- This record was updated by the submitter. Please see the current version.
NM_000518.5(HBB):c.20A>T (p.Glu7Val) AND Hb SS disease
- Germline classification:
- Pathogenic (17 submissions)
- Last evaluated:
- Feb 25, 2022
- Review status:
- 2 stars out of maximum of 4 starscriteria provided, multiple submitters, no conflicts
- Somatic classification
of clinical impact: - None
- Review status:
- (0/4) 0 stars out of maximum of 4 starsno assertion criteria provided
- Somatic classification
of oncogenicity: - None
- Review status:
- (0/4) 0 stars out of maximum of 4 starsno assertion criteria provided
- Record status:
- current
- Accession:
- RCV000016574.54
Allele description
NM_000518.5(HBB):c.20A>T (p.Glu7Val)
- Genes:
- LOC106099062:HBB recombination region [Gene]
HBB:hemoglobin subunit beta [Gene - OMIM - HGNC]
LOC107133510:origin of replication at HBB [Gene] - Variant type:
- single nucleotide variant
- Cytogenetic location:
- 11p15.4
- Genomic location:
- Preferred name:
- NM_000518.5(HBB):c.20A>T (p.Glu7Val)
- Other names:
- E6V; HbS
- HGVS:
- NC_000011.10:g.5227002T>A
- NG_000007.3:g.70614A>T
- NG_042296.1:g.533T>A
- NG_046672.1:g.4937T>A
- NG_059281.1:g.5070A>T
- NM_000518.5:c.20A>TMANE SELECT
- NP_000509.1:p.Glu7Val
- NP_000509.1:p.Glu7Val
- LRG_1232t1:c.20A>T
- LRG_1232:g.5070A>T
- LRG_1232p1:p.Glu7Val
- NC_000011.9:g.5248232T>A
- NM_000518.4:c.20A>T
- P68871:p.Glu7Val
This HGVS expression did not pass validation- Protein change:
- E7V; Glu6Val
- Links:
- Genetic Testing Registry (GTR): GTR000115629; Genetic Testing Registry (GTR): GTR000500319; UniProtKB: P68871#VAR_002863; OMIM: 141900.0039; OMIM: 141900.0040; OMIM: 141900.0243; OMIM: 141900.0244; OMIM: 141900.0245; OMIM: 141900.0246; OMIM: 141900.0247; OMIM: 141900.0521; OMIM: 141900.0523; dbSNP: rs334
- NCBI 1000 Genomes Browser:
- rs334
- Molecular consequence:
- NM_000518.5:c.20A>T - missense variant - [Sequence Ontology: SO:0001583]
- Observations:
- 3
Condition(s)
- Name:
- Hb SS disease (SCD)
- Synonyms:
- Sickle cell anemia; HbS disease; Hemoglobin S Disease; See all synonyms [MedGen]
- Identifiers:
- MONDO: MONDO:0011382; MedGen: C0002895; Orphanet: 232; OMIM: 603903
Assertion and evidence details
Submission Accession | Submitter | Review Status (Assertion method) | Clinical Significance (Last evaluated) | Origin | Method | Citations |
---|---|---|---|---|---|---|
SCV000036843 | OMIM | no assertion criteria provided | Pathogenic (Nov 14, 2019) | germline | literature only | PubMed (43) Herrick, J. B. Peculiar elongated and sickle-shaped red blood corpuscles in a case of severe anemia. Arch. Intern. Med. 6: 517-521, 1910., |
SCV000190688 | GeneReviews | no classification provided | not provided | germline | literature only | |
SCV000247542 | Genetic Services Laboratory,University of Chicago | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Feb 16, 2015) | germline | clinical testing | |
SCV000584093 | HudsonAlpha Institute for Biotechnology, HudsonAlpha Institute for Biotechnology - CSER-HudsonAlpha | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Apr 16, 2018) | paternal, maternal, unknown | research | |
SCV000603887 | ARUP Laboratories, Molecular Genetics and Genomics,ARUP Laboratories | criteria provided, single submitter (arup molecular germline variant investigation process 2021) | Pathogenic (Feb 25, 2022) | germline | clinical testing | |
SCV000914520 | Illumina Laboratory Services,Illumina | criteria provided, single submitter (ICSL Variant Classification Criteria 09 May 2019) | Pathogenic (Apr 27, 2017) | germline | clinical testing | |
SCV000967671 | Laboratory for Molecular Medicine,Mass General Brigham Personalized Medicine | criteria provided, single submitter (LMM Criteria) | Pathogenic (Apr 25, 2017) | germline | clinical testing | |
