Anemia Panel
Is ideal for patients suspected to have hereditary anemia who have had HBA1 and HBA2 variants excluded as the cause of their anemia or patients suspected to have hereditary anemia who are not suspected to have HBA1 or HBA2 variants as the cause of their anemia. The genes on this panel are included in the Comprehensive Hematology Panel.
Is not recommended for patients suspected to have anemia due to alpha-thalassemia (HBA1 or HBA2). These genes are highly homologous reducing mutation detection rate due to challenges in variant call and difficult to detect mutation profile (deletions and gene-fusions within the homologous genes tandem in the human genome).
Is not recommended for patients with a suspicion of severe Hemophilia A if the common inversions are not excluded by previous testing. An intron 22 inversion of the F8 gene is identified in 43%-45% individuals with severe hemophilia A and intron 1 inversion in 2%-5% (GeneReviews NBK1404; PMID:8275087, 8490618, 29296726, 27292088, 22282501, 11756167). This test does not detect reliably these inversions.
- PLUS
Summary
The Blueprint Genetics Anemia Panel (test code HE0401):
Read about our accreditations, certifications and CE-marked IVD medical devices here.
ICD Codes
Refer to the most current version of ICD-10-CM manual for a complete list of ICD-10 codes.
Sample Requirements
- Blood (min. 1ml) in an EDTA tube
- Extracted DNA, min. 2 μg in TE buffer or equivalent
- Saliva (Please see Sample Requirements for accepted saliva kits)
Label the sample tube with your patient’s name, date of birth and the date of sample collection.
We do not accept DNA samples isolated from formalin-fixed paraffin-embedded (FFPE) tissue. In addition, if the patient is affected with a hematological malignancy, DNA extracted from a non-hematological source (e.g. skin fibroblasts) is strongly recommended.
Please note that, in rare cases, mitochondrial genome (mtDNA) variants may not be detectable in blood or saliva in which case DNA extracted from post-mitotic tissue such as skeletal muscle may be a better option.
Read more about our sample requirements here.
Anemia is defined as a decrease in the amount of red blood cells or hemoglobin in the blood. The symptoms of anemia include fatigue, weakness, pale skin, and shortness of breath. Other more serious symptoms may occur depending on the underlying cause. The causes of anemia may be classified as impaired red blood cell (RBC) production or increased RBC destruction (hemolytic anemias). Hereditary anemia may be clinically highly variable, including mild, moderate, or severe forms. Hb Bart syndrome is a severe form of anemia secondary to alpha thalassemia. It is characterized by hydrops fetalis leading to death almost always in utero or shortly after birth. The thalassemias, sickle cell disease, and other hemoglobinopathies represent a major group of inherited disorders of hemoglobin synthesis (HBA1, HBA2, HBB). The thalassemias are among the most common genetic disorders worldwide, occurring more frequently in the Mediterranean region, the Indian subcontinent, Southeast Asia, and West Africa. Hereditary spherocytosis and hereditary elliptocytosis are examples of inherited hemolytic anemias. Hereditary spherocytosis is the most common congenital hemolytic anemia among Caucasians with an estimated prevalence ranging from 1:2,000 to 1:5,000.
Genes in the Anemia Panel and their clinical significance
To view complete table content, scroll horizontally.
Gene | Associated phenotypes | Inheritance | ClinVar | HGMD |
---|---|---|---|---|
ABCB7 | Anemia, sideroblastic, and spinocerebellar ataxia | XL | 8 | 9 |
ADAMTS13 | Schulman-Upshaw syndrome, Thrombotic thrombocytopenic purpura, familial | AR | 30 | 183 |
AK1 | Adenylate kinase deficiency, hemolytic anemia due to | AR | 8 | 10 |
ALAS2 | Anemia, sideroblastic, Protoporphyria, erythropoietic | XL | 27 | 103 |
AMN | Megaloblastic anemia-1, Norwegian | AR | 29 | 34 |
ANK1 | Spherocytosis | AD/AR | 20 | 105 |
ATM | Breast cancer, Ataxia-Telangiectasia | AD/AR | 1047 | 1109 |
ATR | Cutaneous telangiectasia and cancer syndrome, Seckel syndrome | AD/AR | 10 | 33 |
ATRX | Carpenter-Waziri syndrome, Alpha-thalassemia/mental retardation syndrome, Holmes-Gang syndrome, Juberg-Marsidi syndrome, Smith-Fineman-Myers syndrome, Mental retardation-hypotonic facies syndrome | XL | 65 | 165 |
BLM | Bloom syndrome | AR | 152 | 119 |
BRCA2 | Fanconi anemia, Medulloblastoma, Glioma susceptibility, Pancreatic cancer, Wilms tumor, Breast-ovarian cancer, familial | AD/AR | 3369 | 2659 |
BRIP1 | Fanconi anemia, Breast cancer | AD/AR | 238 | 189 |
C15ORF41 | Congenital dyserythropoietic anemia | AR | 3 | 3 |
CDAN1 | Anemia, dyserythropoietic congenital | AR | 12 | 61 |
CLCN7 | Osteopetrosis | AD/AR | 15 | 98 |
CUBN* | Megaloblastic anemia-1, Finnish | AR | 42 | 53 |
CYB5R3 | Methemoglobinemia due to methemoglobin reductase deficiency | AR | 21 | 71 |
DHFR* | Megaloblastic anemia due to dihydrofolate reductase deficiency | AR | 2 | 5 |
DNAJC21 | Bone marrow failure syndrome 3 | AR | 5 | 11 |
DNASE2 | Autoinflammatory-pancytopenia syndrome | AR | 2 | |
