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NM_001276345.2(TNNT2):c.508GAG[3] (p.Glu173del) AND not provided

Germline classification:
Pathogenic/Likely pathogenic (8 submissions)
Last evaluated:
Jul 13, 2022
Review status:
2 stars out of maximum of 4 stars
criteria provided, multiple submitters, no conflicts
Somatic classification
of clinical impact:
None
Review status:
(0/4) 0 stars out of maximum of 4 stars
no assertion criteria provided
Somatic classification
of oncogenicity:
None
Review status:
(0/4) 0 stars out of maximum of 4 stars
no assertion criteria provided
Record status:
current
Accession:
RCV000624557.13

Allele description [Variation Report for NM_001276345.2(TNNT2):c.508GAG[3] (p.Glu173del)]

NM_001276345.2(TNNT2):c.508GAG[3] (p.Glu173del)

Gene:
TNNT2:troponin T2, cardiac type [Gene - OMIM - HGNC]
Variant type:
Microsatellite
Cytogenetic location:
1q32.1
Genomic location:
Preferred name:
NM_001276345.2(TNNT2):c.508GAG[3] (p.Glu173del)
HGVS:
  • NC_000001.10:g.201332505_201332507del
  • NC_000001.11:g.201363377CTC[3]
  • NG_007556.1:g.19290GAG[3]
  • NM_000364.4:c.508GAG[3]
  • NM_001001430.3:c.478GAG[3]
  • NM_001001431.3:c.478GAG[3]
  • NM_001001432.3:c.463GAG[3]
  • NM_001276345.2:c.508GAG[3]MANE SELECT
  • NM_001276346.2:c.388GAG[3]
  • NM_001276347.2:c.478GAG[3]
  • NP_000355.2:p.Glu173del
  • NP_001001430.1:p.Glu163del
  • NP_001001431.1:p.Glu163del
  • NP_001001432.1:p.Glu158del
  • NP_001263274.1:p.Glu173del
  • NP_001263275.1:p.Glu133del
  • NP_001263276.1:p.Glu163del
  • LRG_431t1:c.508GAG[3]
  • LRG_431:g.19290GAG[3]
  • LRG_431p1:p.Glu173del
  • NC_000001.10:g.201332505CTC[3]
  • NC_000001.10:g.201332505_201332507del
  • NC_000001.10:g.201332505_201332507delCTC
  • NC_000001.10:g.201332514_201332516del
  • NM_000364.2:c.517_519del
  • NM_000364.3:c.517_519delGAG
  • NM_001001430.1:c.487_489del
  • NM_001001430.1:c.487_489delGAG
  • NM_001001430.2:c.487_489del
  • NM_001001430.2:c.487_489delGAG
  • c.487_489delGAG
Protein change:
E133del
Links:
dbSNP: rs397516470
NCBI 1000 Genomes Browser:
rs397516470
Molecular consequence:
  • NM_000364.4:c.508GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
  • NM_001001430.3:c.478GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
  • NM_001001431.3:c.478GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
  • NM_001001432.3:c.463GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
  • NM_001276345.2:c.508GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
  • NM_001276346.2:c.388GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
  • NM_001276347.2:c.478GAG[3] - inframe_deletion - [Sequence Ontology: SO:0001822]
Observations:
1

Condition(s)

Synonyms:
none provided
Identifiers:
MedGen: C3661900

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Assertion and evidence details

Help
Submission AccessionSubmitterReview Status
(Assertion method)		Clinical Significance
(Last evaluated)		OriginMethodCitations
SCV000209278GeneDx
criteria provided, single submitter

(GeneDx Variant Classification Process June 2021)		Pathogenic
(May 16, 2022) 		germlineclinical testing

Citation Link,

SCV000740431Molecular Diagnostic Laboratory for Inherited Cardiovascular Disease, Montreal Heart Institute
criteria provided, single submitter

(ACMG Guidelines, 2015)		Pathogenic
(Nov 28, 2016) 		germlineclinical testing

PubMed (1)
[See all records that cite this PMID]

SCV000924966Stanford Center for Inherited Cardiovascular Disease, Stanford University
no assertion criteria provided
Pathogenic
(Apr 12, 2017) 		germlineprovider interpretation

SCV000927600Blueprint Genetics
criteria provided, single submitter

(Blueprint Genetics Variant Classification Scheme)		Pathogenic
(Mar 16, 2018) 		germlineclinical testing

Citation Link,

SCV001929709Genome Diagnostics Laboratory, University Medical Center Utrecht - VKGL Data-share Consensus

See additional submitters

no assertion criteria provided
Likely pathogenicgermlineclinical testing

SCV001953581Joint Genome Diagnostic Labs from Nijmegen and Maastricht, Radboudumc and MUMC+ - VKGL Data-share Consensus