SCV000996163 | Rady Children's Institute for Genomic Medicine, Rady Children's Hospital San Diego | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Jun 29, 2018) | germline | clinical testing | |
SCV001163295 | Baylor Genetics | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic | germline | clinical testing | |
SCV001423600 | Institute for Genomic Medicine (IGM) Clinical Laboratory,Nationwide Children's Hospital | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (May 9, 2018) | germline | clinical testing | |
SCV001984022 | Al Jalila Children's Genomics Center,Al Jalila Childrens Speciality Hospital | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Mar 10, 2021) | germline | clinical testing | |
SCV002028318 | Centogene AG - the Rare Disease Company | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Sep 22, 2021) | germline | clinical testing | |
SCV002030204 | Baylor Genetics - CSER-TexasKidsCanSeq | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Jan 11, 2022) | unknown | clinical testing | |
SCV002058326 | 3billion | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Jan 3, 2022) | germline | clinical testing | PubMed (1) PMID:3267215, |
SCV002073896 | Genomics Facility,Ludwig-Maximilians-Universität München | criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Dec 28, 2021) | biparental | clinical testing | |
SCV002097812 | New York Genome Center - CSER-NYCKidSeq | criteria provided, single submitter (NYGC Assertion Criteria 2020) | Pathogenic (Feb 10, 2021) | germline | clinical testing | |
SCV002556497 | Genetics and Molecular Pathology, SA Pathology
| criteria provided, single submitter (ACMG Guidelines, 2015) | Pathogenic (Feb 6, 2020) | germline | clinical testing |
Summary from all submissions
Ethnicity | Origin | Affected | Individuals | Families | Chromosomes tested | Number Tested | Family history | Method |
---|---|---|---|---|---|---|---|---|
not provided | germline | unknown | not provided | not provided | not provided | not provided | not provided | literature only, clinical testing |
not provided | germline | not provided | 3 | 3 | not provided | not provided | not provided | literature only, clinical testing |
not provided | maternal | unknown | 1 | not provided | not provided | 1 | not provided | research |
not provided | paternal | yes | 1 | not provided | not provided | 1 | not provided | research |
not provided | biparental | yes | not provided | not provided | not provided | not provided | not provided | clinical testing |
not provided | germline | yes | 3 | not provided | not provided | 3 | not provided | clinical testing |
not provided | unknown | yes | 1 | not provided | not provided | 1 | not provided | clinical testing, research |
not provided | unknown | unknown | 6 | not provided | not provided | 6 | not provided | research |
Citations
PubMed
Identification of a nondeletion defect in alpha-thalassemia.
Kan YW, Dozy AM, Trecartin R, Todd D.
N Engl J Med. 1977 Nov 17;297(20):1081-4.
- PMID:
- 909565
Antenatal diagnosis of sickle-cell anaemia by D.N.A. analysis of amniotic-fluid cells.
Kan YW, Dozy AM.
Lancet. 1978 Oct 28;2(8096):910-2.
- PMID:
- 81926
Details of each submission
From OMIM, SCV000036843.13
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | literature only | PubMed (43) |
Description
The change from glutamic acid to valine in sickle hemoglobin was reported by Ingram (1959). Ingram (1956) had reported that the difference between hemoglobin A and hemoglobin S lies in a single tryptic peptide. His analysis of this peptide, peptide 4, was possible by the methods developed by Sanger for determining the structure of insulin and Edman's stepwise degradation of peptides.