EFL1* | Shwachman-Diamond syndrome | AR | 3 | 2 |
EPB42 | Spherocytosis | AR | 8 | 17 |
ERCC4 | Fanconi anemia, Xeroderma pigmentosum, XFE progeroid syndrome | AR | 13 | 70 |
FANCA | Fanconi anemia | AR | 191 | 677 |
FANCB | Fanconi anemia | XL | 11 | 21 |
FANCC | Fanconi anemia | AR | 94 | 64 |
FANCD2* | Fanconi anemia | AR | 21 | 61 |
FANCE | Fanconi anemia | AR | 4 | 17 |
FANCF | Fanconia anemia | AR | 7 | 16 |
FANCG | Fanconi anemia | AR | 16 | 92 |
FANCI | Fanconi anemia | AR | 13 | 45 |
FANCL | Fanconi anemia | AR | 13 | 24 |
FANCM | Premature ovarian failure | AD/AR | 6 | 50 |
G6PD | Glucose-6-phosphate dehydrogenase deficiency | XL | 45 | 226 |
GATA1 | Anemia, without thrombocytopenia, Thrombocytopenia with beta-thalessemia,, Dyserythropoietic anemia with thrombocytopenia | XL | 21 | 15 |
GCLC | Gamma-glutamylcysteine synthetase deficiency | AR | 2 | 7 |
GPI | Hemolytic anemia, nonspherocytic due to glucose phosphate isomerase deficiency | AR | 11 | 41 |
GSS | Glutathione synthetase deficiency | AR | 8 | 38 |
HBA1* | Alpha-thalassemia (Hemoglobin Bart syndrome), Alpha-thalassemia (Hemoglobin H disease) | AR/Digenic | 27 | 214 |
HBA2#* | Alpha-thalassemia (Hemoglobin Bart syndrome), Alpha-thalassemia (Hemoglobin H disease) | AR/Digenic | 44 | 290 |
HBB | Sickle cell disease, Thalassemia-beta, dominant inclusion body, Other Thalassemias/Hemoglobinopathies, Beta-thalassemia, Hereditary persistence of fetal hemogoblin | AD/AR/Digenic | 242 | 865 |
HFE | Hemochromatosis | AR/Digenic | 11 | 56 |
KIF23 | Anemia, dyserythropoietic congenital | AD | 1 | 3 |
KLF1 | Anemia, dyserythropoietic congenital, Blood group, Lutheran inhibitor, Hereditary persistence of fetal hemoglobin | AD/AR | 16 | 45 |
LPIN2 | Majeed syndrome | AR | 12 | 14 |
MTR | Methylmalonic acidemia | AR | 13 | 43 |
NBN | Breast cancer, Nijmegen breakage syndrome | AD/AR | 188 | 97 |
NT5C3A | Uridine 5-prime monophosphate hydrolase deficiency, hemolytic anemia due to | AR | 10 | 28 |
PALB2 | Fanconi anemia, Pancreatic cancer, Breast cancer | AD/AR | 495 | 406 |
PC | Pyruvate carboxylase deficiency | AR | 32 | 41 |
PDHA1 | Leigh syndrome, Pyruvate dehydrogenase E1-alpha deficiency | XL | 66 | 192 |
PDHX | Pyruvate dehydrogenase E3-binding protein deficiency | AR | 14 | 22 |
PIEZO1 | Dehydrated hereditary stomatocytosis, Lympehedema, hereditary III | AD/AR | 23 | 60 |
PKLR | Pyruvate kinase deficiency, Elevation of red blood cell ATP levels, familial | AD/AR | 17 | 277 |
PUS1 | Mitochondrial myopathy and sideroblastic anemia | AR | 7 | 9 |
RAD51C | Fanconi anemia, Breast-ovarian cancer, familial | AD/AR | 107 | 125 |
REN | Hyperuricemic nephropathy, Hyperproreninemia, familial, Renal tubular dysgenesis | AD/AR | 9 | 18 |
RHAG | Overhydrated hereditary stomatocytosis, Anemia, hemolytic, Rh-null, regulator type, Anemia, hemolytic,Rh-Mod type, RHAG blood group | AD/AR/BG | 13 | 28 |
RPL11 | Diamond-Blackfan anemia | AD | 12 | 45 |
RPL15* | Diamond-Blackfan anemia | AD | 2 | 2 |
RPL27 | Diamond-Blackfan anemia 16 | 1 | 1 | |
RPL31 | Diamond-Blackfan anemia | AD | 2 | |
RPL35A | Diamond-Blackfan anemia | AD | 7 | 14 |
RPL5 | Diamond-Blackfan anemia | AD | 19 | 77 |
RPS10 | Diamond-Blackfan anemia | AD | 3 | 5 |
RPS19 | Diamond-Blackfan anemia | AD | 23 | 172 |
RPS24 | Diamond-Blackfan anemia | AD | 6 | 10 |
RPS26 | Diamond-Blackfan anemia | AD | 10 | 33 |
RPS28 | Diamond-Blackfan anemia 15 with mandibulofacial dysostosis | AD | 1 | 1 |
RPS29 | Diamond-Blackfan anemia | AD | 4 | 4 |
RPS7 | Diamond-Blackfan anemia | AD | 2 | 10 |
SBDS* | Aplastic anemia, Shwachman-Diamond syndrome, Severe spondylometaphyseal dysplasia | AR | 19 | 90 |
SEC23B | Anemia, dyserythropoietic congenital | AR | 18 | 121 |
SLC11A2 | Anemia, hypochromic microcytic, with iron overload | AR | 5 | 10 |
SLC19A2 | Thiamine-responsive megaloblastic anemia syndrome | AR | 14 | 51 |
SLC25A38 | Anemia, sideroblastic 2, pyridoxine-refractory | AR | 7 | 27 |
SLC4A1 | Spherocytosis, Ovalcytosis, Renal tubular acidosis, distal, with hemolytic anemia, Cryohydrocytosis, Acanthocytosis, Band 3 Memphis | AD/AR/BG | 38 | 122 |
SLX4 | Fanconi anemia | AR | 18 | 72 |
SPTA1 | Spherocytosis, Ellipsocytosis, Pyropoikilocytosis | AD/AR | 29 | 51 |
SPTB | Spherocytosis, Anemia, neonatal hemolytic, Ellipsocytosis | AD/AR | 24 | 99 |
SRP54 | Shwachman-Diamond syndrome | AD | 3 | |
TCN2 | Transcobalamin II deficiency | AR | 9 | 35 |
TF | Atransferrinemia | AR | 8 | 17 |
THBD | Thrombophilia due to thrombomodulin defect, Hemolytic uremic syndrome, atypical | AD | 5 | 28 |
TMPRSS6 | Iron-refractory iron deficiency anemia | AR | 13 | 102 |
TPI1 | Triosephosphate isomerase deficiency | AR | 8 | 19 |
XRCC2 | Hereditary breast cancer | AD/AR | 10 | 21 |
YARS2 | Myopathy, lactic acidosis, and sideroblastic anemia | AR | 27 | 11 |
The gene has suboptimal coverage (means <90% of the gene’s target nucleotides are covered at >20x with mapping quality score (MQ>20) reads), and/or the gene has exons listed under Test limitations section that are not included in the panel as they are not sufficiently covered with high quality sequence reads.
