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Long QT Syndrome and Jervell and Lange-Nielsen Syndrome via KCNE1 Gene Sequencing with CNV Detection

  • Summary and Pricing
  • Clinical Features and Genetics
  • Citations
  • Methods
  • Ordering/Specimens
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TEST METHODS

Sequencing with CNV

Test Code Test Copy GenesPriceCPT Code Copy CPT Codes
9193 KCNE1$890 81479,81479 Add to Order
Pricing Comments

Our favored testing approach is exome based NextGen sequencing with CNV analysis. This will allow cost effective reflexing to PGxome or other exome based tests. However, if full gene Sanger sequencing is desired for STAT turnaround time, insurance, or other reasons, please see link below for Test Code, pricing, and turnaround time information. If the Sanger option is selected, CNV detection may be ordered through Test #600.

For Sanger Sequencing click here.
Targeted Testing

For ordering sequencing of targeted known variants, please proceed to our Targeted Variants landing page.

Turnaround Time

The great majority of tests are completed within 26 days.

Clinical Sensitivity

Pathogenic variants have been found in either KCNQ1 or KCNE1 in 94% of individuals with clinical JLNS undergoing molecular testing. The pathogenic variants may be located in all coding exons. Current experience indicates that 33% are compound heterozygotes (Schwartz et al 2006). About 90 percent of Jervell and Lange-Nielsen syndrome cases are caused by mutations in the KCNQ1 gene. KCNE1 mutations are responsible for the remaining 10 percent of cases (Schwartz et al. 2006; Tyson et al. 2000). Splawski et al (2000) screened 262 unrelated LQTS patients for causative variants in 5 genes: KVLQT1, HERG, SCN5A, KCNE1 and KCNE2. They reported causative variants in 68% of their subjects. Of these, 45% were in HERG, 42% in KVLQT1, 8% in SCN5A, 3% in KCNE1 and 2% in KCNE2.

Gross deletions and duplications in the KCNE1 gene have not been reported in patients with Long QT syndrome and Jervell and Lange-Nielsen syndrome (Human Gene Mutation Database).

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Clinical Features
Long QT syndrome (LQTS) is a heritable channelopathy characterized by an exceedingly prolonged cardiac repolarization that may trigger ventricular arrhythmias (torsade de pointes), recurrent syncopes, seizure, or sudden cardiac death (SCD) (Cerrone et al. 2012). The incidence of LQTS has been estimated between 1 in 2500 and 1 in 7000 in the general population.  LQTS can manifest with syncope and cardiac arrest that is commonly triggered by adrenergic stress, often precipitated by emotion or exercise. Roughly 10% to 15% of patients experience symptoms at rest or during the night (Schwartz et al. 2001). The mean age of onset of symptoms is 12 years, and earlier onset usually is associated with a more severe form of the disease (Priori et al 2004). Inherited LQTS occurs due to mutations in multiple genes such as KCNQ1 (LQT1), KCNH2 (LQT2), SCN5A (LQT3), ANK2(LQT4), KCNE1 (LQT5), KCNE2 (LQT6), KCNJ2(LQT7), CACNA1C(LQT8), CAV3(LQT9), SCN4B(LQT10), AKAP9(LQT11), SNTA1(LQT12) and KCNJ5 (LQT13), but it can also be acquired (acquired LQTS), usually as a result of pharmacological therapy. A small percentage of cases of LQTS occur in people who have an underlying variation in the KCNE1 gene.

Jervell and Lange-Nielsen Syndrome (JLNS) is characterized by congenital profound bilateral sensorineural hearing loss and long QTc, usually greater than 500 msec. If untreated, the irregular heartbeats can lead to life-threatening ventricular arrhythmias, and a high risk of sudden cardiac death (Schwartz et al. 2006). Jervell and Lange-Nielsen syndrome prevalence remains largely unknown due to the high mortality in infancy and lack of comprehensive neonatal screening methods. KCNQ1 or KCNE1 are the only two genes in which pathogenic variants are known to cause JLNS. JLNS is usually detected during early childhood and is inherited as an autosomal dominant genetic disorder. More than half of the untreated cases of JLNS result in death before the age of 15.
Genetics
Jervell and Lange-Nielsen Syndrome is inherited in an autosomal dominant pattern. About 90 percent of Jervell and Lange-Nielsen syndrome cases are caused by mutations in the KCNQ1 gene. KCNE1 mutations are responsible for the remaining 10 percent of cases (Schwartz et al. 2006; Tyson et al. 2000). The subtype of Jervell and Lange-Nielsen syndrome caused by mutations in the KCNQ1 gene is called JLNS1. Another  subtype,  JLNS2, is  caused by mutations in the KCNE1 gene, also known as Ward-Romano syndrome, and Long QT syndrome 5. So far, KCNE1 mutations found in JLNS are missense/nonsense (87%) and small deletion/insertion/indels (11%) (Human Gene Mutation Database).