Kan and Dozy (1978) used the HpaI restriction endonuclease polymorphism (actually the linkage principle) to make the prenatal diagnosis of sickle cell anemia (603903). As described in 143020, when 'normal' DNA is digested with HpaI, the beta-globin gene is contained in a fragment 7.6 kilobases long. In persons of African extraction 2 variants were detected, 7.0 kb and 13.0 kb long. These variants resulted from alteration in the normal HpaI recognition site 5000 nucleotides to the 3-prime side of the beta-globin gene. The 7.6 and 7.0 kb fragments were present in persons with Hb A, while 87% of persons with Hb S had the 13.0 kb variant. The method is sufficiently sensitive that the cells in 15 ml of uncultured amniotic fluid sufficed. Restriction enzyme studies indicate that whereas Hb S and Hb C originated against the same genetic background (as independent mutations) and the Hb S in the Mediterranean littoral probably is the same mutation as the West African Hb S, Hb S in Asia is apparently a separate mutation. It does not show association with the noncoding polymorphism (Kan and Dozy, 1979).
Mears et al. (1981) used the linkage of the sickle gene with restriction polymorphisms to trace the origin of the sickle gene in Africa. They found evidence that 2 different chromosomes bearing sickle genes were subjected to selection and expansion in 2 physically close but ethnically separate regions of West Africa, with subsequent diffusion to other areas of Africa. The restriction enzyme MnlI recognizes the sequence G-A-G-G, which also is eliminated by the sickle mutation. The MstII enzyme recognizes the sequence C-C-T-N-A-G-G. Predictably, the resulting fragments are larger than those produced by some other enzymes, and MstII is, therefore, particularly useful in prenatal diagnosis (Wilson et al., 1982). The sickle cell mutation can be identified directly in DNA by use of either of 2 restriction endonucleases, DdeI or MstII (Geever et al., 1981; Kazazian, 1982). The nucleotide substitution alters a specific cleavage site recognized by each of these 2 enzymes. The fifth, sixth, and seventh codons of Hb A are CCT-GAG-GAG; in Hb S, they are CCT-GTG-GAG. The recognition site for DdeI is C-T-N-A-G, in which N = any nucleoside. Chang and Kan (1982) and Orkin et al. (1982) found that the assay using the restriction enzyme MstII is sufficiently sensitive that it can be applied to uncultured amniotic fluid cells. The enzyme DdeI requires that the amniotic cells be cultured to obtain enough DNA for the assay.
Antonarakis et al. (1984) applied the Kazazian haplotype method to the study of the origin of the sickle mutation in Africans. Among 170 beta-S bearing chromosomes, 16 different haplotypes of polymorphic sites were found. The 3 most common beta-S haplotypes, accounting for 151 of the 170, were only rarely seen in chromosomes bearing the beta-A gene in these populations (6 out of 47). They suggested the occurrence of up to 4 independent mutations and/or interallelic gene conversions. By haplotype analysis of the beta-globin gene cluster in cases of Hb S in different parts of Africa, Pagnier et al. (1984) concluded that the sickle mutation arose at least 3 times on separate preexisting chromosomal haplotypes. The Hb S gene is closely linked to 3 different haplotypes of polymorphic endonuclease restriction sites in the beta-like gene cluster: one prevalent in Atlantic West Africa, another in central West Africa, and the last in Bantu-speaking Africa (equatorial, East, and southern Africa). Nagel et al. (1985) found hematologic differences between the first 2 types explicable probably by differences in fetal hemoglobin production. Ramsay and Jenkins (1987) found that 20 of 23 sickle-associated haplotypes in southern-African Bantu-speaking black subjects were the same as those found commonly in the Central African Republic, a finding providing the first convincing biologic evidence for the common ancestry of geographically widely separated speakers of languages belonging to the Bantu family. The 3 haplotypes seen with the beta-S gene in Africa are referred to as Senegal, Benin, and Bantu. The 'Bantu line' extends across the waist of Africa; south of the line, Bantu languages are spoken. Based on their study, Ramsay and Jenkins (1987) suggested that the sickle cell mutation arose only once in the Bantu speakers, presumably in their nuclear area of origin, before the Bantu expansion occurred about 2,000 years ago. In Yaounde, the capital city of Cameroon, Lapoumeroulie et al. (1992) observed a novel RFLP pattern in the study of beta-S chromosomes. This chromosome contained an A-gamma-T gene and the RFLP haplotype was different from all the other beta(S) chromosomes in both the 5-prime and 3-prime regions. All the carriers of this specific chromosome belonged to the Eton ethnic group and originated from the Sanaga river valley.
