinVar: Jan 31, 2016 Last updated: Jan 31, 2016 |
Clinical Features:
Developmental regression (present) , Cherry red spot of the macula (present) , Muscular hypotonia (present) , Seizures (present) , Hyperacusis (present) , Hepatomegaly (present) , … (more)
Developmental regression (present) , Cherry red spot of the macula (present) , Muscular hypotonia (present) , Seizures (present) , Hyperacusis (present) , Hepatomegaly (present) , EEG abnormality (present) , Abnormal thalamic MRI signal intensity (present) (less)
Age: 0-9 years
Sex: male
Ethnicity/Population group: Indian
Geographic origin: India
Tissue: Blood
Method: Polymerase Chain Reaction followed by bi-directional Sanger sequencing was performed covering all exons and exon-intron boundaries of the HEXA gene.
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Uncertain significance
(Jan 01, 2019)
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no assertion criteria provided
Method: clinical testing
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Intellectual disability
Affected status: yes
Allele origin:
unknown
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Centre de Biologie Pathologie Génétique, Centre Hospitalier Universitaire de Lille
Accession: SCV001428274.1
First in ClinVar: Aug 17, 2020 Last updated: Aug 17, 2020 |
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Affects
(Mar 01, 2004)
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no assertion criteria provided
Method: literature only
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TAY-SACHS DISEASE
Affected status: not provided
Allele origin:
germline
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OMIM
Accession: SCV000024259.67
First in ClinVar: Apr 04, 2013 Last updated: May 01, 2024 |
Comment on evidence:
Myerowitz and Costigan (1988) demonstrated that the most frequent DNA lesion in Tay-Sachs disease (272800) of Ashkenazi Jews is a homozygous 4-bp insertion in exon … (more)
Myerowitz and Costigan (1988) demonstrated that the most frequent DNA lesion in Tay-Sachs disease (272800) of Ashkenazi Jews is a homozygous 4-bp insertion in exon 11. This mutation introduces a premature termination signal in exon 11, resulting in a deficiency of mRNA. Using a dot-blot assay to screen patients and heterozygous carriers for the insertion mutation, Myerowitz and Costigan (1988) found the lesion in about 70% of carriers tested, thus identifying it as the most frequent defect underlying Tay-Sachs disease in the Ashkenazi Jewish population. Triggs-Raine and Gravel (1990) showed that this insertion mutation of only 4 bp can be detected by the formation of heteroduplexes. This mutation causes a frameshift and a termination codon 9 nucleotides downstream. By site-directed mutagenesis, Nishimoto et al. (1991) examined the basis of the paradox that the mutant gene with the 4-base insertion in exon 11 is transcribed normally but the mRNA is essentially undetectable. They found no evidence of interference with normal splicing of the transcript and the mutation did not destabilize properly spliced mRNA. Thus, the studies left open the question of the mechanism of the mutation. The possibility was mentioned that another still unidentified abnormality in the same allele may be responsible for the nearly complete absence of mRNA. There appears to be an increased frequency of TSD in the Cajun population of southwest Louisiana which numbers less than one million persons. McDowell et al. (1992) reported that in the previous 3 decades, at least 8 infants from 6 apparently unrelated Cajun families had been identified. They found that the mutation in 11 of 12 of the TSD alleles in these 6 families was the exon 11 insertion present in approximately 70% of Ashkenazi Jewish TSD heterozygotes. The remaining allele was a single-base transition in the donor splice site of intron 9 (606869.0033). To trace the origins of these 2 mutations in the Cajun population, the TSD carrier status was determined enzymatically in 90 members of 4 of the 6 families, and extensive pedigrees were constructed for all carriers. A single ancestral couple from France was found to be common to most of the carriers of the