See additional submitters

no assertion criteria provided
Likely pathogenicgermlineclinical testing

SCV002501176AiLife Diagnostics, AiLife Diagnostics
criteria provided, single submitter

(ACMG Guidelines, 2015)		Likely pathogenic
(May 28, 2021) 		germlineclinical testing

PubMed (13)
[See all records that cite these PMIDs]

SCV005197898Clinical Genetics Laboratory, Skane University Hospital Lund
criteria provided, single submitter

(ACMG Guidelines, 2015)		Pathogenic
(Jul 13, 2022) 		germlineclinical testing

PubMed (1)
[See all records that cite this PMID]

Help

Summary from all submissions

EthnicityOriginAffectedIndividualsFamiliesChromosomes testedNumber TestedFamily historyMethod
not providedgermlineyes1not providednot providednot providednot providedclinical testing
not providedgermlineunknownnot providednot providednot providednot providednot providedprovider interpretation

Citations

PubMed

Mutations in the genes for cardiac troponin T and alpha-tropomyosin in hypertrophic cardiomyopathy.

Watkins H, McKenna WJ, Thierfelder L, Suk HJ, Anan R, O'Donoghue A, Spirito P, Matsumori A, Moravec CS, Seidman JG, et al.

N Engl J Med. 1995 Apr 20;332(16):1058-64.

PubMed [citation]
PMID:
7898523

FRET-based analysis of the cardiac troponin T linker region reveals the structural basis of the hypertrophic cardiomyopathy-causing Δ160E mutation.

Abdullah S, Lynn ML, McConnell MT, Klass MM, Baldo AP, Schwartz SD, Tardiff JC.

J Biol Chem. 2019 Oct 4;294(40):14634-14647. doi: 10.1074/jbc.RA118.005098. Epub 2019 Aug 6.

PubMed [citation]
PMID:
31387947
PMCID:
PMC6779437
See all PubMed Citations (13)

Details of each submission

From GeneDx, SCV000209278.5

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedclinical testingnot provided

Description

Not observed at significant frequency in large population cohorts (gnomAD); Published functional studies in E. coli demonstrated p.(E163del) (reported as deltaE160) resulted in recombinant troponin with increased calcium ion sensitivity (Messer et al., 2016); Published functional studies using transgenic mice demonstrated that the del160E (c.487_489delGAG) variant leads to cellular hypertrophy and myofilament disarray as well as impairments in contraction, relaxation, and calcium handling (Moore et al., 2013; Moore et al., 2014); In silico analysis supports a deleterious effect on protein structure/function; This variant is associated with the following publications: (PMID: 14654368, 22579624, 22144547, 7898523, 28771489, 12746413, 31589614, 33673806, 33025817, 21835320, 23054336, 20800588, 25558701, 12707239, 20624503, 24480310, 27662471, 27639548, 26688388, 16538283, 27532257, 28214152, 24792744, 26714042, 31006259, 31308319, 31387947, 22260945, 14636924, 11606294, 10731693, 33906374, 23434821, 27036851)

#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot providednot providednot providednot providednot provided

From Molecular Diagnostic Laboratory for Inherited Cardiovascular Disease, Montreal Heart Institute, SCV000740431.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedclinical testing PubMed (1)
#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot providednot providednot providednot providednot provided

From Stanford Center for Inherited Cardiovascular Disease, Stanford University, SCV000924966.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedprovider interpretationnot provided