Kulozik et al. (1986) found that the sickle gene in Saudi Arabia and on the west and east coasts of India exists in a haplotype not found in Africa. They concluded that the data are most consistent with an independent Asian origin of the sickle cell mutation. The distribution of the Asian beta-S-haplotype corresponded to the reported geographic distribution of a mild clinical phenotype of homozygous SS disease. Ragusa et al. (1988) found that the beta-S gene in Sicily is in linkage disequilibrium with the Benin haplotype, the same haplotype observed among sickle cell anemia patients from Central West Africa. In addition, this haplotype is either nonexistent or very rare among nonsickling Sicilian persons. They concluded that the beta-S gene was introduced into Sicily from North Africa and that the gene flow originated in Central West Africa, traveling north through historically well-defined trans-Saharan commercial routes.
Zeng et al. (1994) indicated that 5 different haplotypes associated with Hb S had been described, 4 in Africa (Bantu, Benin, Senegal, and Cameroon) and 1 found in both India and Saudi Arabia (Chebloune et al., 1988). There is a correlation between disease severity and haplotype for at least the 2 extremes of severity: patients with the Indian/Arabian haplotype have the mildest course of disease, while those with the Bantu haplotype exhibit the most severe course. Nucleotide -530 is a binding site for a protein called BP1 (601911), which may be a repressor of the HBB gene. BP1 binds with the highest affinity to the Indian haplotype sequence and with the weakest affinity to the Bantu sequence, which might explain the differences in clinical course in these different population groups. Zeng et al. (1994) demonstrated the same sequence at -530 bp in patients with the Arabian haplotype as in Indian sickle cell anemia patients. This supports the idea of a common origin of the sickle cell mutation in individuals in India and Saudi Arabia.
Sammarco et al. (1988) presented further strong evidence that the Hb S gene in Sicily was brought by North African populations, probably during the Muslim invasions.
Currat et al. (2002) studied the genetic diversity of the beta-globin gene cluster in an ethnically well-defined population, the Mandenka from eastern Senegal. The absence of recent admixture and amalgamation in this population permitted application of population genetics methods to investigate the origin of the sickle cell mutation (Flint et al., 1993) and to estimate its age. The frequency of the sickle cell mutation in the Mandenka was estimated as 11.7%. The mutation was found strictly associated with the single Senegal haplotype. Approximately 600 bp of the upstream region of the beta-globin gene were sequenced for 94 chromosomes, showing the presence of 4 transversions, 5 transitions, and a composite microsatellite polymorphism. The sequence of 22 chromosomes carrying the sickle mutation was also identical to the previously defined Senegal haplotype, suggesting that the mutation is very recent. Maximum likelihood estimates of the age of the mutation using Monte Carlo simulations were 45 to 70 generations (1,350-2,100 years) for different demographic scenarios.
Embury et al. (1987) described a new method for rapid prenatal diagnosis of sickle cell anemia by DNA analysis. The first step involved a 200,000-fold enzymatic amplification of the specific beta-globin DNA sequences suspected of carrying the sickle mutation. Next, a short radiolabelled synthetic DNA sequence homologous to normal beta-A-globin gene sequences is hybridized to the amplified target sequence. The hybrid duplexes are then digested sequentially with 2 restriction endonucleases. The presence of the beta-A or beta-S gene sequence in the amplified target DNA from the patient determines whether the beta-A hybridization probe anneals perfectly or with a single nucleotide mismatch. This difference affects the restriction enzyme digestion of the DNA and the size of the resulting radiolabelled digestion products which can be distinguished by electrophoresis followed by autoradiography. The method was sufficiently sensitive and rapid that same-day prenatal diagnosis using fetal DNA was possible. The same test could be applied to the diagnosis of hemoglobin C disease. Hemoglobin C (Georgetown) also sickles. See Herrick (1910), Sherman (1940), Neel (1949), Pauling et al. (1949), Allison (1954), Ingram (1956, 1957, 1959), Chang and Kan (1981), and Shalev et al. (1988).
