LAMA2 mRNA processing alterations generate a complete deficiency of laminin-alpha2 protein and a severe congenital muscular dystrophy.

An increasing number of genomic variations are no more regarded as harmless changes in protein coding sequences or as genetic polymorphisms. Studying the impact of these variations on mRNA metabolism became a central issue to better understand the biological significance of disease. We describe here a severe congenital muscular dystrophy (CMD) with lumbar scoliosis and respiratory complications in a patient, who died at the age of 10. Despite a poor linkage to any form of CMD, total deficiency of laminin-alpha2 rather suggested the occurrence of an MDC1A form. Extensive analysis of LAMA2 gene revealed two novel mutations: a (8007delT) frameshift deletion in exon 57, and a de novo 7nt deletion in intron 17. Using an ex vivo approach, we provided strong evidence that the intron mutation is responsible for complete exon 17 skipping. The mutations are in trans and they each generate a nonsense mRNA potentially elicited to degradation by NMD. We further discuss the impact of mRNA alterations on the subtle phenotypic discrepancies.

Molecular prenatal diagnosis of muscular dystrophies in Tunisia and postnatal follow-up role.

We undertook in this study the first successful prenatal diagnoses of MDC1A and LGMD2C forms in Africa, with a subsequent postnatal clinical follow-up of the newborns. Genetic and molecular studies were performed on cultured amniotic fluid cells after exclusion of maternal cell contamination. Immunofluorescence on the patients' muscle biopsies was performed so as to study the expression of muscular laminins. Results showed that normal and affected fetuses were diagnosed according to the presence or the absence of the responsible mutation in LAMA2 or SGCG genes. Postnatal molecular and clinical outcome was concordant with all prenatal diagnoses. However, a patient with MDC1A form of congenital muscular dystrophy who was diagnosed as affected was normal at birth, and developed later clinical features different from those observed in his severely affected elder brother. This intrafamilial clinical variability in two siblings occurring with the same mutation in LAMA2 gene emphasizes the importance of the postnatal follow-up in the confirmation of prenatal diagnosis, and suggests that other genetic or epigenetic factors can monitor the course of the MDC1A form.

Severe MDC1A congenital muscular dystrophy due to a splicing mutation in the LAMA2 gene resulting in exon skipping and significant decrease of mRNA level.

Congenital muscular dystrophies (CMDs) are a clinically and genetically heterogeneous group of neuromuscular disorders, with autosomal recessive inheritance. We report a patient with severe congenital muscular dystrophy and total deficiency in the laminin alpha2 chain. Genetic analyses showed a linkage to the MDC1A locus for the patient's family, and DNA sequencing revealed in the propositus of a new homozygous mutation in the donor splice site of intron 58 of the LAMA2 gene. RT-PCR experiments performed on total RNA from a patient's muscle biopsy showed a complete skipping of exon 58 in LAMA2 cDNA and a significant decrease in the LAMA2 mRNA level. This exon skipping altered the open reading frame of the mutant transcript and generated a premature termination codon (PTC) within exon 59, which potentially elicits the nonsense mRNA to degradation by NMD (nonsense-mediated mRNA decay). However, the residual exon 58-lacking mRNA could potentially be translated, and the resulting truncated alpha2 chain would lack its LG4 and LG5 domains that are involved in binding with alpha-dystroglycan. These results demonstrate the utility of mRNA analysis to understand the mutation primary impact and the disease phenotype in the patients.

Evaluation of the effect of c.2946+1G>T mutation on splicing in the SCN1A gene.

Mutations in the SCN1A gene have commonly been associated with a wide range of mild to severe epileptic syndromes. They generate a wide spectrum of phenotypes ranging from the relatively mild generalized epilepsy with febrile seizures plus (GEFS+) to other severe epileptic encephalopathies, including myoclonic epilepsy in infancy (SMEI), cryptogenic focal epilepsy (CFE), cryptogenic generalized epilepsy (CGE) and a distinctive subgroup termed as severe infantile multifocal epilepsy (SIMFE). The present study was undertaken to investigate the potential effects of a transition in the first nucleotide at the donor splice site of intron 15 of the SCN1A gene leading to CGES. Functional analyses using site-directed mutagenesis by PCR and subsequent ex-vivo splicing assays, revealed that the c.2946+1G>T mutation lead to a total skipping of exon 15. The exclusion of this exon did not alter the reading frame but induced the deletion of the amino acids (853 Leu -971 Val) which are a major part in the fourth, fifth and sixth transmembrane segments of the SCN1A protein. The theoretical implications of the splice site mutations predicted with the bioinformatic tool human splice finder were investigated and compared with the results obtained by the cellular assay.