KCNE1 (potassium voltage-gated channel, Isk-related family, member 1) belongs to the potassium channel KCNE gene family.  The KCNE1 gene regulates a potassium channel made up of proteins produced by the KCNQ1 gene. KCNE1 and KCNQ1 work together to form a potassium channel that transports positively charged potassium ions out of cells, which is critical for maintaining the normal functions of the inner ear and cardiac muscle (Crump et al. 2014).
Testing Strategy

For this Next Generation Sequencing (NGS) test, sequencing is accomplished by capturing specific regions with an optimized solution-based hybridization kit, followed by massively parallel sequencing of the captured DNA fragments. Additional Sanger sequencing is performed for regions not captured or with insufficient number of sequence reads.

For Sanger sequencing, polymerase chain reaction (PCR) is used to amplify targeted regions. After purification of the PCR products, cycle sequencing is carried out using the ABI Big Dye Terminator v.3.0 kit. PCR products are resolved by electrophoresis on an ABI 3730xl capillary sequencer. In nearly all cases, cycle sequencing is performed separately in both the forward and reverse directions.

Copy number variants (CNVs) are also detected from NGS data. We utilize a CNV calling algorithm that compares mean read depth and distribution for each target in the test sample against multiple matched controls. Neighboring target read depth and distribution and zygosity of any variants within each target region are used to reinforce CNV calls. All CNVs are confirmed using another technology such as aCGH, MLPA, or PCR before they are reported.

This test provides full coverage of all coding exons of the KCNE1 gene plus 10 bases of flanking noncoding DNA in all available transcripts along with other non-coding regions in which pathogenic variants have been identified at PreventionGenetics or reported elsewhere. We define full coverage as >20X NGS reads or Sanger sequencing.

Since this test is performed using exome capture probes, a reflex to any of our exome based tests is available (PGxome, PGxome Custom Panels).

Indications for Test
All patients with symptoms suggestive of Long QT syndrome/ Jervell and Lange-Nielsen syndrome are candidates for this test.

Gene

Official Gene Symbol OMIM ID
KCNE1 176261
Inheritance Abbreviation
Autosomal Dominant AD
Autosomal Recessive AR
X-Linked XL
Mitochondrial MT

Related Test

Name
Long QT Syndrome via SCN4B Gene Sequencing with CNV Detection

CONTACTS

Genetic Counselors
Geneticist
Citations
  • Cerrone M. et al. 2012. Circulation. Cardiovascular genetics. 5: 581-90. PubMed ID: 23074337
  • Crump SM, Abbott GW. 2014. Arrhythmogenic KCNE gene variants: current knowledge and future challenges. Front Genet 5: 3. PubMed ID: 24478792
  • Human Gene Mutation Database (Bio-base).
  • Priori SG. et al. 2004. JAMA. 292: 1341-4. PubMed ID: 15367556
  • Schwartz PJ, Spazzolini C, Crotti L, Bathen J, Amlie JP, Timothy K, Shkolnikova M, Berul CI, Bitner-Glindzicz M, Toivonen L, Horie M, Schulze-Bahr E, Denjoy I. 2006. The Jervell and Lange-Nielsen syndrome: natural history, molecular basis, and clinical outcome. Circulation 113: 783–790. PubMed ID: 16461811
  • Schwartz PJ. et al. 2001. Circulation. 103: 89-95. PubMed ID: 11136691
  • Splawski I. et al. 2000. Circulation. 102: 1178-85. PubMed ID: 10973849
  • Tyson J, Tranebjaerg L, McEntagart M, Larsen LA, Christiansen M, Whiteford ML, Bathen J, Aslaksen B, Sørland SJ, Lund O, Pembrey ME, Malcolm S, Bitner-Glindzicz M. 2000. Mutational spectrum in the cardioauditory syndrome of Jervell and Lange-Nielsen. Hum. Genet. 107: 499–503. PubMed ID: 11140949
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TEST METHODS

