Clinical and Genetic Spectrum of Myotonia Congenita in Turkish Children.

BACKGROUND: Myotonia congenita is the most common form of nondystrophic myotonia and is caused by Mendelian inherited mutations in the CLCN1 gene encoding the voltage-gated chloride channel of skeletal muscle. OBJECTIVE: The study aimed to describe the clinical and genetic spectrum of Myotonia congenita in a large pediatric cohort. METHODS: Demographic, genetic, and clinical data of the patients aged under 18 years at time of first clinical attendance from 11 centers in different geographical regions of Türkiye were retrospectively investigated. RESULTS: Fifty-four patients (mean age:15.2 years (±5.5), 76% males, with 85% Becker, 15% Thomsen form) from 40 families were included. Consanguineous marriage rate was 67%. 70.5% of patients had a family member with Myotonia congenita. The mean age of disease onset was 5.7 (±4.9) years. Overall 23 different mutations (2/23 were novel) were detected in 52 patients, and large exon deletions were identified in two siblings. Thomsen and Becker forms were observed concomitantly in one family. Carbamazepine (46.3%), mexiletine (27.8%), phenytoin (9.3%) were preferred for treatment. CONCLUSIONS: The clinical and genetic heterogeneity, as well as the limited response to current treatment options, constitutes an ongoing challenge. In our cohort, recessive Myotonia congenita was more frequent and novel mutations will contribute to the literature.

Homozygous Val6Gly Variation in PRDM5 Gene Causing Brittle Cornea Syndrome: A New Turkish Case.

Introduction: Brittle cornea syndrome (BCS) is a rare connective tissue disorder with ocular and systemic features. Extreme corneal thinning and fragility are the main hallmarks of BCS. Case Report: A 4-year-old boy presented with recurrent spontaneous corneal perforation. He had blue sclera, corneal leucoma, irregular iris, shallow anterior chamber, corneal astigmatism, and bilateral corneal thinning. He also had several systemic features including hearing loss, skin hyperelasticity, joint hypermobility, scoliosis, and umbilical hernia. A diagnosis of BCS was confirmed with molecular analysis. A homozygous c.17T>G, p.(Val6Gly) variation was identified in the PRDM5 gene. Discussion: p.(Val6Gly) variation in PRDM5 was previously reported in 2 patients with BCS. We also considered PRDM5 c.17T>G, p.(Val6Gly) variation as pathogenic based on the following features: the absence of the variation in population databases, in silico predictions, segregation analysis, and clinical signs of our patient. Extremely thin and brittle corneas lead to corneal perforation spontaneously or after minor trauma. Nearly all patients have lost their vision because of corneal rupture and scars. The key challenge in the management of BCS is the prevention of ocular rupture which relies on early diagnosis. Early diagnosis allows for taking prompt measures to prevent ocular rupture.

YIF1B-related Kaya-Barakat-Masson Syndrome: Report of a new patient and literature review.

Kaya-Barakat-Masson syndrome (KABAMAS) is a recently identified severe neurodevelopmental disorder characterized by severe global developmental delay, epilepsy, movement disorder, epilepsy, and microcephaly. KABAMAS is caused by bi-allelic variants in the YIF1B gene which encodes a trafficking protein involved in the anterograde traffic from the endoplasmic reticulum to the cell membrane including neural cells in association with other trafficking proteins and also Golgi apparatus morphology. That's why clinical overlapping between KABAMAS and golgipathies isn't surprising. It is a rare condition with only 24 patients reported to date. Here we described a 5.5-year-old boy presenting with severe global developmental delay, epileptic encephalopathy, microcephaly, dystonia, spasticity, blindness, feeding difficulties, respiratory failure, and dysmorphic features. Whole exome sequencing identified homozygous splice site variation (NM_001039672.3: c.297+1G > A) in the YIF1B gene. This splice site variant is rare in the general population (gnomAD Variant allele fraction (VAF): 0.0007%, 2 heterozygotes, 0 homozygotes) and has not previously been associated with the disease. Multiple in silico tools predict a deleterious effect of this splice site change. Considering the points mentioned above, we have considered the detected variant as pathogenic according to guidelines in light of current knowledge. By reporting a new case with the homozygous YIF1B splice site variant we provide further evidence to clinical and molecular data of this recently recognized severe neurodevelopmental disorder. We further emphasize that trafficking errors should be considered as an underlying mechanism in undiagnosed severe neurodevelopmental disorders.

Comprehensive Genetic Analysis of RASopathy in the Era of Next-Generation Sequencing and Definition of a Novel Likely Pathogenic >KRAS Variation.

