Precise pre-mRNA splicing, essential for appropriate protein translation, depends on the presence of consensus “cis” sequences that define exon-intron boundaries and regulatory sequences recognized by splicing machinery. Point mutations at these consensus sequences can cause improper exon and intron recognition and may result in the formation of an aberrant transcript of the mutated gene. The splicing mutation may occur in both introns and exons and disrupt existing splice sites or splicing regulatory sequences (intronic and exonic splicing silencers and enhancers), create new ones, or activate the cryptic ones. Usually such mutations result in errors during the splicing process and may lead to improper intron removal and thus cause alterations of the open reading frame. Recent research has underlined the abundance and importance of splicing mutations in the etiology of inherited diseases. The application of modern techniques allowed to identify synonymous and nonsynonymous variants as well as deep intronic mutations that affected pre-mRNA splicing. The bioinformatic algorithms can be applied as a tool to assess the possible effect of the identified changes. However, it should be underlined that the results of such tests are only predictive, and the exact effect of the specific mutation should be verified in functional studies. This article summarizes the current knowledge about the “splicing mutations” and methods that help to identify such changes in clinical diagnosis.
The original version on this paper contained an error. The first names and last names of Anna Abramowicz and Monika Gos are inadvertently interchanged and are incorrectly displayed in indexing sites. The correct names are presented above. Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Neurofibromatosis type I (NF1) is multisystemic disease characterized by pigmentary skin changes, increased susceptibility to tumor formation, neurological deficits and skeletal defects. The disease is a monogenic, autosomal dominant disorder, caused by the presence of mutations in the NF1 gene encoding neurofibromin - a multifunctional regulatory protein. The basic function of neurofibromin protein is modulation of the RAS protein activity necessary for regulation of cell proliferation and differentiation by the RAS/MAPK and RAS/PI3K/AKT signal transduction pathways. In addition, neurofibromin is a regulator of adenylate cyclase activity and therefore may interfere with signaling by the cAMP/protein kinase A pathway that regulates cell cycle progression or learning and memory formation processes. Neurofibromin also interacts with many other proteins that are engaged in intracellular transport (tubulin, kinesin), actin cytoskeleton rearrangements (LIMK2, Rho and Rac) or morphogenesis of neural cells (syndecans, CRMP proteins). The activity of neurofibromin is strictly regulated by the expression of different NF1 mRNA isoforms depending on tissue type or period in organism development, the protein localization, posttranslational modifications (phosphorylation, ubiquitination) or interactions with other proteins (e.g. 14-3-3). The fact that neurofibromin is engaged in many cellular processes has significant consequences when the proper protein functioning is impaired due to decreased protein level or activity. It affects the normal cell function and results in disturbances of organism development that lead to the occurrence of clinical signs specific for NF1. In the article, the basic neurofibromin functions are presented in the context of the molecular pathogenesis of NF1.
Cardio-facio-cutaneous syndrome (CFCS), a rare congenital disorder of RASopathies, displays high phenotypic variability. Complications during pregnancy and in the perinatal period are commonly reported. Polyhydramnios is observed in over half of pregnancies and might occur with fetal macrocephaly, macrosomia, and/or heart defects. Premature birth is not uncommon and any complications like respiratory insufficiency, edema, and feeding difficulties are present and might delay accurate clinical diagnosis. Besides neonatal complications, CFCS newborns and later infants have distinctive dysmorphic features usually accompanied by neurological (hypotonia with motor delay, neurocognitive delay) findings. Also, heart defects usually present at birth. Herein, we present the case of a female baby born prematurely from a pregnancy complicated with polyhydramnios, presenting at birth with craniofacial features typical for RASopathies, heart defects, neurological abnormalities, and hyperkeratosis unusual for a neonatal period. Due to the presence of a heart defect and other complications related to premature birth, the course of the disease was severe with a fatal outcome at the age of 9 months. The RASopathy, particularly CFCS, clinical diagnosis was confirmed and de novo p.Phe57Ile mutation in MAP2K2 was identified.
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