Novel SCN1A variants in Dravet syndrome and evaluating a wide approach of patient selection.

Voltage-gated sodium channels are essential for generation and propagation of the action potential mainly in nerve and muscle cells. Causative variants in SCN1A gene which codes the main, pore-forming subunit of the channel expressed in central nervous system are associated predominantly with Dravet syndrome (DS), as well as with generalized epilepsy with febrile seizures plus (GEFS+) making it one of the most significant epilepsy gene. Our goal was to determine whether SCN1A screening is relevant in patients with a broad range of epileptic syndromes. 52 patients diagnosed with DS, generalized epilepsy with GEFS+ or similar types of epileptic syndromes were included. Sequencing of the protein coding parts of the gene complemented with MLPA analysis was carried out. One already described nonsense variant, four novel protein truncating variants and a deletion encompassing the whole SCN1A gene were revealed, all in heterozygous state. All identified variants were found in DS patients with 85.7% sensitivity, thus supporting the role of profound SCN1A gene variants in etiology of DS phenotype. No causative variants were identified in any of non-DS epileptic patients in our cohort, suggesting a minor, but not irrelevant role for SCN1A in patients with other types of childhood epilepsy.

Comparison of different DNA binding fluorescent dyes for applications of high-resolution melting analysis.

OBJECTIVES: Different applications of high-resolution melting (HRM) analysis have been adopted for a wide range of research and clinical applications. This study compares the performance of selected DNA binding fluorescent dyes for their possible application in HRM. DESIGN AND METHODS: We compared twelve dyes with basic properties considered relevant for PCR amplification and melting curve analysis. These included PCR inhibition, fluorescence intensity, the ability to generate melting curves and their effect on melting temperature (Tm). Seven of these dyes with promising properties were then evaluated for possible use in basic HRM applications; such as small amplicon genotyping, genotyping of a 1 kb insertion/deletion polymorphism, probe-based genotyping and mutation screening. RESULTS: Five dyes failed to exhibit promising properties during the first part of the study, and these were excluded from further testing. Of the remaining dyes, SYTO11, SYTO13 and SYTO16 showed better PCR inhibitory and Tm affecting properties compared to commercial HRM dyes LCGreen Plus, EvaGreen and ResoLight. Although the SYTO dyes generally exhibited good discrimination powers in HRM applications, SYTO11 and SYTO14 gave low signal intensity and lower quality results. CONCLUSIONS: Our results suggest that the best performing dyes for HRM are those commercially offered for HRM analyses. However, the performance of SYTO16 and SYTO13 was comparable to the HRM dyes in the majority of our assays, thus demonstrating that they are also quite suitable for both real-time PCR and HRM applications.

Mutation screening of the HGD gene identifies a novel alkaptonuria mutation with significant founder effect and high prevalence.

Alkaptonuria (AKU) is an autosomal recessive disorder; caused by the mutations in the homogentisate 1, 2-dioxygenase (HGD) gene located on Chromosome 3q13.33. AKU is a rare disorder with an incidence of 1: 250,000 to 1: 1,000,000, but Slovakia and the Dominican Republic have a relatively higher incidence of 1: 19,000. Our study focused on studying the frequency of AKU and identification of HGD gene mutations in nomads. HGD gene sequencing was used to identify the mutations in alkaptonurics. For the past four years, from subjects suspected to be clinically affected, we found 16 positive cases among a randomly selected cohort of 41 Indian nomads (Narikuravar) settled in the specific area of Tamil Nadu, India. HGD gene mutation analysis showed that 11 of these patients carry the same homozygous splicing mutation c.87 + 1G > A; in five cases, this mutation was found to be heterozygous, while the second AKU-causing mutation was not identified in these patients. This result indicates that the founder effect and high degree of consanguineous marriages have contributed to AKU among nomads. Eleven positive samples were homozygous for a novel mutation c.87 + 1G > A, that abolishes an intron 2 donor splice site and most likely causes skipping of exon 2. The prevalence of AKU observed earlier seems to be highly increased in people of nomadic origin.

Uninterrupted CCTG tracts in the myotonic dystrophy type 2 associated locus.

Myotonic dystrophy comprises at least two genetically distinct forms, DM1 and DM2. DM2 is caused by expansion of the (CCTG)n repeat tract in the CNBP gene. The CCTG tract is generally interrupted in healthy range alleles by GCTG, TCTG or ACTG motifs. However, alleles with uninterrupted tracts have been reported on expanded alleles, and occasionally on large-sized healthy range alleles. Therefore, these uninterrupted large-sized alleles have been considered to be possible DM2 premutations. In comparison to previous studies, we identified a wider range and a higher frequency of healthy range alleles containing uninterrupted CCTG tracts. They are most likely not restricted only to large alleles, as they constantly exist in the whole spectrum of healthy range alleles. Our results indicate that the boundary between stable and unstable uninterrupted healthy range alleles is approximately 30 CCTG repeats. This suggests a similar distribution of healthy range, premutation and mutation range uninterrupted DM2 alleles, which is also typical for DM1 alleles. Interrupted alleles, and those uninterrupted with less than approximately 30 CCTG repeats, appear stable, while instability increases with increasing length of uninterrupted parts above this threshold. Unstable DM2 premutation alleles can range from approximately 30 to 55 CCTG repeats.

High-resolution melting analysis for genotyping of the myotonic dystrophy type 1 associated Alu insertion/deletion polymorphism.

Since its introduction, high-resolution melting (HRM) analysis has been used for genotyping of various types of sequence alterations. In this study, we report the use of HRM for genotyping of the 1-kb insertion/deletion polymorphism, involving a problematic region of five consecutive Alu elements, that is associated with myotonic dystrophy type 1. We combined a three-primer polymerase chain reaction (PCR) amplification approach with HRM using two primer sets. Analyses based on curve shapes are sensitive enough to differentiate between genotypes with both primer sets. In addition, the newly designed insertion-specific primer from the second primer set equalizes the allele-specific amplicon lengths, thereby reducing the possibility of preferential amplification of shorter fragments.