Synaptic defects in type I spinal muscular atrophy in human development.

Childhood spinal muscular atrophy is an autosomal recessive neuromuscular disorder caused by alterations in the Survival Motor Neuron 1 gene that triggers degeneration of motor neurons within the spinal cord. Spinal muscular atrophy is the second most common severe hereditary disease of infancy and early childhood. In the most severe cases (type I), the disease appears in the first months of life, suggesting defects in fetal development. However, it is not yet known how motor neurons, neuromuscular junctions, and muscle interact in the neuropathology of the disease. We report the structure of presynaptic and postsynaptic apparatus of the neuromuscular junctions in control and spinal muscular atrophy prenatal and postnatal human samples. Qualitative and quantitative data from confocal and electron microscopy studies revealed changes in acetylcholine receptor clustering, abnormal preterminal accumulation of vesicles, and aberrant ultrastructure of nerve terminals in the motor endplates of prenatal type I spinal muscular atrophy samples. Fetuses predicted to develop milder type II disease had a similar appearance to controls. Postnatal muscle of type I spinal muscular atrophy patients showed persistence of the fetal subunit of acetylcholine receptors, suggesting a delay in maturation of neuromuscular junctions. We observed that pathology in the severe form of the disease starts in fetal development and that a defect in maintaining the initial innervation is an early finding of neuromuscular dysfunction. These results will improve our understanding of the spinal muscular atrophy pathogenesis and help to define targets for possible presymptomatic therapy for this disease.

Polymorphisms of genes involved in homocysteine metabolism in preeclampsia and in uncomplicated pregnancies.

OBJECTIVE: To evaluate the possible relationship between preeclampsia and polymorphisms in the main genes involved in folate-homocysteine metabolism. STUDY DESIGN: Case-control study: 43 patients with preeclampsia and 122 controls without pregnancy complications. Laboratory studies: tHcy and other amino acids, folate and vitamin B(12) and polymorphisms: 677C > T and 1298A > C (MTHFR); 699C > T, 844ins68 and 1080C > T (CBS); 2756A > G (MTR); and 66G > A, IVS1+766G > A and IVS1+754A > C (MTRR). RESULTS: Plasma tHcy and folate values were significantly higher (P = 0.004 and P = 0.019), while Met/tHcy ratios were lower (P < 0.001) in the patients compared with controls. No association was observed between polymorphisms tested and preeclampsia. In the control group, four such associations were found: the 1298A > C polymorphism (MTHFR) with the ratio Met/tHcy (P = 0.014); the 699C > T polymorphism (CBS) with the ratio tHcy/SigmaAA (P = 0.013); the 2756A > G polymorphism (MTR) with tHcy (P = 0.034); and the IVS1+766G > A polymorphism (MTRR) with hyperhomocysteinemia (P = 0.012). CONCLUSION: An association between the polymorphisms analysed and preeclampsia could not be demonstrated.

Decay in survival motor neuron and plastin 3 levels during differentiation of iPSC-derived human motor neurons.

Spinal muscular atrophy (SMA) is a neuromuscular disease caused by mutations in Survival Motor Neuron 1 (SMN1), leading to degeneration of alpha motor neurons (MNs) but also affecting other cell types. Induced pluripotent stem cell (iPSC)-derived human MN models from severe SMA patients have shown relevant phenotypes. We have produced and fully characterized iPSCs from members of a discordant consanguineous family with chronic SMA. We differentiated the iPSC clones into ISL-1+/ChAT+ MNs and performed a comparative study during the differentiation process, observing significant differences in neurite length and number between family members. Analyses of samples from wild-type, severe SMA type I and the type IIIa/IV family showed a progressive decay in SMN protein levels during iPSC-MN differentiation, recapitulating previous observations in developmental studies. PLS3 underwent parallel reductions at both the transcriptional and translational levels. The underlying, progressive developmental decay in SMN and PLS3 levels may lead to the increased vulnerability of MNs in SMA disease. Measurements of SMN and PLS3 transcript and protein levels in iPSC-derived MNs show limited value as SMA biomarkers.

Evaluation of fetal nuchal translucency in 98 pregnancies at risk for severe spinal muscular atrophy: possible relevance of the SMN2 copy number.

OBJECTIVE: To study fetal nuchal translucency (NT) thickness as a possible early marker in fetuses at risk for severe spinal muscular atrophy (SMA). To investigate the significance of the survival motor neuron (SMN) 2 gene copy number in affected fetuses. METHODS: We performed 2D-ultrasound in 98 pregnancies at risk for SMA, all of which underwent prenatal molecular testing of the SMN1 gene. Crown-rump length (CRL) and NT measurements were obtained in all cases before chorionic villus sampling. Fetuses were diagnosed as healthy, carriers or affected according to the SMN1 molecular testing results. SMN2 copies were also tested in all affected fetuses. RESULTS: Nineteen fetuses were predicted to be affected due to the absence of the SMN1 gene, 18 of which had two SMN2 copies. Mean CRL and NT values did not differ between healthy, carrier and affected fetuses. In the remaining affected case who had only one SMN2 copy, the ultrasound examination showed a NT value of 4.98 mm and findings compatible with hypoplastic left heart. CONCLUSIONS: Most affected SMA fetuses have normal NT values. Our findings support the idea that SMN2 copy number in SMA fetuses is relevant for the development of congenital heart defects and increased NT values.

Exome sequencing identifies KIAA1377 and C5orf42 as susceptibility genes for monomelic amyotrophy.