Description

Testing for our patients was performed at the Invitae laboratory. Given the strong case data, supportive functional studies, and absence in general population databases, we consider this variant very likely disease causing and we do feel it is suitable for assessing risk in healthy relatives ("predictive genetic testing"). This variant is also referenced in the literature as DeltaE160. The variant has been published in at least 8 unrelated cases of HCM and 3 unrelated cases of RCM (not including this patient's family). We have seen this variant in two patients with HCM at our center. Many of the published families have several affected family members who carry the variant. There is additional case data and strong segregation data have been reported by genetic testing laboratories. The unrelated case count is a conservative estimate, however it is difficult to discern independent cases since few of the published cases report where genetic testing was done and overlapping authors. Presumably some of the original cases published by Watkins in 1995 overlap with cases documented by testing laboratories. Watkins et al. (1995) first reports this variant in patients with HCM. They report the variant was observed in 32 individuals from two families (includes those identified by screening, those deduced from pedigree, and some deceased individuals). However, only 14 of those individuals were studied clinically. 14 of the 32 individuals died suddenly. Average maximum wall thickness was 17.5mm. Study was done at Harvard. Richard et al (2003) report this variant in one index patient with HCM (recruited in France). HCM diagnostic criteria for the study included wall thickness >1.3cm or major abnormalities on ECG. Torricelli et al (2003) reports the variant in three affected individuals of one family (proband, brother, nephew) with HCM. These individuals were recruited from Tuscany. Millat et al. (2010) report this variant in one affected proband with HCM. Patients were French. While possibly an overlapping case with Richard et al, the authors do not appear to overlap. Pasquale et al (2012) refers to the variant as Delta163. The authors observed the variant in 3 families, with 27 carriers. Cases may overlap with those from Watkins et al. There was no specific clinical data for the individuals with the variant, although they all had HCM. Walsh et al. (2012) report this variant in a proband with RCM diagnosed at 17yo and another with RCM diagnosed at 16yo. Maron et al (2014) reports this variant in a brief case report of a family with HCM and RCM (see pedigree below). The authors report that this variant was associated with several phenotypes: non-dilated LV with segmental hypertrophy (no measurements) and intact systolic function, end stage HCM with LV remodeling and systolic dysfunction, and "restrictive" form with impaired ejection fraction. Individual III-4 had non obstructive HCM, anterior ventricular septum measuring 2.3cm, and EF 53% at 37yo. Individual III-2 had non obstructive HCM, posterior ventricular septum measuring 2.1cm and EF of 75% at 28yo. Individual II-1 had a progressive heart failure requiring transplantation at 54yo. He also had history of 2 cardiac arrests, EF of 30% and LVEDD of 5.2cm. Individual II-5 is a 67yo with heart failure requiring transplantation at age 61. She had a restrictive phenotype, LV wall was normal thickness, and EF of 40%. It is unclear from the pedigree if these individuals are all from one family or separate families. The authors also do not include clinical information on those individuals who have tested negative (II-6, III-5, and III-6). The glutamine at codon 163 is conserved across species. The variant falls within the hinge-flexible loop domain and several functional studies have been done to investigate the functional effect of this single amino acid deletion. Harada et al. (2000) report that "the mutant troponin T showed a slightly reduced potency in replacing the endogenous troponin complex in myofibrils and did not affect the inhibitory action of troponin I but potentiated the neutralizing action of troponin C, suggesting that the deletion of a single amino acid, Glu-160, in the strong tropomyosin-binding region affects the tropomyosin binding affinity of the entire troponin T molecule and alters the interaction between troponin I and troponin C within ternary troponin complex in the thin filament. This mutation also increased the Ca(2+) sensitivity of the myofibrillar ATPase activity, as in the case of other mutations in troponin T with clinical phenotypes of poor prognosis similar to that of Glu160." Manning et al (2012) found that this variant results in a decrease in flexibility of the troponin T protein, which results in a tightening of the helix at the C-terminus of TNT1 that both stiffens TNT1 and pulls on the cTnT linker. This results in dramatically different physical behavior. Moore et al (2014) evaluated the in vivo effects of this variant in mutant mice. Severe, progressive cardiac remodeling and myofilament disarray were observed in vivo. In vitro motility assays were consistent with weaker electrostatic binding conditions and increased calcium sensitivity. Messer et al (2016) also replicated increased calcium sensitivity in vitro in troponin T protein harboring this variant. The variant is not present in the Genome Aggregation Consortium Dataset (gnomAD; http://gnomad.broadinstitute.org/), which currently includes variant calls on >123,000 unrelated individuals of African, Asian, European, Latino, and Ashkenazi descent. The average coverage at that site in gnomAD is 95x.

#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineunknownnot providednot providednot providednot providednot providednot providednot provided

From Blueprint Genetics, SCV000927600.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedclinical testingnot provided
#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot providednot providednot providednot providednot provided

From Genome Diagnostics Laboratory, University Medical Center Utrecht - VKGL Data-share Consensus, SCV001929709.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedclinical testingnot provided
#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot providednot providednot providednot providednot provided

From Joint Genome Diagnostic Labs from Nijmegen and Maastricht, Radboudumc and MUMC+ - VKGL Data-share Consensus, SCV001953581.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedclinical testingnot provided
#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot providednot providednot providednot providednot provided

From AiLife Diagnostics, AiLife Diagnostics, SCV002501176.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not provided1not providednot providedclinical testing PubMed (13)
#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot provided1not providednot providednot provided

From Clinical Genetics Laboratory, Skane University Hospital Lund, SCV005197898.1

#EthnicityIndividualsChromosomes TestedFamily HistoryMethodCitations
1not providednot providednot providednot providedclinical testing PubMed (1)
#SampleMethodObservation
OriginAffectedNumber testedTissuePurposeMethodIndividualsAllele frequencyFamiliesCo-occurrences
1germlineyesnot providednot providednot providednot providednot providednot providednot provided

Last Updated: Sep 29, 2024