Intended purpose
The SALSA MLPA Probemix P114 Long-QT is an in vitro diagnostic (IVD)
1 or research use only (RUO) semi-quantitative assay
2 for the detection of deletions or duplications in the
KCNQ1,
KCNH2,
KCNE1,
KCNE2 and
KCNJ2 genes in order to confirm a potential cause for and clinical diagnosis of congenital Long-QT syndrome (LQTS) types, 1, 2, 5, 6 and 7, respectively. In addition, this probemix can be used to confirm a potential cause for and clinical diagnosis of Jervell Lange-Nielsen syndrome (JLNS); a recessive form of LQTS associated with mutations in
KCNQ1 or
KCNE1. P114 Long-QT can also be used for molecular genetic testing of at-risk family members. This assay is for use with human DNA extracted from peripheral whole blood specimens.
Copy number variations (CNVs) detected with P114 Long-QT should be confirmed with a different technique. In particular, CNVs detected by only a single probe always require confirmation by another method. Most defects in the in
KCNQ1,
KCNH2,
KCNE1,
KCNE2 and
KCNJ2 genes are point mutations, none of which will be detected by MLPA. It is therefore recommended to use this assay in combination with sequence analysis.
Assay results are intended to be used in conjunction with other clinical and diagnostic findings, consistent with professional standards of practice, including confirmation by alternative methods, clinical genetic evaluation, and counselling, as appropriate. The results of this test should be interpreted by a clinical molecular geneticist or equivalent.
This device is not intended to be used for standalone diagnostic purposes, pre-implantation or prenatal testing, newborn or population screening, or for the detection of, or screening for, acquired or somatic genetic aberrations. This assay is not for use with DNA extracted from dried blood spots.
1 Please note that this probemix is for in vitro diagnostic (IVD) use in the countries specified at the end of this product description.
2 To be used in combination with a SALSA MLPA Reagent Kit and Coffalyser.Net analysis software.
Clinical background
Congenital Long-QT Syndrome (LQTS) is a hereditary disease that predisposes patients to cardiac arrhythmias, which can result in recurrent syncopes, seizure and sudden death. LQTS patients are electrocardiographically characterized by a prolonged QT interval resulting in a predisposition to develop the ventricular tachycardia
torsade de pointes. The cumulative mortality is 6-8% before the age of 40, and therefore it is a leading cause of sudden death in young people. LQTS occurs in an estimated 1:2500 live births and is generally caused by mutations in cardiac sodium or potassium channel genes which result in the prolongation of the ventricular action potential. LQTS can be diagnosed based on prolonged QT intervals and/or abnormal T-waves in an ECG. There are presently 15 types of LQTS known, each linked to a distinct gene. The most common causes of LQTS are mutations in the genes
KCNQ1,
KCNH2, and
SCN5A. Generally, LQTS is inherited in an autosomal dominant fashion but some exceptions are discussed below. LQTS is also referred to as Romano-Ward syndrome (RWS).
40-55% of LQTS patients have type 1; an autosomal dominant disease caused by defects in the
KCNQ1 gene. Mutations in
KCNQ1 are not only associated with long QT syndrome: homozygous or compound heterozygous mutations in
KCNQ1 are associated with the recessive disorder Jervell and Lange-Nielsen syndrome (JLNS). Patients with JLNS present a much more severe phenotype. They have more extended long-QT intervals and suffer from sensorineural hearing loss. 50% of patients with this syndrome have cardiac events before the age of three and more than half of untreated children die before the age of 15.
30-45% of LQTS patients have LQTS type 2, which is also autosomal dominant and caused by defects in the
KCNH2 gene. <1% of LQTS patients have type 5 which is associated with
KCNE1; and ~1% have type 6, which is associated with
KCNE2. Both types are autosomal dominant traits.
KCNE1 and
KCNE2 are located closely together on chromosome 21q22. As of yet, no exon CNVs or whole gene deletions/duplications of
KCNE1 and
KCNE2 have been found in LQTS patients (Williams et al. 2015). Like
KCNQ1, homozygous or compound heterozygous mutations in
KCNE1 are associated with JLNS. LQTS type 7, also autosomal dominant, is associated with mutations in
KCNJ2. Less than 1% of LQTS patients have this type, but there is evidence that CNVs of
KCNJ2 occur in LQTS patients (Marquis-Nicholson et al. 2014). LQTS type 7 is also known as Andersen-Tawil syndrome. Besides a long-QT interval and ventricular arrhythmias, these patients experience periodic paralysis due to flaccid muscle weakness and can have a variety of congenital or developmental abnormalities including low-set ears, widely spaced eyes, small mandible, fifth-digit clinodactyly, syndactyly, short stature, scoliosis and in some cases mental retardation.
Notably, 5-10% of LQTS patients have type 3, which is associated with gain-of-function variants of the
SCN5A gene. All known gain-of-function mutations are point mutations, which cannot be detected with MLPA. Because CNVs in
SCN5A are not expected to cause LQTS, no probes for this gene are included in this probemix. Loss-of-function variants in
SCN5A result in a different disease: Brugada syndrome, for which the SALSA MLPA Probemix P108 is available.
More information on LQTS can be found here:
https://www.ncbi.nlm.nih.gov/books/NBK1129/.
Probemix content
The SALSA MLPA Probemix P114-C1 Long-QT contains 52 MLPA probes with amplification products between 124 and 500 nt. This includes 18 probes for
KCNQ1, 16 probes for
KCNH2, three probes for
KCNJ2, four probes for
KCNE1, and two probes for
KCNE2. In addition, nine reference probes are included that detect autosomal chromosomal locations. Complete probe sequences and the identity of the genes detected by the reference probes are available online (
www.mrcholland.com).
This probemix contains nine quality control fragments generating amplification products between 64 and 105 nt: four DNA Quantity fragments (Q-fragments), two DNA Denaturation fragments (D-fragments), one Benchmark fragment, and one chromosome X and one chromosome Y-specific fragment. More information on how to interpret observations on these control fragments can be found in the MLPA General Protocol and online at
www.mrcholland.com.