Exome Sequencing with CNV Detection

Test Procedure

For PGxome® we use Next Generation Sequencing (NGS) technologies to cover the coding regions of targeted genes plus 10 bases of flanking non-coding DNA in all available transcripts along with other non-coding regions in which pathogenic variants have been identified at PreventionGenetics or reported elsewhere. As required, genomic DNA is extracted from patient specimens. Patient DNA corresponding to these regions is captured using Agilent Clinical Research Exome hybridization probes. Captured DNA is sequenced on the NovaSeq 6000 using 2x150 bp paired-end reads (Illumina, San Diego, CA, USA). The following quality control metrics are generally achieved: >97% of target bases are covered at >20x, and mean coverage of target bases >120x. Data analysis and interpretation is performed by the internally developed software Titanium-Exome. In brief, the output data from the NovaSeq 6000 is converted to fastqs by Illumina Bcl2Fastq, and mapped by BWA. Variant calls are made by the GATK Haplotype caller and annotated using in house software and SnpEff. Variants are filtered and annotated using VarSeq (www.goldenhelix.com).

For Sanger sequencing, polymerase chain reaction (PCR) is used to amplify targeted regions. After purification of the PCR products, cycle sequencing is carried out using the ABI Big Dye Terminator v.3.0 kit. PCR products are resolved by electrophoresis on an ABI 3730xl capillary sequencer. In nearly all cases, cycle sequencing is performed separately in both the forward and reverse directions.

Copy number variants (CNVs) are also detected from NGS data. We utilize a CNV calling algorithm that compares mean read depth and distribution for each target in the test sample against multiple matched controls. Neighboring target read depth and distribution and zygosity of any variants within each target region are used to reinforce CNV calls. All CNVs are confirmed using another technology such as aCGH, MLPA, or PCR before they are reported.

Analytical Validity

NextGen Sequencing: As of March 2016, 6.36 Mb of sequence (83 genes, 1557 exons) generated in our lab was compared between Sanger and NextGen methodologies. We detected no differences between the two methods. The comparison involved 6400 total sequence variants (differences from the reference sequences). Of these, 6144 were nucleotide substitutions and 256 were insertions or deletions. About 65% of the variants were heterozygous and 35% homozygous. The insertions and deletions ranged in length from 1 to over 100 nucleotides.

In silico validation of insertions and deletions in 20 replicates of 5 genes was also performed. The validation included insertions and deletions of lengths between 1 and 100 nucleotides. Insertions tested in silico: 2200 between 1 and 5 nucleotides, 625 between 6 and 10 nucleotides, 29 between 11 and 20 nucleotides, 25 between 21 and 49 nucleotides, and 23 at or greater than 50 nucleotides, with the largest at 98 nucleotides. All insertions were detected. Deletions tested in silico: 1813 between 1 and 5 nucleotides, 97 between 6 and 10 nucleotides, 32 between 11 and 20 nucleotides, 20 between 21 and 49 nucleotides, and 39 at or greater than 50 nucleotides, with the largest at 96 nucleotides. All deletions less than 50 nucleotides in length were detected, 13 greater than 50 nucleotides in length were missed. Our standard NextGen sequence variant calling algorithms are generally not capable of detecting insertions (duplications) or heterozygous deletions greater than 100 nucleotides. Large homozygous deletions appear to be detectable.

Copy Number Variant Analysis: The PGxome test detects most larger deletions and duplications including intragenic CNVs and large cytogenetic events; however aberrations in a small percentage of regions may not be accurately detected due to sequence paralogy (e.g., pseudogenes, segmental duplications), sequence properties, deletion/duplication size (e.g., 1-3 exons vs. 4 or more exons), and inadequate coverage. In general, sensitivity for single, double, or triple exon CNVs is ~70% and for CNVs of four exon size or larger is >95%, but may vary from gene-to-gene based on exon size, depth of coverage, and characteristics of the region.

Analytical Limitations

Interpretation of the test results is limited by the information that is currently available. Better interpretation should be possible in the future as more data and knowledge about human genetics and this specific disorder are accumulated.

When sequencing does not reveal any heterozygous differences from the reference sequence, we cannot be certain that we were able to detect both patient alleles.