Barany (1991) described a new assay designed to detect single base substitutions using a thermostable enzyme similar to the DNA polymerase used in PCR. This enzyme, DNA ligase, specifically links adjacent oligonucleotides only when the nucleotides are perfectly base-paired at the junction. In the presence of a second set of adjacent oligonucleotides, complementary to the first set and the target, the oligonucleotide products may be exponentially amplified by thermal cycling of the ligation reaction. Because a single base mismatch precludes ligation and amplification, it will be easily distinguished. Barany (1991) demonstrated the utility of the method in discriminating between normal and sickle globin genotypes from 10 microliter blood samples.
Prezant and Fischel-Ghodsian (1992) described a trapped-oligonucleotide nucleotide incorporation (TONI) assay for the screening of a mitochondrial polymorphism and also showed that it could distinguish the genotypes of hemoglobins A/C, A/A, A/S, and S/S. The method was considered particularly useful for diagnosing mutations that do not produce alterations detectable by restriction enzyme analysis. It also requires only a single oligonucleotide and no electrophoretic separation of the allele-specific products. It represents an improved and simplified modification of the allele-specific primer extension methods. (TONI, the acronym for the method, is also the given name of the first author.)
Grosveld et al. (1987) identified dominant control region (DCR) sequences that flank the human beta-globin locus and direct high-level, copy-number-dependent expression of the human beta-globin gene in erythroid cells in transgenic mice. By inserting a construct that included 2 human alpha genes and the defective human beta-sickle gene, all driven by the DCR sequences, Greaves et al. (1990) produced 2 mice with relatively high levels of human Hb S in their red cells. Use of this as an animal model for the study of this disease was suggested.
Turhan et al. (2002) presented evidence suggesting that a pathogenetic mechanism in sickle cell vasoocclusion may reside in adherent leukocytes. Using intravital microscopy in mice expressing human sickle hemoglobin, they demonstrated that SS red blood cells bind to adherent leukocytes in inflamed venules, producing vasoocclusion of cremasteric venules. SS mice deficient in P- and E-selectins, which display defective leukocyte recruitment to the vessel wall, were protected from vasoocclusion. Thus, drugs targeting SS RBC-leukocyte or leukocyte-endothelial interactions might prevent or treat the vascular complications of this disease.
Nitric oxide (NO), essential for maintaining vascular tone, is produced from arginine by NO synthase. Plasma arginine levels are low in sickle cell anemia, and Romero et al. (2002) reported that the sickle transgenic mouse model has low plasma arginine. They supplemented these mice with a 4-fold increase in arginine over a period of several months. Mean corpuscular hemoglobin concentration decreased and the percent high-density red cells was reduced. Romero et al. (2002) concluded that the major mechanism by which arginine supplementation reduces red cell density in these mice is by inhibiting the Ca(++)-activated K(+) channel.
In a Jamaican study, Serjeant et al. (1968) described 60 patients with homozygous sickle cell disease who were 30 years of age or older, and Platt et al. (1994) estimated a median survival of 42 to 48 years. Serjeant et al. (2007) stated that the sickle cell clinic at the University of West Indies had treated 102 patients (64.7% women) who survived beyond their 60th birthday. None of the patients received hydroxyurea, and only 2 patients with renal impairment received regular transfusions. The ages of the patients ranged from 60.2 to 85.6 years. Measurement of fetal hemoglobin levels suggested that higher fetal hemoglobin levels probably conferred protection in childhood. The major clinical problems emerging with age were renal impairment and decreased levels of hemoglobin.