Some, or all, of the gene is duplicated in the genome. Read more.
The sensitivity to detect variants may be limited in genes marked with an asterisk (*) or number sign (#). Due to possible limitations these genes may not be available as single gene tests.
Gene refers to the HGNC approved gene symbol; Inheritance refers to inheritance patterns such as autosomal dominant (AD), autosomal recessive (AR), mitochondrial (mi), X-linked (XL), X-linked dominant (XLD) and X-linked recessive (XLR); ClinVar refers to the number of variants in the gene classified as pathogenic or likely pathogenic in this database (ClinVar); HGMD refers to the number of variants with possible disease association in the gene listed in Human Gene Mutation Database (HGMD). The list of associated, gene specific phenotypes are generated from CGD or Mitomap databases.
Non-coding variants covered by Anemia Panel
To view complete table content, scroll horizontally.
Gene | Genomic location HG19 | HGVS | RefSeq | RS-number |
---|---|---|---|---|
ALAS2 | ChrX:55054634 | c.-15-2186C>G | NM_000032.4 | |
ALAS2 | ChrX:55054635 | c.-15-2187T>C | NM_000032.4 | |
ALAS2 | ChrX:55054636 | c.-15-2188A>G | NM_000032.4 | |
ALAS2 | ChrX:55057393 | c.-34C>T | NM_000032.4 | rs780642606 |
ALAS2 | ChrX:55057617 | c.-258C>G | NM_000032.4 | rs140772352 |
AMN | Chr14:103395424 | c.514-34G>A | NM_030943.3 | rs144077391 |
AMN | Chr14:103396444 | c.1007-31_1006+34delCCTCGCCCCGCCGCG | NM_030943.3 | rs386834161 |
AMN | Chr14:103396458 | c.1007-29_1006+36delTCGCCCCGCCGCGGG | NM_030943.3 | rs386834162 |
ANK1 | Chr8:41566510 | c.1900-17G>A | NM_001142446.1 | rs786205243 |
ANK1 | Chr8:41566511 | c.1900-18C>A | NM_001142446.1 | |
ANK1 | Chr8:41655127 | c.-73_-72delTG | NM_020476.2 | rs786205242 |
ATM | Chr11:108093770 | c.-174A>G | NM_000051.3 | |
ATM | Chr11:108094508 | c.-31+595G>A | NM_000051.3 | |
ATM | Chr11:108098321 | c.-30-1G>T | NM_000051.3 | rs869312754 |
ATM | Chr11:108138753 | c.2639-384A>G | NM_000051.3 | |
ATM | Chr11:108141209 | c.2839-579_2839-576delAAGT | NM_000051.3 | |
ATM | Chr11:108151710 | c.3403-12T>A | NM_000051.3 | rs201370733 |
ATM | Chr11:108158168 | c.3994-159A>G | NM_000051.3 | rs864622543 |
ATM | Chr11:108164028 | c.4612-12A>G | NM_000051.3 | |
ATM | Chr11:108179837 | c.5763-1050A>G | NM_000051.3 | rs774925473 |
ATM | Chr11:108214779 | c.8418+681A>G | NM_000051.3 | rs748635985 |
BRCA2 | Chr13:32889805 | c.-40+1G>A | NM_000059.3 | |
BRCA2 | Chr13:32890469 | c.-39-89delC | NM_000059.3 | |
BRCA2 | Chr13:32890556 | c.-39-1_-39delGA | NM_000059.3 | rs758732038 |
BRCA2 | Chr13:32890558 | c.-39-1G>A | NM_000059.3 | rs1060499566 |
BRCA2 | Chr13:32900222 | c.426-12_426-8delGTTTT | NM_000059.3 | rs276174844 |
BRCA2 | Chr13:32945079 | c.8488-14A>G | NM_000059.3 | |
BRCA2 | Chr13:32953872 | c.8954-15T>G | NM_000059.3 | |
BRCA2 | Chr13:32971007 | c.9502-28A>G | NM_000059.3 | rs397508059 |
BRCA2 | Chr13:32971023 | c.9502-12T>G | NM_000059.3 | rs81002803 |
BRIP1 | Chr17:59858864 | c.1629-498A>T | NM_032043.2 | |
CLCN7 | Chr16:1506057 | c.916+57A>T | NM_001287.5 | |
CLCN7 | Chr16:1507356 | c.739-18G>A | NM_001287.5 | rs371893553 |
CUBN | Chr10:17088532 | c.3330-439C>G | NM_001081.3 | rs386833782 |
FANCA | Chr16:89805127 | c.4261-19_4261-12delACCTGCTC | NM_000135.3 | |
FANCA | Chr16:89816056 | c.3239+82T>G | NM_000135.2 | |
FANCA | Chr16:89818822 | c.2982-192A>G | NM_000135.2 | |
FANCA | Chr16:89831215 | c.2778+83C>G | NM_000135.2 | rs750997715 |
FANCA | Chr16:89836111 | c.2504+134A>G | NM_000135.2 | |
FANCA | Chr16:89836805 | c.2223-138A>G | NM_000135.2 | |
FANCA | Chr16:89849346 | c.1567-20A>G | NM_000135.2 | rs775154397 |
FANCA | Chr16:89864654 | c.893+920C>A | NM_000135.2 | |