Slight variations in the SC35 ESE sequence motif among human chromosomes: a computational approach.

Gene expression is initiated by the binding of transcription factors to cis-regulatory modules such as enhancer elements binding to the Serine/Arginine proteins. Recently, we noticed an increased ability to identify the location as well as the motifs of enhancers using genome-wide information on spliceosomal factor occupancy, cofactor recruitment and chromatin modifications. In this study, we have undertaken a large-scale genomic analysis in an attempt to uncover if the exonic splicing enhancer motif binding to the SC35 and the SRp40 SR proteins is conserved among several groups of human genes. For the SRp40, the results showed that the ESE consensus is conserved among human genes. Concerning the SC35 SR protein, results showed an ESE motif conserved among human tissues and between different levels of muscular cell differentiation and within the same chromosome. However, this motif displays subtle discrepancies between genes localized in different chromosomes. These results emphasize the presence of different translational isoforms of the SFRS2 gene encoding for the SC35, or different post-translational protein maturations in different chromosomes, confirming that chromatin structure is another layer of gene regulation. These links between chromatin pattern and splicing give further mechanistic support to functional interconnections between splicing, transcription and chromatin structure, and raise the intriguing possibility of the existence of a memory for splicing patterns to be inherited through epigenetic modifications.

An Unusual Case of Peters Plus Syndrome with Sexual Ambiguity and Absence of Mutations in the B3GALTL Gene.

BACKGROUND: Peters Plus syndrome (MIM 261540) is a rare autosomal recessive condition characterized by ocular defects (typically Peters anomaly) and other systemic major/minor abnormalities. Mutations in the B3GALTL gene encoding the ß-1,3-glucosyltransferase have been found in virtually all patients with typical Peters Plus syndrome. CASE PRESENTATION: We report here a female patient with severe manifestations of Peters Plus syndrome including facial dysmorphism and bilateral corneal opacity associated with left renal pyelo-calicial dilatation and sexual ambiguity. Total sequencing of the B3GALTL gene revealed no mutation in the patient. CONCLUSION: To our knowledge, sexual ambiguity has not previously been reported in Peters Plus syndrome so far, and renal malformation is also apparently rare in the syndrome.

First functional analysis of a novel splicing mutation in the B3GALTL gene by an ex vivo approach in Tunisian patients with typical Peters plus syndrome.

Peters plus syndrome is a rare recessive autosomal disorder comprising ocular anterior segment dysgenesis, short stature, hand abnormalities and distinctive facial features. It was related only to mutations in the B3GALTL gene in the 13q12.3 region. In this study, we undertook the first functional analysis of a novel c.597-2 A>G splicing mutation within the B3GALTL gene using an ex-vivo approach. The results showed a complete skipping of exon 8 in the B3GALTL cDNA, which altered the open reading frame of the mutant transcript and generated a PTC within exon 9. This finding potentially elicits the nonsense mRNA to degradation by NMD (nonsense-mediated mRNA decay). The theoretical consequences of splice site mutations, predicted with the bioinformatics tool Human Splice Finder, were investigated and evaluated in relation to ex-vivo results. The findings confirmed the key role played by the B3GALTL gene in typical Peters-plus syndromes and the utility of mRNA analysis to understand the primary impacts of this mutation and the phenotype of the disease.

Two Tunisian patients with Peters plus syndrome harbouring a novel splice site mutation in the B3GALTL gene that modulates the mRNA secondary structure.