exon 11 insertion. Pedigree data suggested that this mutation has been in the Cajun population since its founding and that it may be widely distributed within the population. In contrast, the intron 9 mutation was apparently introduced later and is probably limited to a few Louisiana families. Zlotogora (1993) argued that 2 mutations would not be unexpected in the Cajun population. Thurmon (1993) gave a historical account of the 'Jews of Acadiana.' He indicated that the Jews were assimilated into the Acadian culture and suggested that this was the source of the Tay-Sachs genes. He also pointed out that about the same time Jewish merchants began to arrive in Acadiana, the French Revolution produced an influx of non-Acadian French immigrants. Many were of aristocratic lineage and held themselves aloof from the Acadians. This mutation is alternatively designated 1277TATC or 1278insTATC. See 606869.0054. To investigate the genetic history of the 1278insTATC mutation, the most frequent cause of Tay-Sachs disease in Ashkenazi Jews, Frisch et al. (2004) identified a conserved haplotype in 1278insTATC chromosomes for 55 unrelated Ashkenazi Jewish individuals (15 homozygotes and 40 heterozygotes for the TSD mutation), suggesting the occurrence of a common founder. When 2 methods were used for analysis of linkage disequilibrium (LD) between flanking polymorphic markers and the disease locus and for study of the decay of LD over time, the estimated age of the insertion was found to be 40 +/- 12 generations (95% confidence interval, 30 to 50 generations), so that the most recent common ancestor of the mutation-bearing chromosomes would date to the 8th or 9th century. This corresponds with the demographic expansion of Ashkenazi Jews in central Europe, following the founding of the Ashkenazi settlement in the early Middle Ages. The results were also consistent with the geographic distribution of the mutation and with the coalescent times of mutations causing 2 other lysosomal storage diseases frequent in Ashkenazi Jews: Gaucher disease (230800) and mucolipidosis IV (252650). Evidence for the absence of a heterozygote advantage of the mutation was provided by comparison between the estimated age of 1278insTATC and the probability of the current Ashkenazi Jewish frequency of the mutant allele as a function of its age, calculated by use of a branching-process model. Therefore, the founder effect in a rapidly expanding population arising from a bottleneck provides a robust and parsimonious hypothesis explaining the spread of 1278insTATC-related TSD in Ashkenazi Jewish individuals. (less)
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Likely pathogenic
(-)
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no assertion criteria provided
Method: clinical testing
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not provided
Affected status: yes
Allele origin:
germline
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Laboratory of Diagnostic Genome Analysis, Leiden University Medical Center (LUMC)
Study: VKGL Data-share Consensus
Accession: SCV001798857.1 First in ClinVar: Aug 21, 2021 Last updated: Aug 21, 2021 |
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Pathogenic
(-)
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no assertion criteria provided
Method: clinical testing
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not provided
Affected status: yes
Allele origin:
germline
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Clinical Genetics DNA and cytogenetics Diagnostics Lab, Erasmus MC, Erasmus Medical Center
Additional submitter:
Diagnostic Laboratory, Department of Genetics, University Medical Center Groningen
Study: VKGL Data-share Consensus
Accession: SCV001973862.1 First in ClinVar: Oct 07, 2021 Last updated: Oct 07, 2021 |
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Pathogenic
(Mar 17, 2017)
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no assertion criteria provided
Method: clinical testing
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Tay-Sachs disease
Affected status: unknown
Allele origin:
germline
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Natera, Inc.