Precise topographic localization, predominance in males mostly of Asian origin, and existence of some familial cases suggest a genetic background for monomelic amyotrophy. To identify susceptibility genes for monomelic amyotrophy, we performed whole-exome sequencing of four unrelated patients with monomelic amyotrophy and detected a total of 45 novel nonsynonymous single-nucleotide polymorphisms as unique variants to monomelic amyotrophy compared to control exomes. Genetic association analysis showed significant association with monomelic amyotrophy in the Gly668Ser variant of the KIAA1377 gene (odds ratio=4.62, P-value=0.0040) and the Pro1794Leu variant of the C5orf42 gene (odds ratio=4.63, P-value=0.0040). Moreover, the combination of two variants increased the risk of monomelic amyotrophy (P=1.4×10(-5), OR=61.69, 95% confidence interval=9.62-394.94, in case of combination of two heterozygotes). These data suggest that KIAA1377 and C5orf42 synergistically play a role as susceptibility genes for monomelic amyotrophy.

Treatment of spinal muscular atrophy cells with drugs that upregulate SMN expression reveals inter- and intra-patient variability.

Spinal muscular atrophy (SMA) is a genetic neuromuscular disorder caused by mutations in the SMN1 gene. The homologous copy (SMN2) is always present in SMA patients. SMN1 gene transcripts are usually full-length (FL), but exon 7 is spliced out in a high proportion of SMN2 transcripts (delta7) (Δ7). Advances in drug therapy for SMA have shown that an increase in SMN mRNA and protein levels can be achieved in vitro. We performed a systematic analysis of SMN expression in primary fibroblasts and EBV-transformed lymphoblasts from seven SMA patients with varying clinical severity and different SMN1 genotypes to determine expression differences in two accessible tissues (skin and blood). The basal expression of SMN mRNA FL and Δ7 in fibroblasts and lymphoblasts was analyzed by quantitative real-time PCR. The FL-SMN and FL/Δ7 SMN ratios were higher in control cells than in patients. Furthermore, we investigated the response of these cell lines to hydroxyurea, valproate and phenylbutyrate, drugs previously reported to upregulate SMN2. The response to treatments with these compounds was heterogeneous. We found both intra-patient and inter-patient variability even within haploidentical siblings, suggesting that tissue and individual factors may affect the response to these compounds. To optimize the stratification of patients in clinical trials, in vitro studies should be performed before enrolment so as to define each patient as a responder or non-responder to the compound under investigation.

Accuracy of marker analysis, quantitative real-time polymerase chain reaction, and multiple ligation-dependent probe amplification to determine SMN2 copy number in patients with spinal muscular atrophy.

Spinal muscular atrophy (SMA) is an autosomal recessive neuromuscular disorder caused by absence of or mutations in the survival motor neuron1 gene (SMN1). All SMA patients have a highly homologous copy of SMN1, the SMN2 gene. Severe (type I) SMA patients present one or two SMN2 copies, whereas milder chronic forms (type II-III) usually have three or four SMN2 copies. SMN2 dosage is important to stratify patients for motor function tests and clinical trials. Our aim was to compare three methods, marker analysis, real-time quantitative polymerase chain reaction using the LightCycler instrument, and multiple ligation-dependent probe amplification (MLPA), to characterize their accuracy in quantifying SMN2 genes. We studied a group of 62 genetically confirmed SMA patients, 54 with homozygous absence of exons 7 and 8 of SMN1 and 8 with SMN2-SMN1 hybrid genes. A complete correlation using the three methods was observed in 32 patients (51.6%). In the remaining 30 patients, discordances between the three methods were found, including under or overestimation of SMN2 copies by marker analysis with respect to the quantitative methods (LightCycler and MLPA) because of lack of informativeness of markers, 3' deletions of SMN genes, and breakpoints in SMN2-SMN1 hybrid genes. The technical limitations and advantages and disadvantages of these methods are discussed. We conclude that the three methods complement each other in estimating the SMN2 copy number in most cases. However, MLPA offers additional information to characterize SMA cases with particular rearrangements such as partial deletions and hybrid genes.

Plastin 3 expression in discordant spinal muscular atrophy (SMA) siblings.

Spinal muscular atrophy (SMA) is caused by loss or mutations of the survival motor neuron 1 gene (SMN1). Its highly homologous copy, SMN2, is present in all SMA cases and is a phenotypic modifier. There are cases where asymptomatic siblings of typical SMA patients possess a homozygous deletion of SMN1 just like their symptomatic brothers or sisters. Plastin 3 (PLS3) when over expressed in lymphoblasts from females has been suggested to act as a genetic modifier of SMA. We studied PLS3 expression in four Spanish SMA families with discordant siblings haploidentical for the SMA locus. We excluded PLS3 as a possible modifier in two of our families with female discordant siblings. In the remaining two, we observed small differences in PLS3 expression between male and female discordant siblings. Indeed, we found that values of PLS3 expression in lymphoblasts and peripheral blood ranged from 12 to 200-fold less than those in fibroblasts. These findings warrant further investigation in motor neurons derived from induced pluripotential stem cells of these patients.

Ultrasound evaluation of fetal movements in pregnancies at risk for severe spinal muscular atrophy.

We studied spinal muscular atrophy (SMA) during human development to identify possible delays or alterations in fetal movements detectable by ultrasound. We evaluated 29 pregnancies at risk for severe SMA performing 2D-ultrasound around 11-14 weeks, prior to prenatal molecular testing of the SMN1 gene. We charted the occurrence of generalized body movements, isolated movements of arms and legs, head movements, startle and hiccup. Fetuses were diagnosed as healthy (n=12), carriers (n=10) or affected (n=7) according to the SMN1 molecular testing results obtained. SMN2 copies were also tested in the seven affected fetuses, six of whom showed two SMN2 copies and one a unique SMN2 copy. The movements under study were observed in all recordings, regardless of group and the SMN2 copies. At the gestational age examined, we did not observe a qualitative early limitation of movements in fetuses with SMA, even in cases predicted to develop a severe neonatal form.