Kwiatkowski (2005) noted that HbS homozygotes have sickle-cell disease, whereas heterozygosity confers a 10-fold increase in protection from life-threatening malaria (611162) and lesser protection against mild malaria.
Cholera et al. (2008) found that P. falciparum (Pf)-infected HbA/HbS erythrocytes did not bind to microvascular endothelial cells as well as Pf-infected HbA/HbA erythrocytes. Reduced binding correlated with altered display of the major Pf cytoadherence ligand on erythrocyte membranes. Cholera et al. (2008) noted that this protective mechanism had features in common with that of HbC (141900.0038), and they suggested that weakening of cytoadherence interactions may influence the degree of malaria protection in HbA/HbS children.
Modiano et al. (2008) adopted 2 partially independent haplotypic approaches to study the Mossi population in Burkina Faso, where both the HbS and HbC alleles are common. They showed that both alleles are monophyletic, but that the HbC allele has acquired higher recombinatorial and DNA slippage haplotypic variability or linkage disequilibrium decay and is likely older than HbS. Modiano et al. (2008) inferred that the HbC allele has accumulated mainly through recessive rather than a semidominant mechanism of selection.
Gouagna et al. (2010) used cross-sectional surveys of 3,739 human subjects and transmission experiments involving 60 children and over 6,000 mosquitoes in Burkina Faso, West Africa, to test whether the HBB variants HbC and HbS, which are protective against malaria, are associated with transmission of the parasite from the human host to the Anopheles mosquito vector. They found that HbC and HbS were associated with significant 2-fold in vivo (P = 1.0 x 10(-6)) and 4-fold ex vivo (P = 7.0 x 10(-5)) increases of parasite transmission from host to vector. In addition, mean oocyte densities were particularly high in mosquitoes fed from HbS carriers.
Ferreira et al. (2011) demonstrated that wildtype mice or mice expressing normal human Hb, but not mice expressing Hbs, developed experimental cerebral malaria (ECM) 6 to 12 days after infection with the murine malaria parasite, Plasmodium berghei. The Hbs mice eventually succumbed to the unrelated condition of hyperparasitemia-induced anemia. Tolerance to Plasmodium infection was associated with high levels of Hmox1 (141250) expression in hematopoietic cells, and mice expressing Hbs became susceptible to ECM when Hmox1 expression was inhibited. Hbs induced expression of Hmox1 in an Nrf2 (NFE2L2; 600492)-dependent manner, which inhibited the production of chemokines and Cd8-positive T cells associated with ECM pathogenesis. Ferreira et al. (2011) concluded that sickle hemoglobin suppresses the onset of ECM via induction of HMOX1 and the production of carbon monoxide, which inhibits the accumulation of free heme, affording tolerance to Plasmodium infection.
Cyrklaff et al. (2011) found that HbS and HbC affect the trafficking system that directs parasite-encoded proteins to the surface of infected erythrocytes. Cryoelectron tomography revealed that P. falciparum generates a host-derived actin cytoskeleton within the cytoplasm of wildtype red blood cells that connects the Maurer clefts with the host cell membrane and to which transport vesicles are attached. The actin cytoskeleton and the Maurer clefts were aberrant in erythrocytes containing HbS or HbC. Hemoglobin oxidation products, enriched in HbS and HbC erythrocytes, inhibited actin polymerization in vitro and may account for the protective role in malaria.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | not provided | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From GeneReviews, SCV000190688.2
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | literature only | not provided |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | unknown | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Genetic Services Laboratory,University of Chicago, SCV000247542.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From HudsonAlpha Institute for Biotechnology, HudsonAlpha Institute for Biotechnology - CSER-HudsonAlpha, SCV000584093.2
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | 1 | not provided | not provided | research | PubMed (1) |
2 | not provided | 1 | not provided | not provided | research | PubMed (1) |
3 | not provided | 1 | not provided | not provided | research | PubMed (1) |
4 | not provided | 1 | not provided | not provided | research | PubMed (1) |
5 | not provided | 1 | not provided | not provided | research | PubMed (1) |
6 | not provided | 1 | not provided | not provided | research | PubMed (1) |
7 | not provided | 1 | not provided | not provided | research | PubMed (1) |
8 | not provided | 1 | not provided | not provided | research | PubMed (1) |
9 | not provided | 1 | not provided | not provided | research | PubMed (1) |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | unknown | yes | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
2 | paternal | yes | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
3 | unknown | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
4 | unknown | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
5 | maternal | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
6 | unknown | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