Accession: SCV002085670.1
First in ClinVar: Apr 23, 2022 Last updated: Apr 23, 2022 |
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Pathogenic
(Jul 16, 2024)
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no assertion criteria provided
Method: clinical testing
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HEXA-related condition
Affected status: unknown
Allele origin:
germline
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PreventionGenetics, part of Exact Sciences
Accession: SCV005346811.1
First in ClinVar: Oct 08, 2024 Last updated: Oct 08, 2024 |
Comment:
The HEXA c.1274_1277dupTATC variant is predicted to result in a frameshift and premature protein termination (p.Tyr427Ilefs*5). This is among the most common pathogenic variants in … (more)
The HEXA c.1274_1277dupTATC variant is predicted to result in a frameshift and premature protein termination (p.Tyr427Ilefs*5). This is among the most common pathogenic variants in HEXA and is responsible for up to 80% of documented cases of Tay-Sachs Disease in the Ashkenzi Jewish population (Myerowitz et al. 1988. PubMed ID: 2848800; Kaback et al. 1993. PubMed ID: 20301397). This variant is interpreted as pathogenic. (less)
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Pathogenic
(Jan 06, 2020)
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no assertion criteria provided
Method: curation
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Tay-Sachs disease
Affected status: unknown
Allele origin:
germline
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Reproductive Health Research and Development, BGI Genomics
Accession: SCV001142451.1
First in ClinVar: Jan 12, 2020 Last updated: Jan 12, 2020 |
Comment:
NM_000520.4:c.1274_1277dupTATC in the HEXA gene has an allele frequency of 0.013 in Ashkenazi Jewish subpopulation in the gnomAD database. This variant is located at the … (more)
NM_000520.4:c.1274_1277dupTATC in the HEXA gene has an allele frequency of 0.013 in Ashkenazi Jewish subpopulation in the gnomAD database. This variant is located at the 11th exon (14 exons in the NM_000520.4 transcript), therefore, it is predicted to lead nonsense-mediated mRNA decay. The c.1274_1277dupTATC (p.Tyr427Ilefs*5) variant has been reported multiple times and is determiend as the most common disease-causing variant in the Ashkenazi Jewis (PMID: 20672374). Taken together, we interprete this variant as Pathogenic/Likely pathogenic. ACMG/AMP criteria applied: PVS1; PS4; PP4 (less)
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Germline Functional Evidence
There is no functional evidence in ClinVar for this variation. If you have generated functional data for this variation, please consider submitting that data to ClinVar. |
Citations for germline classification of this variant
HelpTitle | Author | Journal | Year | Link |
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Exome sequencing efficacy and phenotypic expansions involving esophageal atresia/tracheoesophageal fistula plus. | Sy MR | American journal of medical genetics. Part A | 2022 | PMID: 36135330 |
HEXA Disorders. | Adam MP | - | 2020 | PMID: 20301397 |
Temporary Efficacy of Pyrimethamine in Juvenile-Onset Tay-Sachs Disease Caused by 2 Unreported HEXA Mutations in the Indian Population. | Udwadia-Hegde A | Child neurology open | 2017 | PMID: 28503624 |
Resolution of Disease Phenotypes Resulting from Multilocus Genomic Variation. | Posey JE | The New England journal of medicine | 2017 | PMID: 27959697 |
Cerebellar atrophy and muscle weakness: late-onset Tay-Sachs disease outside Jewish populations. | Steiner KM | BMJ case reports | 2016 | PMID: 27033294 |
Standards and guidelines for the interpretation of sequence variants: a joint consensus recommendation of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology. | Richards S | Genetics in medicine : official journal of the American College of Medical Genetics | 2015 | PMID: 25741868 |
Biomarkers of central nervous system inflammation in infantile and juvenile gangliosidoses. | Utz JR | Molecular genetics and metabolism | 2015 | PMID: 25557439 |
Prader-Willi syndrome and Tay-Sachs disease in association with mixed maternal uniparental isodisomy and heterodisomy 15 in a girl who also had isochromosome Xq. | Zeesman S | American journal of medical genetics. Part A | 2015 | PMID: 25287655 |
Expanding the spectrum of HEXA mutations in Indian patients with Tay-Sachs disease. | Sheth J | Molecular genetics and metabolism reports | 2014 | PMID: 27896118 |
Molecular study of lysosomal storage disorders in India. | Sheth J | Molecular cytogenetics | 2014 | PMID: 24940364 |
Three novel mutations in Iranian patients with Tay-Sachs disease. | Jamali S | Iranian biomedical journal | 2014 | PMID: 24518553 |