FANCC | Chr9:98011653 | c.-78-2A>G | NM_000136.2 | rs587779898 |
FANCC | Chr9:98079807 | c.-79+1G>A | NM_000136.2 | |
FANCD2 | Chr3:10083186 | c.696-121C>G | NM_033084.3 | |
FANCD2 | Chr3:10102127 | c.1766+40T>G | NM_033084.3 | |
FANCD2 | Chr3:10106024 | c.1948-16T>G | NM_033084.3 | |
FANCI | Chr15:89825208 | c.1583+142C>T | NM_001113378.1 | |
FANCL | Chr2:58433394 | c.375-2033C>G | NM_001114636.1 | |
GATA1 | ChrX:48649496 | c.-19-2A>G | NM_002049.3 | |
GSS | Chr20:33537864 | c.129+1663A>G | NM_000178.2 | |
GSS | Chr20:33543525 | c.-9+5G>A | NM_000178.2 | |
HBA1 | Chr16:227471 | c.*63_*65delCCT | NM_000558.3 | |
HBA2 | Chr16:223646 | c.*47G>C | NM_000517.4 | rs4021971 |
HBA2 | Chr16:223672 | c.*74_*89delCCTTCCTGGTCTTTGA | NM_000517.4 | rs63750919 |
HBA2 | Chr16:223690 | c.*93_*94delAA | NM_000517.4 | rs63751268 |
HBA2 | Chr16:223691 | c.*92A>G | NM_000517.4 | rs63750067 |
HBA2 | Chr16:223693 | c.*94A>G | NM_000517.4 | |
HBA2 | Chr16:223693 | c.*94A>C | NM_000517.4 | |
HBA2 | Chr16:223703 | c.*104G>T | NM_000517.4 | |
HBB | Chr11:5246696 | c.*132C>A/T | NM_000518.4 | |
HBB | Chr11:5246696 | c.*132C>A | NM_000518.4 | rs1420779550 |
HBB | Chr11:5246696 | c.*132C>T | NM_000518.4 | |
HBB | Chr11:5246699 | c.*129T>C | NM_000518.4 | |
HBB | Chr11:5246711 | c.*115_*116delAA | NM_000518.4 | rs281864532 |
HBB | Chr11:5246713 | c.*110_*114delTAAAA | NM_000518.4 | rs606231219,rs35949130 |
HBB | Chr11:5246715 | c.*113A>G | NM_000518.4 | rs33985472 |
HBB | Chr11:5246716 | c.*112A>G/T | NM_000518.4 | rs63750954 |
HBB | Chr11:5246716 | c.*112A>T | NM_000518.4 | |
HBB | Chr11:5246716 | c.*112A>G | NM_000518.4 | |
HBB | Chr11:5246716 | c.*110_*111delTA | NM_000518.4 | rs63750205,rs281864905 |
HBB | Chr11:5246717 | c.*111A>G | NM_000518.4 | rs63751128 |
HBB | Chr11:5246718 | c.*110T>A/C | NM_000518.4 | rs33978907 |
HBB | Chr11:5246718 | c.*110T>G | NM_000518.4 | |
HBB | Chr11:5246720 | c.*108A>C/G | NM_000518.4 | |
HBB | Chr11:5246720 | c.*108A>C | NM_000518.4 | |
HBB | Chr11:5246720 | c.*108A>G | NM_000518.4 | |
HBB | Chr11:5246722 | c.*93_*105delATCTGGATTCTGC | NM_000518.4 | rs34171453 |
HBB | Chr11:5246732 | c.*96T>C | NM_000518.4 | rs34029390 |
HBB | Chr11:5246754 | c.*74A>G | NM_000518.4 | rs369101035 |
HBB | Chr11:5246781 | c.*47C>G | NM_000518.4 | |
HBB | Chr11:5246796 | c.*32A>C | NM_000518.4 | |
HBB | Chr11:5246970 | c.316-14T>G | NM_000518.4 | rs35703285 |
HBB | Chr11:5247046 | c.316-90A>G | NM_000518.4 | rs63750433 |
HBB | Chr11:5247062 | c.316-106C>G | NM_000518.4 | rs34690599 |
HBB | Chr11:5247102 | c.316-146T>G | NM_000518.4 | rs35328027 |
HBB | Chr11:5247153 | c.316-197C>T | NM_000518.4 | rs34451549 |
HBB | Chr11:5247216 | c.316-260T>C | NM_000518.4 | |
HBB | Chr11:5247602 | c.315+203_315+205delTCTinsCC | NM_000518.4 | |
HBB | Chr11:5248044 | c.93-15T>G | NM_000518.4 | rs35456885 |
HBB | Chr11:5248050 | c.93-21G>A | NM_000518.4 | rs35004220 |
HBB | Chr11:5248050 | c.93-22delT | NM_000518.4 | |
HBB | Chr11:5248263 | c.-12C>T | NM_000518.4 | rs113115948 |
HBB | Chr11:5248269 | c.-18C>G | NM_000518.4 | rs34135787 |
HBB | Chr11:5248272 | c.-21T>A | NM_000518.4 | |
HBB | Chr11:5248280 | c.-29G>A/T | NM_000518.4 | rs34704828 |
HBB | Chr11:5248281 | c.-31delC | NM_000518.4 | |
HBB | Chr11:5248282 | c.-31C>T | NM_000518.4 | rs63750628 |
HBB | Chr11:5248291 | c.-41delT | NM_000518.4 | rs35352549 |
HBB | Chr11:5248294 | c.-43C>T | NM_000518.4 | |
HBB | Chr11:5248301 | c.-50A>C | NM_000518.4 | rs34305195 |
HBB | Chr11:5248301 | c.-50A>G/T | NM_000518.4 | |
HBB | Chr11:5248326 | c.-75G>T | NM_000518.4 | |
HBB | Chr11:5248326 | c.-75G>C | NM_000518.4 | rs63750400 |
HBB | Chr11:5248326 | NM_000518.4 | rs63750953 | |
HBB | Chr11:5248327 | c.-76A>C | NM_000518.4 | rs281864525 |