7 | unknown | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
8 | unknown | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided | |
9 | unknown | unknown | 1 | not provided | not provided | 1 | not provided | not provided | not provided |
From ARUP Laboratories, Molecular Genetics and Genomics,ARUP Laboratories, SCV000603887.6
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | not provided |
Description
The Hb S variant (HBB: c.20A>T; p.Glu7Val, also known as Glu6Val when numbered from the mature protein, HbVar ID: 226, rs334) is a common pathogenic beta globin variant. Heterozygosity for Hb S is consistent with sickle cell trait. Homozygosity for Hb S results in sickle cell anemia. Hb S in combination with a different pathogenic HBB variant on the opposite chromosome results in various forms of sickle cell disease (see HbVar link and references therein). References: Link to HbVar database: https://globin.bx.psu.edu/hbvar/menu.html
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | unknown | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Illumina Laboratory Services,Illumina, SCV000914520.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (3) |
Description
The HBB c.20A>T (p.Glu7Val) missense variant, also described as p.Glu6Val, is the singular cause of hemoglobin S (Hb S). Individuals who are heterozygous for this variant are said to carry the sickle cell trait. Across a selection of available literature, the p.Glu7Val variant was identified in a homozygous state in at least 1,032 individuals who were diagnosed with sickle cell disease (Kondani et al. 2014; Shrikhande et al. 2014; Grosse et al. 2016). Kondani et al. (2014) reported that of 247 Congolese children studied, the 19 children who were diagnosed with sickle cell anemia were all homozygous for the p.Glu7Val variant, while those without the disease did not carry the variant. In a community screening program of the HBB gene in 35,636 Indian individuals, Shrikhande et al. (2014) identified 5,466 individuals who were heterozygous for the p.Glu7Val variant and 1,010 individuals who were homozygous and who had sickle cell disease. The p.Glu7Val variant is reported at a frequency of 0.13889 in the Yoruba in Ibadan, Nigeria population of the 1000 Genomes Project. Based on the collective evidence, the p.Glu7Val variant is classified as pathogenic for sickle cell disease. This variant was observed by ICSL as part of a predisposition screen in an ostensibly healthy population.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | unknown | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Laboratory for Molecular Medicine,Mass General Brigham Personalized Medicine, SCV000967671.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | 3 | not provided | not provided | clinical testing | PubMed (1) |
Description
The p.Glu7Val variant (also known as Glu6Val and hemoglobin S variant) in HBB ha s been identified in 1088/24028 (4.5%) of African chromosomes by the Genome Aggr egation Database (gnomAD, http://gnomad.broadinstitute.org; dbSNP rs77121243). T he p.Glu7Val variant in HBB, in the homozygous state, causes sickle cell anemia, which accounts for 60-70% of sickle cell disease in the US. Co-inheritance with a second HBB variant associated with abnormal hemoglobin (such as Hb C, Hb D, H b O, Hb E and ?-thalassemia pathogenic variants) results in sickle cell disease.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | not provided | not provided | not provided | not provided | 3 | not provided | 3 | not provided |
From Rady Children's Institute for Genomic Medicine, Rady Children's Hospital San Diego, SCV000996163.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | 1 | not provided | not provided | clinical testing | PubMed (1) |
Description
The c.20A>T (p.Glu7Val) variant in HBB (also known as p.Glu6Val) is the most prevalent genotype associated with sickle cell disease (PMID: 25203083). This variant is an established disease-associated mutation and has been reported as pathogenic by multiple clinical diagnostic laboratories in ClinVar (variant ID: 15333). Based on the available evidence, the c.20A>T (p.Glu7Val) variant is classified as pathogenic.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | 1 | not provided | not provided | 1 | not provided | not provided | not provided |
From Baylor Genetics, SCV001163295.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | unknown | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Institute for Genomic Medicine (IGM) Clinical Laboratory,Nationwide Children's Hospital, SCV001423600.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
Description
[ACMG/AMP: PS3, PM3, PM5, PS4_Moderate, PP5] This alteration is supported by well-established in vitro or in vivo functional studies to have a damaging effect on protein function or splicing [PS3], is detected in trans with a known pathogenic variant [PM3], is a novel missense change at an amino residue where a different missense change has been deemed to be pathogenic [PM5], has previously been observed in multiple unrelated patients with the same phenotype [PS4_Moderate], was reported as a pathogenic/likely pathogenic alteration by a reputable source (ClinVar or other correspondence from a clinical testing laboratory) [PP5].