Validation for clinical use of, and initial clinical experience with, a novel approach to population-based carrier screening using high-throughput, next-generation DNA sequencing. | Hallam S | The Journal of molecular diagnostics : JMD | 2014 | PMID: 24374108 |
Burden of lysosomal storage disorders in India: experience of 387 affected children from a single diagnostic facility. | Sheth J | JIMD reports | 2014 | PMID: 23852624 |
An empirical estimate of carrier frequencies for 400+ causal Mendelian variants: results from an ethnically diverse clinical sample of 23,453 individuals. | Lazarin GA | Genetics in medicine : official journal of the American College of Medical Genetics | 2013 | PMID: 22975760 |
GM2 gangliosidoses in Spain: analysis of the HEXA and HEXB genes in 34 Tay-Sachs and 14 Sandhoff patients. | Gort L | Gene | 2012 | PMID: 22789865 |
Identification of novel mutations in HEXA gene in children affected with Tay Sachs disease from India. | Mistri M | PloS one | 2012 | PMID: 22723944 |
Molecular analysis of HEXA gene in Argentinean patients affected with Tay-Sachs disease: possible common origin of the prevalent c.459+5A>G mutation. | Zampieri S | Gene | 2012 | PMID: 22441121 |
Carrier testing for severe childhood recessive diseases by next-generation sequencing. | Bell CJ | Science translational medicine | 2011 | PMID: 21228398 |
Experience with carrier screening and prenatal diagnosis for 16 Ashkenazi Jewish genetic diseases. | Scott SA | Human mutation | 2010 | PMID: 20672374 |
Common HEXB polymorphisms reduce serum HexA and HexB enzymatic activities, potentially masking Tay-Sachs disease carrier identification. | Vallance H | Molecular genetics and metabolism | 2006 | PMID: 16352452 |
Molecular analysis of the HEXA gene in Italian patients with infantile and late onset Tay-Sachs disease: detection of fourteen novel alleles. | Montalvo AL | Human mutation | 2005 | PMID: 16088929 |
Origin and spread of the 1278insTATC mutation causing Tay-Sachs disease in Ashkenazi Jews: genetic drift as a robust and parsimonious hypothesis. | Frisch A | Human genetics | 2004 | PMID: 14727180 |
Nonsense-mediated decay of human HEXA mRNA. | Rajavel KS | Molecular and cellular biology | 2001 | PMID: 11463833 |
Biochemical consequences of mutations causing the GM2 gangliosidoses. | Mahuran DJ | Biochimica et biophysica acta | 1999 | PMID: 10571007 |
Ten novel mutations in the HEXA gene in non-Jewish Tay-Sachs patients. | Akli S | Human molecular genetics | 1993 | PMID: 8490625 |
Is the presence of two different Tay-Sachs disease mutations in a Cajun population an unexpected observation? | Zlotogora J | American journal of human genetics | 1993 | PMID: 8488832 |
Tay-Sachs genes in Acadians. | Thurmon TF | American journal of human genetics | 1993 | PMID: 8352284 |
Tay-Sachs disease--carrier screening, prenatal diagnosis, and the molecular era. An international perspective, 1970 to 1993. The International TSD Data Collection Network. | Kaback M | JAMA | 1993 | PMID: 8230592 |
The presence of two different infantile Tay-Sachs disease mutations in a Cajun population. | McDowell GA | American journal of human genetics | 1992 | PMID: 1307230 |
A mutation common in non-Jewish Tay-Sachs disease: frequency and RNA studies. | Akerman BR | Human mutation | 1992 | PMID: 1301938 |
Sequence of DNA flanking the exons of the HEXA gene, and identification of mutations in Tay-Sachs disease. | Triggs-Raine BL | American journal of human genetics | 1991 | PMID: 1833974 |
Expression of the beta-hexosaminidase alpha subunit gene with the four-base insertion of infantile Jewish Tay-Sachs disease. | Nishimoto J | The Journal of biological chemistry | 1991 | PMID: 1830584 |
Diagnostic heteroduplexes: simple detection of carriers of a 4-bp insertion mutation in Tay-Sachs disease. | Triggs-Raine BL | American journal of human genetics | 1990 | PMID: 2294750 |
The major defect in Ashkenazi Jews with Tay-Sachs disease is an insertion in the gene for the alpha-chain of beta-hexosaminidase. | Myerowitz R | The Journal of biological chemistry | 1988 | PMID: 2848800 |
A deletion involving Alu sequences in the beta-hexosaminidase alpha-chain gene of French Canadians with Tay-Sachs disease. | Myerowitz R | The Journal of biological chemistry | 1987 | PMID: 2824459 |
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Text-mined citations for rs387906309 ...
HelpRecord last updated Nov 25, 2024
This date represents the last time this VCV record was updated. The update may be due to an update to one of the included submitted records (SCVs), or due to an update that ClinVar made to the variant such as adding HGVS expressions or a rs number. So this date may be different from the date of the “most recent submission” reported at the top of this page.