Introduction: Germline pathogenic variations of the genes encoding the components of the Ras-MAPK pathway are found to be responsible for RASopathies, a clinically and genetically heterogeneous group of diseases. In this study, we aimed to present the results of patients genetically investigated for RASopathy-related mutations in our Genetic Diagnosis Center. Methods: The results of 51 unrelated probands with RASopathy and 4 affected relatives (31 male, 24 female; mean age: 9.327 ± 8.214) were included in this study. Mutation screening was performed on DNA samples from peripheral blood of the patients either by Sanger sequencing of PTPN11 hotspot regions (10/51 probands), or by a targeted amplicon next-generation sequencing panel (41/51 probands) covering the exonic regions of BRAF, CBL, HRAS, KRAS, LZTR1, MAP2K1, MAP2K2, NF1, NRAS, PTPN11, RAF1, RASA2, RIT1, SHOC2, SOS1, SOS2, SPRED1, and KAT6B genes. Results: Pathogenic/likely pathogenic variations found in 22 out of 51 probands (43.13%) and their 4 affected family members were located in PTPN11, BRAF, KRAS, NF1, RAF1, SOS1, and SHOC2 genes. The c.148A>C (p.Thr50Pro) variation in the KRAS gene was a novel variant detected in a sibling in our patient cohort. We found supportive evidence for the pathogenicity of the NF1 gene c.5606G>T (p.Gly1869Val) variation which we defined in an affected boy who inherited the mutation from his affected father. Conclusion: Although PTPN11 is the most frequently mutated gene in our patient cohort, as in most previous reports, different mutation distribution among the other genes studied motivates the use of a next-generation sequencing gene panel including the possible responsible genes.

Targeted High-Throughput Sequencing Analysis Results of Osteogenesis Imperfecta Patients from Different Regions of Turkey.

Objective: Osteogenesis imperfecta (OI) includes a group of disorders characterized by susceptibility to bone fractures with different severities. The increasing number of genes that may underlie the disorder, along with the broad phenotypic spectrum that overlaps with other skeletal diseases, provided a compelling case for the use of high-throughput sequencing (HTS) technology as an aid to OI diagnoses. The aim of this analysis was to present the data from our 5-year targeted HTS results, that includes the reporting of 9 novel and 24 known mutations, found in OI patients, from 5 different regions of Turkey. Materials and Methods: We performed a retrospective cross-sectional study, reporting the HTS results of 43 patients (23 female and 20 male; mean age: 9.5 years), directed to our center with a suspicion of OI between February 2015 and May 2020. Genetic analyses were also performed for 24 asymptomatic parents to aid the segregation analyses. We utilized an HTS panel targeting the coding regions of 57 genes associated with a reduction, increase, or abnormal development of bone mineralization. In addition, we sequenced the entire coding region of the IFITM5 gene through HTS. Results: Thirty-nine patients had at least one pathogenic/likely pathogenic variation (90.69%) in the COL1A1 (56.41%), COL1A2 (20.51%), FKBP10 (7.7%), P3H1 (5.13%), IFITM5 (5.13%), CTRAP (2.56%), or TMEM38B (2.56%) genes. Nine of the determined pathogenic/likely pathogenic variations were novel. The recurrent pathogenic mutations were c.1081C>T (p.Arg361Ter) (3/43), c.1405C>T (p.Arg469Ter) (2/43), and c.3749del (p.Gly1250AlafsTer81) in COL1A1 gene, along with c.-14C>T variation in the 5'UTR of the IFITM5 gene (2/43) and the c.890_897dup variation in the FKBP10 gene (2/43). Three out of 43 patients were carrying at least one additional variant of unknown significance, highlighting the importance of a multigene panel approach and segregation analyses. Conclusion: We suggest that a targeted HTS panel is a feasible tool for genetic diagnosis of OI in patients.

Cardiofaciocutaneous Syndrome Phenotype in a Case with de novo KRAS Pathogenic Variant.

Cardiofaciocutaneous (CFC) syndrome is one of the developmental disorders caused by a dysregulation of the Ras/mitogen-activated protein kinase (MAPK) pathway. RASopathies share overlapping clinical features, making the diagnosis challenging, especially in the newborn period. The majority of CFC syndrome cases arise by a mutation in the BRAF, MAP2K1, MAP2K2, or (rarely) KRAS genes. Germline KRAS mutations are identified in a minority of CFC and Noonan syndrome cases. Here, we describe a patient with a KRAS mutation presenting with a CFC syndrome phenotype. The female patient was referred for genetic testing because of congenital exophthalmos. Her facial appearance is distinctive with a coarse face, exophthalmos, ptosis, downslanting palpebral fissures, hypertelorism, deep philtrum, downturned corners of the mouth, and a short neck. She suffered from feeding difficulties, poor weight gain, and developmental delay. The sequencing of the genes involved in the MAPK pathway (PTPN11, SOS1, RAF1, KRAS, NRAS, MAP2K1, SHOC2, CBL, and SPRED1) identified a heterozygous de novo NM_004985.4:c.173C>T (p.Thr58Ile) in the KRAS gene. Germline KRAS mutations have been identified in approximately 2% of the reported NS cases and less than 5% of the reported CFC syndrome cases. Because CFC and Noonan syndrome share clinical overlapping features, the phenotype caused by KRAS mutations is often difficult to assign to one of the 2 entities. The mutation that we detected in our patient was previously reported in a patient with an Noonan syndrome phenotype. However, our patient predominantly exhibits CFC clinical features. In our case, coarse facial appearance and severe developmental delay help discriminate CFC from Noonan syndrome. Thus, patient follow-up, especially for delayed motor milestones suspected from RASopathies, is important for the discrimination of overlapping conditions as in the abovementioned syndromes.