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Al Jalila Children's Genomics Center,Al Jalila Childrens Speciality Hospital, SCV001984022.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Centogene AG - the Rare Disease Company, SCV002028318.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From Baylor Genetics - CSER-TexasKidsCanSeq, SCV002030204.2
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
Description
This variant was determined to be pathogenic according to ACMG Guidelines, 2015 [PMID:25741868].
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | unknown | yes | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
From 3billion, SCV002058326.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | 1 | not provided | not provided | clinical testing | PubMed (1) |
Description
Same nucleotide change resulting in same amino acid change has been previously reported as pathogenic/likely pathogenic with strong evidence (ClinVar ID: VCV000015333, PMID:3267215, PS1_S). The variant has been observed in multiple (>3) similarly affected unrelated individuals(PMID: 25023084, 25203083, 25023085, PS4_S). Functional studies provide strong evidence of the variant having a damaging effect on the gene or gene product (PMID: 1802884, 2296310, 28356267, 12124399, PS3_S). The variant has been reported to be in trans with a pathogenic variant as either compound heterozygous or homozygous in at least one similarly affected unrelated individual (PMID: 23591685, 29542687, PM3_M). A different missense change at the same codon has been reported as pathogenic/likely pathogenic with strong evidence (ClinVar ID: VCV000015126,VCV000036301, PMID:19460936,6129204,8294201, PM5_M). In silico tool predictions suggest damaging effect of the variant on gene or gene product (3CNET: 0.83, PP3_P). Therefore, this variant is classified as pathogenic according to the recommendation of ACMG/AMP guideline.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | 1 | not provided | not provided | 1 | not provided | not provided | not provided |
From Genomics Facility,Ludwig-Maximilians-Universität München, SCV002073896.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (1) |
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | biparental | yes | not provided | PBMCs | not provided | not provided | not provided | not provided | not provided |
From New York Genome Center - CSER-NYCKidSeq, SCV002097812.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | 1 | not provided | not provided | clinical testing | not provided |
Description
The c.20A>T (p.Glu7Val) variant in HBB (also known as p.Glu6Val) is the most prevalent genotype associated with sickle cell disease [PMID: 25203083]. This variant is an established disease-associated mutation and has been reported as pathogenic by multiple clinical diagnostic laboratories in ClinVar (variant ID: 15333). This variant is identified in gnomAD in 1826 heterozygous individuals, 9 homozygous individuals, with an allele frequency of 1.27e-2. Based on the available evidence, the c.20A>T (p.Glu7Val) variant is classified as pathogenic.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | 1 | not provided | not provided | 1 | not provided | not provided | not provided |
From Genetics and Molecular Pathology, SA Pathology, SCV002556497.1
# | Ethnicity | Individuals | Chromosomes Tested | Family History | Method | Citations |
---|---|---|---|---|---|---|
1 | not provided | not provided | not provided | not provided | clinical testing | PubMed (3) |
Description
PS4, PS3, PP1, PP5, PP4.
# | Sample | Method | Observation | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Origin | Affected | Number tested | Tissue | Purpose | Method | Individuals | Allele frequency | Families | Co-occurrences | |
1 | germline | yes | not provided | not provided | not provided | not provided | not provided | not provided | not provided |
Last Updated: Sep 24, 2022