Peters plus syndrome is an autosomal recessive rare disorder comprising ocular anterior segment dysgenesis, short stature, hand abnormalities, distinctive facial features, and often other major/minor additional defects. Peters plus syndrome is related to mutations in the B3GALTL gene with only seven recently reported mutations, leading to the inactivation of the B1, 3-glucosyltransferase. In this study, we screened the B3GALTL gene in two unrelated patients with typical Peters plus syndrome. A novel homozygous c.597-2A>G mutation was identified in both patients. Bioinformatic analyses showed that this mutation modulates the pre mRNA secondary structure of the gene, and decreases the score value related to the formation of splicing loops. Moreover, the c.597-2A>G mutation is located in a CpG Island of the B3GALTL gene, suggesting a potential epigenetic role of this position including gene's methylation and regulation. These data confirm an important role of the B3GALTL gene test that provides diagnosis confirmation and improves genetic counseling for the families.

Subtle discrepancies of SF2/ASF ESE sequence motif among human tissues: A computational approach.

The intron removal during the pre-mRNA splicing in higher eukaryotes requires the accurate identification of the two splice sites at the ends of the exons, or exon definition. However, the consensus sequences at the splice sites provide insufficient information to distinguish true splice sites from the large number of the false ones that populate the primary transcripts. Additional information is provided by cis-acting regulatory sequences that serve to enhance or repress splicing, and that may be exonic or intronic in nature: the splicing enhancers and the splicing silencers, respectively. In this study, we tested by computational and statistical approaches if the exonic splicing enhancer motif binding to the SF2/ASF SR protein is conserved among several groups of human genes. The results showed that the SF2/ASF ESE consensus was conserved between genes within the same chromosome, within different chromosomes and between different levels of muscular cells differentiation. However, this motif displays subtle variations within the consensus sequence between genes expressed in different tissues. These results can emphasize the presence of different translational isoforms of the SFRS1 gene encoding for the SF2/ASF, or different post-translational protein maturations in different tissues. This tissular discrepancy can also account for the alternative splicing of several genes between tissues.

Novel sequence variations in LAMA2 andSGCG genes modulating cis-acting regulatory elements and RNA secondary structure.

In this study, we detected new sequence variations in LAMA2 and SGCG genes in 5 ethnic populations, and analysed their effect on enhancer composition and mRNA structure. PCR amplification and DNA sequencing were performed and followed by bioinformatics analyses using ESEfinder as well as MFOLD software. We found 3 novel sequence variations in the LAMA2 (c.3174+22_23insAT and c.6085 +12delA) and SGCG (c. (*) 102A/C) genes. These variations were present in 210 tested healthy controls from Tunisian, Moroccan, Algerian, Lebanese and French populations suggesting that they represent novel polymorphisms within LAMA2 and SGCG genes sequences. ESEfinder showed that the c. (*) 102A/C substitution created a new exon splicing enhancer in the 3'UTR of SGCG genes, whereas the c.6085 +12delA deletion was situated in the base pairing region between LAMA2 mRNA and the U1snRNA spliceosomal components. The RNA structure analyses showed that both variations modulated RNA secondary structure. Our results are suggestive of correlations between mRNA folding and the recruitment of spliceosomal components mediating splicing, including SR proteins. The contribution of common sequence variations to mRNA structural and functional diversity will contribute to a better study of gene expression.

Novel sequence variations in LAMA2 and SGCG genes modulating cis-acting regulatory elements and RNA secondary structure

In this study, we detected new sequence variations in LAMA2 and SGCG genes in 5 ethnic populations, and analysed their effect on enhancer composition and mRNA structure. PCR amplification and DNA sequencing were performed and followed by bioinformatics analyses using ESEfinder as well as MFOLD software. We found 3 novel sequence variations in the LAMA2 (c.3174+22_23insAT and c.6085 +12delA) and SGCG (c.*102A/C) genes. These variations were present in 210 tested healthy controls from Tunisian, Moroccan, Algerian, Lebanese and French populations suggesting that they represent novel polymorphisms within LAMA2 and SGCG genes sequences. ESEfinder showed that the c.*102A/C substitution created a new exon splicing enhancer in the 3'UTR of SGCG genes, whereas the c.6085 +12delA deletion was situated in the base pairing region between LAMA2 mRNA and the U1snRNA spliceosomal components. The RNA structure analyses showed that both variations modulated RNA secondary structure. Our results are suggestive of correlations between mRNA folding and the recruitment of spliceosomal components mediating splicing, including SR proteins. The contribution of common sequence variations to mRNA structural and functional diversity will contribute to a better study of gene expression.