HBB | Chr11:5248328 | c.-77A>G/T | NM_000518.4 | |
HBB | Chr11:5248328 | NM_000518.4 | ||
HBB | Chr11:5248328 | NM_000518.4 | ||
HBB | Chr11:5248329 | c.-78A>C/G | NM_000518.4 | rs33931746 |
HBB | Chr11:5248329 | NM_000518.4 | ||
HBB | Chr11:5248329 | NM_000518.4 | ||
HBB | Chr11:5248330 | c.-79A>G | NM_000518.4 | rs34598529 |
HBB | Chr11:5248330 | NM_000518.4 | rs397509430 | |
HBB | Chr11:5248331 | c.-80T>A/C | NM_000518.4 | rs33980857 |
HBB | Chr11:5248331 | NM_000518.4 | ||
HBB | Chr11:5248331 | NM_000518.4 | ||
HBB | Chr11:5248332 | c.-81A>C/G | NM_000518.4 | rs33981098 |
HBB | Chr11:5248332 | NM_000518.4 | ||
HBB | Chr11:5248332 | NM_000518.4 | ||
HBB | Chr11:5248333 | c.-82C>A/T | NM_000518.4 | rs34500389 |
HBB | Chr11:5248333 | NM_000518.4 | ||
HBB | Chr11:5248333 | NM_000518.4 | ||
HBB | Chr11:5248342 | c.-91A>C | NM_000518.4 | |
HBB | Chr11:5248343 | c.-92C>G | NM_000518.4 | rs397515291 |
HBB | Chr11:5248351 | c.-100G>A | NM_000518.4 | rs281864524 |
HBB | Chr11:5248372 | c.-121C>T | NM_000518.4 | rs281864518 |
HBB | Chr11:5248373 | NM_000518.4 | rs1272414751 | |
HBB | Chr11:5248374 | c.-123A>T | NM_000518.4 | |
HBB | Chr11:5248377 | c.-126C>A | NM_000518.4 | |
HBB | Chr11:5248378 | c.-127G>C | NM_000518.4 | |
HBB | Chr11:5248384 | NM_000518.4 | rs72561473 | |
HBB | Chr11:5248387 | c.-136C>A/G/T | NM_000518.4 | rs33994806 |
HBB | Chr11:5248387 | NM_000518.4 | ||
HBB | Chr11:5248387 | NM_000518.4 | ||
HBB | Chr11:5248387 | NM_000518.4 | ||
HBB | Chr11:5248388 | c.-137C>A/G/T | NM_000518.4 | rs33941377 |
HBB | Chr11:5248388 | NM_000518.4 | ||
HBB | Chr11:5248388 | NM_000518.4 | ||
HBB | Chr11:5248388 | NM_000518.4 | ||
HBB | Chr11:5248389 | c.-138C>A/T | NM_000518.4 | rs33944208 |
HBB | Chr11:5248389 | NM_000518.4 | ||
HBB | Chr11:5248389 | NM_000518.4 | ||
HBB | Chr11:5248391 | NM_000518.4 | rs34999973 | |
HBB | Chr11:5248393 | c.-142C>T | NM_000518.4 | rs34883338 |
HBB | Chr11:5248394 | c.-143C>G | NM_000518.4 | rs63751043 |
HBB | Chr11:5248402 | c.-151C>T | NM_000518.4 | rs63751208 |
HBB | Chr11:5248402 | NM_000518.4 | ||
HBB | Chr11:5248403 | c.-152C>A | NM_000518.4 | |
HBB | Chr11:5248491 | c.-240G>A | NM_000518.4 | rs753344875 |
HBB | Chr11:5248524 | c.-273T>C | NM_000518.4 | rs139703273 |
HFE | Chr6:26087649 | c.-20G>A | NM_000410.3 | rs138378000 |
KLF1 | Chr19:12998078 | c.-124T>C | NM_006563.3 | |
KLF1 | Chr19:12998102 | NM_006563.3 | rs552824864 | |
KLF1 | Chr19:12998108 | c.-154C>T | NM_006563.3 | rs372651309 |
MTR | Chr1:236971838 | c.340-166A>G | NM_000254.2 | |
MTR | Chr1:236977232 | c.609+1088G>A | NM_000254.2 | rs752526782 |
MTR | Chr1:237057461 | c.3205-196A>G | NM_000254.2 | rs544410324 |
PALB2 | Chr16:23649285 | c.109-12T>A | NM_024675.3 | rs774949203 |
PC | Chr11:66620883 | c.1369-29A>G | NM_000920.3 | |
PDHA1 | ChrX:19371182 | c.533-17_533-14delTGTT | NM_001173454.1 | |
PDHA1 | ChrX:19372579 | c.625-30G>A | NM_001173454.1 | |
PDHA1 | ChrX:19373648 | c.873+26G>A | NM_001173454.1 | |
PDHA1 | ChrX:19377849 | c.*79_*90dupAGTCAATGAAAT | NM_001173454.1 | rs606231192 |
PDHA1 | ChrX:19377861 | c.*79_*90dupAGTCAATGAAAT | NM_001173454.1 | |
PDHX | Chr11:34988372 | c.816+11C>G | NM_003477.2 | |
PKLR | Chr1:155263185 | c.1269+44C>T | NM_000298.5 | |
PKLR | Chr1:155265208 | c.507+20C>A | NM_000298.5 | |
PKLR | Chr1:155271258 | c.-72A>G | NM_000298.5 | |
PKLR | Chr1:155271259 | c.-73G>C | NM_000298.5 | |
PKLR | Chr1:155271269 | c.-83G>C | NM_000298.5 | |
PKLR | Chr1:155271269 | NM_000298.5 | rs1460844860 | |
REN | Chr1:204129817 | c.374-12_374-11delTCinsAG | NM_000537.3 | |
RPL31 | Chr2:101618778 | c.-1+1G>A | NM_001098577.2 | |
RPL5 | Chr1:93300322 | c.190-12_191dupCTCTTACTATAGAT | NM_000969.3 | |
RPS19 | Chr19:42364214 | c.-144_-141delTTTC | NM_001022.3 | |