For technical reasons, the PGxome test is not 100% sensitive. Some exons cannot be efficiently captured, and some genes cannot be accurately sequenced because of the presence of multiple copies in the genome. Therefore, a small fraction of sequence variants will not be detected.

We sequence coding exons for all available transcripts plus 10 bp of flanking non-coding DNA for each exon. We also sequence other regions within or near genes in which pathogenic variants have been identified at PreventionGenetics or reported elsewhere.  Unless specifically indicated, test reports contain no information about other portions of genes.

In most cases, we are unable to determine the phase of sequence variants. In particular, when we find two likely causative mutations for recessive disorders, we cannot be certain that the mutations are on different alleles.

Our ability to detect minor sequence variants due to somatic mosaicism is limited. Sequence variants that are present in less than 50% of the patient's nucleated cells may not be detected.

Runs of mononucleotide repeats (eg (A)n or (T)n) with n >8 in the reference sequence are generally not analyzed because of strand slippage during amplification.

Unless otherwise indicated, DNA sequence data is obtained from a specific cell-type (usually leukocytes if taken from whole blood). Test reports contain no information about the DNA sequence in other cell-types.

We cannot be certain that the reference sequences are correct.

Balanced translocations or inversions are only rarely detected.

Certain types of sex chromosome aneuploidy may not be detected.  

Our ability to detect CNVs due to somatic mosaicism is limited.

We have confidence in our ability to track a specimen once it has been received by PreventionGenetics. However, we take no responsibility for any specimen labeling errors that occur before the sample arrives at PreventionGenetics.

A negative finding does not rule out a genetic diagnosis.

Genetic counseling to help to explain test results to the patients and to discuss reproductive options is recommended.

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Ordering Options


myPrevent - Online Ordering
  • The test can be added to your online orders in the Summary and Pricing section.
  • Once the test has been added log in to myPrevent to fill out an online requisition form.
REQUISITION FORM
  • A completed requisition form must accompany all specimens.
  • Billing information along with specimen and shipping instructions are within the requisition form.
  • All testing must be ordered by a qualified healthcare provider.

SPECIMEN TYPES
WHOLE BLOOD

(Delivery accepted Monday - Saturday)

  • Collect 3 ml -5 ml (5 ml preferred) of whole blood in EDTA (purple top tube) or ACD (yellow top tube). For Test #500-DNA Banking only, collect 10 ml -20 ml of whole blood.
  • For small babies, we require a minimum of 1 ml of blood.
  • Only one blood tube is required for multiple tests.
  • Ship blood tubes at room temperature in an insulated container. Do not freeze blood.
  • During hot weather, include a frozen ice pack in the shipping container. Place a paper towel or other thin material between the ice pack and the blood tube.
  • In cold weather, include an unfrozen ice pack in the shipping container as insulation.
  • At room temperature, blood specimen is stable for up to 48 hours.
  • If refrigerated, blood specimen is stable for up to one week.
  • Label the tube with the patient name, date of birth and/or ID number.

DNA

(Delivery accepted Monday - Saturday)

  • Send in screw cap tube at least 5 µg -10 µg of purified DNA at a concentration of at least 20 µg/ml for NGS and Sanger tests and at least 5 µg of purified DNA at a concentration of at least 100 µg/ml for gene-centric aCGH, MLPA, and CMA tests, minimum 2 µg for limited specimens.
  • For requests requiring more than one test, send an additional 5 µg DNA per test ordered when possible.
  • DNA may be shipped at room temperature.
  • Label the tube with the composition of the solute, DNA concentration as well as the patient’s name, date of birth, and/or ID number.
  • We only accept genomic DNA for testing. We do NOT accept products of whole genome amplification reactions or other amplification reactions.

CELL CULTURE

(Delivery preferred Monday - Thursday)

  • PreventionGenetics should be notified in advance of arrival of a cell culture.
  • Culture and send at least two T25 flasks of confluent cells.
  • Some panels may require additional flasks (dependent on size of genes, amount of Sanger sequencing required, etc.). Multiple test requests may also require additional flasks. Please contact us for details.
  • Send specimens in insulated, shatterproof container overnight.
  • Cell cultures may be shipped at room temperature or refrigerated.
  • Label the flasks with the patient name, date of birth, and/or ID number.
  • We strongly recommend maintaining a local back-up culture. We do not culture cells.
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