RPS26 | Chr12:56436176 | c.4-25_4-14delTAACAGTTTTCC | NM_001029.3 | |
RPS7 | Chr2:3622941 | c.-19+1G>T | NM_001011.3 | |
RPS7 | Chr2:3622942 | c.-19+2T>C | NM_001011.3 | |
SEC23B | Chr20:18488060 | c.-571A>G | NM_006363.4 | rs559854357 |
SEC23B | Chr20:18488615 | c.-16A>G | NM_006363.4 | |
SEC23B | Chr20:18491731 | c.221+31A>G | NM_006363.4 | |
SEC23B | Chr20:18491863 | c.221+163A>G | NM_006363.4 | rs573898514 |
SEC23B | Chr20:18492791 | c.222-78C>T | NM_006363.4 | rs150393520 |
SEC23B | Chr20:18526845 | c.1743+168A>G | NM_006363.4 | rs111951711 |
SLC4A1 | Chr17:42340296 | c.-62G>A | NM_000342.3 | rs387906565 |
SPTA1 | Chr1:158613314 | c.4339-99C>T | NM_003126.2 | rs200830867 |
SPTA1 | Chr1:158626459 | c.2806-13T>G | NM_003126.2 | |
TCN2 | Chr22:31011112 | c.581-176A>T | NM_000355.3 | |
TCN2 | Chr22:31011112 | c.581-176A>G | NM_000355.3 | rs372866837 |
THBD | Chr20:23030319 | NM_000361.2 | ||
THBD | Chr20:23030443 | c.-302C>A | NM_000361.2 |
Test Strengths
The strengths of this test include:
- CAP accredited laboratory
- CLIA-certified personnel performing clinical testing in a CLIA-certified laboratory
- Powerful sequencing technologies, advanced target enrichment methods and precision bioinformatics pipelines ensure superior analytical performance
- Careful construction of clinically effective and scientifically justified gene panels
- Some of the panels include the whole mitochondrial genome (please see the Panel Content section)
- Our Nucleus online portal providing transparent and easy access to quality and performance data at the patient level
- ~2,000 non-coding disease causing variants in our clinical grade NGS assay for panels (please see ‘Non-coding disease causing variants covered by this panel’ in the Panel Content section)
- Our rigorous variant classification scheme
- Our systematic clinical interpretation workflow using proprietary software enabling accurate and traceable processing of NGS data
- Our comprehensive clinical statements
Test Limitations
*HBA1* and *HBA2* genes have identical sequences at coding region and their mapping rely purely on differences at intronic/UTR regions. This reduces sensitivity for detecting variants in these region by using standard NGS diagnostics. However, Blueprint Genetics custom assay has good coverage (>20x) with improved mapping rates (mapping quality >40) within the target regions of these genes: *HBA1* 80.7% and *HBA2* 59.4%. Our validation showed high mean coverage of 604x for *HBA1* gene and 463x for *HBA2*. We have been able to detect sequence variants and some of the known disease causing deletions using our assay but some limitations in sensitivity is expected to exist at the moment. Genes with suboptimal coverage in our assay are marked with number sign (#) and genes with partial, or whole gene, segmental duplications in the human genome are marked with an asterisk (*) if they overlap with the UCSC pseudogene regions. Gene is considered to have suboptimal coverage when >90% of the gene’s target nucleotides are not covered at >20x with mapping quality score (MQ>20) reads. The technology may have limited sensitivity to detect variants in genes marked with these symbols (please see the Panel content table above).
This test does not detect the following:
- Complex inversions
- Gene conversions
- Balanced translocations
- Some of the panels include the whole mitochondrial genome but not all (please see the Panel Content section)
- Repeat expansion disorders unless specifically mentioned
- Non-coding variants deeper than ±20 base pairs from exon-intron boundary unless otherwise indicated (please see above Panel Content / non-coding variants covered by the panel).
This test may not reliably detect the following:
- Low level mosaicism in nuclear genes (variant with a minor allele fraction of 14.6% is detected with 90% probability)
- Stretches of mononucleotide repeats
- Low level heteroplasmy in mtDNA (>90% are detected at 5% level)
- Indels larger than 50bp
- Single exon deletions or duplications
- Variants within pseudogene regions/duplicated segments
- Some disease causing variants present in mtDNA are not detectable from blood, thus post-mitotic tissue such as skeletal muscle may be required for establishing molecular diagnosis.
The sensitivity of this test may be reduced if DNA is extracted by a laboratory other than Blueprint Genetics.
For additional information, please refer to the Test performance section.
The genes on the panel have been carefully selected based on scientific literature, mutation databases and our experience.
Our panels are sectioned from our high-quality, clinical grade NGS assay. Please see our sequencing and detection performance table for details regarding our ability to detect different types of alterations (Table).
Assays have been validated for various sample types including EDTA-blood, isolated DNA (excluding from formalin fixed paraffin embedded tissue), saliva and dry blood spots (filter cards). These sample types were selected in order to maximize the likelihood for high-quality DNA yield. The diagnostic yield varies depending on the assay used, referring healthcare professional, hospital and country. Plus analysis increases the likelihood of finding a genetic diagnosis for your patient, as large deletions and duplications cannot be detected using sequence analysis alone. Blueprint Genetics’ Plus Analysis is a combination of both sequencing and deletion/duplication (copy number variant (CNV)) analysis.
The performance metrics listed below are from an initial validation performed at our main laboratory in Finland. The performance metrics of our laboratory in Marlborough, MA, are equivalent.
Performance of Blueprint Genetics high-quality, clinical grade NGS sequencing assay for panels.
Sensitivity % (TP/(TP+FN) | Specificity % | |
---|---|---|
Single nucleotide variants | 99.89% (99,153/99,266) | >99.9999% |
Insertions, deletions and indels by sequence analysis | ||
1-10 bps | 99.2% (7,745/7,806) | >99.9999% |
11-50 bps | 99.13% (2,524/2,546) | >99.9999% |
Copy number variants (exon level dels/dups) | ||
1 exon level deletion (heterozygous) | 100% (20/20) | NA |
1 exon level deletion (homozygous) | 100% (5/5) | NA |
1 exon level deletion (het or homo) | 100% (25/25) | NA |
2-7 exon level deletion (het or homo) | 100% (44/44) | NA |
1-9 exon level duplication (het or homo) | 75% (6/8) | NA |
Simulated CNV detection | ||
5 exons level deletion/duplication | 98.7% | 100.00% |
Microdeletion/-duplication sdrs (large CNVs, n=37)) | ||
Size range (0.1-47 Mb) | 100% (25/25) | |
The performance presented above reached by Blueprint Genetics high-quality, clinical grade NGS sequencing assay with the following coverage metrics | ||
Mean sequencing depth | 143X | |
Nucleotides with >20x sequencing coverage (%) | 99.86% |
Performance of Blueprint Genetics Mitochondrial Sequencing Assay.
Sensitivity % | Specificity % | |
---|---|---|
ANALYTIC VALIDATION (NA samples; n=4) | ||
Single nucleotide variants | ||
Heteroplasmic (45-100%) | 100.0% (50/50) | 100.0% |
Heteroplasmic (35-45%) | 100.0% (87/87) | 100.0% |
Heteroplasmic (25-35%) | 100.0% (73/73) | 100.0% |
Heteroplasmic (15-25%) | 100.0% (77/77) | 100.0% |
Heteroplasmic (10-15%) | 100.0% (74/74) | 100.0% |
Heteroplasmic (5-10%) | 100.0% (3/3) | 100.0% |
Heteroplasmic (<5%) | 50.0% (2/4) | 100.0% |
CLINICAL VALIDATION (n=76 samples) | ||
All types | ||
Single nucleotide variants n=2026 SNVs | ||
Heteroplasmic (45-100%) | 100.0% (1940/1940) | 100.0% |
Heteroplasmic (35-45%) | 100.0% (4/4) | 100.0% |
Heteroplasmic (25-35%) | 100.0% (3/3) | 100.0% |
Heteroplasmic (15-25%) | 100.0% (3/3) | 100.0% |
Heteroplasmic (10-15%) | 100.0% (9/9) | 100.0% |
Heteroplasmic (5-10%) | 92.3% (12/13) | 99.98% |
Heteroplasmic (<5%) | 88.9% (48/54) | 99.93% |
Insertions and deletions by sequence analysis n=40 indels | ||
Heteroplasmic (45-100%) 1-10bp | 100.0% (32/32) | 100.0% |
Heteroplasmic (5-45%) 1-10bp | 100.0% (3/3) | 100.0% |
Heteroplasmic (<5%) 1-10bp | 100.0% (5/5) | 99,997% |
SIMULATION DATA /(mitomap mutations) | ||
Insertions, and deletions 1-24 bps by sequence analysis; n=17 | ||
Homoplasmic (100%) 1-24bp | 100.0% (17/17) | 99.98% |
Heteroplasmic (50%) | 100.0% (17/17) | 99.99% |
Heteroplasmic (25%) | 100.0% (17/17) | 100.0% |
Heteroplasmic (20%) | 100.0% (17/17) | 100.0% |
Heteroplasmic (15%) | 100.0% (17/17) | 100.0% |
Heteroplasmic (10%) | 94.1% (16/17) | 100.0% |
Heteroplasmic (5%) | 94.1% (16/17) | 100.0% |
Copy number variants (separate artifical mutations; n=1500) | ||
Homoplasmic (100%) 500 bp, 1kb, 5 kb | 100.0% | 100.0% |
Heteroplasmic (50%) 500 bp, 1kb, 5 kb | 100.0% | 100.0% |
Heteroplasmic (30%) 500 bp, 1kb, 5 kb | 100.0% | 100.0% |
Heteroplasmic (20%) 500 bp, 1kb, 5 kb | 99.7% | 100.0% |
Heteroplasmic (10%) 500 bp, 1kb, 5 kb | 99.0% | 100.0% |
The performance presented above reached by following coverage metrics at assay level (n=66) | ||
Mean of medians | Median of medians | |
Mean sequencing depth MQ0 (clinical) | 18224X | 17366X |
Nucleotides with >1000x MQ0 sequencing coverage (%) (clinical) | 100% | |
rho zero cell line (=no mtDNA), mean sequencing depth | 12X |
The target region for each gene includes coding exons and ±20 base pairs from the exon-intron boundary. In addition, the panel includes non-coding and regulatory variants if listed above (Non-coding variants covered by the panel). Some regions of the gene(s) may be removed from the panel if specifically mentioned in the ‘Test limitations” section above. If the test includes the mitochondrial genome the target region gene list contains the mitochondrial genes. The sequencing data generated in our laboratory is analyzed with our proprietary data analysis and annotation pipeline, integrating state-of-the art algorithms and industry-standard software solutions. Incorporation of rigorous quality control steps throughout the workflow of the pipeline ensures the consistency, validity and accuracy of results. Our pipeline is streamlined to maximize sensitivity without sacrificing specificity. We have incorporated a number of reference population databases and mutation databases including, but not limited, to 1000 Genomes Project, gnomAD, ClinVar and HGMD into our clinical interpretation software to make the process effective and efficient. For missense variants, in silico variant prediction tools such as SIFT, PolyPhen,MutationTaster are used to assist with variant classification. Through our online ordering and statement reporting system, Nucleus, ordering providers have access to the details of the analysis, including patient specific sequencing metrics, a gene level coverage plot and a list of regions with suboptimal coverage (<20X for nuclear genes and <1000X for mtDNA) if applicable. This reflects our mission to build fully transparent diagnostics where ordering providers can easily visualize the crucial details of the analysis process.
We provide customers with the most comprehensive clinical report available on the market. Clinical interpretation requires a fundamental understanding of clinical genetics and genetic principles. At Blueprint Genetics, our PhD molecular geneticists, medical geneticists, and clinical consultants prepare the clinical statement together by evaluating the identified variants in the context of the phenotypic information provided in the requisition form. Our goal is to provide clinically meaningful statements that are understandable for all medical professionals regardless of whether they have formal training in genetics.
Variant classification is the cornerstone of clinical interpretation and resulting patient management decisions. Our classifications follow the ACMG guideline 2015.
The final step in the analysis is orthogonal confirmation. Sequence and copy number variants classified as pathogenic, likely pathogenic, and variants of uncertain significance (VUS) are confirmed using bi-directional Sanger sequencing or by orthogonal methods such as qPCR/ddPCR when they do not meet our stringent NGS quality metrics for a true positive call.
Our clinical statement includes tables for sequencing and copy number variants that include basic variant information (genomic coordinates, HGVS nomenclature, zygosity, allele frequencies, in silico predictions, OMIM phenotypes, and classification of the variant). In addition, the statement includes detailed descriptions of the variant, gene, and phenotype(s) including the role of the specific gene in human disease, the mutation profile, information about the gene’s variation in population cohorts, and detailed information about related phenotypes. We also provide links to the references, abstracts, and variant databases used to help ordering providers further evaluate the reported findings if desired. The conclusion summarizes all of the existing information and provides our rationale for the classification of the variant.
Identification of pathogenic or likely pathogenic variants in dominant disorders or their combinations in different alleles in recessive disorders are considered molecular confirmation of the clinical diagnosis. In these cases, family member testing can be used for risk stratification. We do not recommend using variants of uncertain significance (VUS) for family member risk stratification or patient management. Genetic counseling is recommended.
Our interpretation team analyzes millions of variants from thousands of individuals with rare diseases. Our internal database and our understanding of variants and related phenotypes increases with every case analyzed. Our laboratory is therefore well-positioned to re-classify previously reported variants as new information becomes available. If a variant previously reported by Blueprint Genetics is re-classified, our laboratory will issue a follow-up statement to the original ordering healthcare provider at no additional cost, according to our latest follow-up reporting policy.
Other
- American Sickle Cell Anemia Association
- Canadian Fanconi Anemia Research Fund
- Cooley’s Anemia Foundation
- Diamond Blackfan Anemia Charity UK
- Diamond Blackfan Anemia Foundation
- Fanconi Anemia Research Fund
- Fanconi Hope
- GeneReviews - Alpha-Thalassemia
- GeneReviews - Beta-Thalassemia
- GeneReviews - Congenital Dyserythropoietic Anemia
- GeneReviews - Congenital Dyserythropoietic Anemia Type I
- GeneReviews - Diamond-Blackfan Anemia
- GeneReviews - Diamond-Blackfan anemia
- GeneReviews - EPB42-Related Hereditary Spherocytosis
- GeneReviews - Fanconi Anemia
- GeneReviews - Shwachman-Diamond Syndrome
- GeneReviews - Sickle Cell Disease
- GeneReviews - X-Linked Sideroblastic Anemia
- GeneReviews - X-Linked Sideroblastic Anemia and Ataxia
- NORD - Beta-Thalassemia
- NORD - Diamond-Blackfan anemia
- NORD - Fanconi Anemia
- NORD - Hereditary Spherocytosis
- NORD - Shwachman-Diamond Syndrome
- NORD - Sickle Cell Disease
- NORD - Sideroblastic Anemia
- Shwachman-Diamond Syndrome Foundation
- Sickle Cell Awareness Group of Ontario
- Thalassemia Support Foundation