The developmental pattern of myotubes in spinal muscular atrophy indicates prenatal delay of muscle maturation.

The loss and degeneration of spinal cord motor neurons result in muscle denervation in spinal muscular atrophy (SMA), but whether there are primary pathogenetic abnormalities of muscle in SMA is not known. We previously detected increased DNA fragmentation and downregulation of Bcl-2 and Bcl-X(L) expression but no morphological changes in spinal motor neurons of SMA fetuses. Here, we performed histological and morphometric analysis of myotubes and assessed DNA fragmentation and Bcl-2/Bcl-X(L) expression in skeletal muscle from fetuses with type I SMA (at approximately 12 and 15 weeks' gestational ages, n = 4) and controls (at approximately 10-15 weeks' gestational ages, n = 7). Myotubes were smaller in the SMA than in control samples at all ages analyzed (p < 0.001) and were often arranged in clusters close to isolated and larger myotubes. Numbers of terminal deoxynucleotidyl transferase dUTP nick end labeling-positive cells in control and SMA fetuses were similar, and no differences in Bcl-2 or Bcl-X(L) immunostaining between control and SMA muscle were identified. Areas with smaller myotubes and the morphometric analysis suggested a delay in growth and maturation in SMA muscle. These results suggest that spinal motor neurons and skeletal muscle undergo different pathogenetic processes in SMA during development; they imply that muscle as well as motor neurons may be targets for early therapeutic intervention in SMA.

Implication of fetal SMN2 expression in type I SMA pathogenesis: protection or pathological gain of function?

Spinal muscular atrophy (SMA) is caused by mutations in the survival motor neuron gene 1 (SMN1). The SMN2 gene, which is the highly homologous SMN1 copy that is present in all the patients, is unable to prevent the disease. Most of the SMN1 transcript is full-length, whereas a substantial proportion of the SMN2 transcript lacks exon 7 (delta7). We characterized the developmental expression of SMN2 by comparing control and SMA fetuses. The control spinal cord revealed the highest amount of FL SMN, most of which was of SMN1 origin. When analyzing the SMA spinal cord transcripts, we detected a considerable reduction in the FL/delta7 ratios due to a decrease in the FL and an increase in delta7 isoform. After immunoblot and immunohistochemistry analyses, we found that the amount of SMN2 protein in the SMA spinal cord and muscle was lower than in the controls. However, the results of the expression of SMN2 in intestine, lung, adrenal gland, kidney, and eye, which are unaffected by the disease, were the same in controls and SMA samples. In these tissues, SMN2 may compensate for the absence of SMN1, whereas in SMA motor neurons, a cell-specific dysregulation of the SMN2 expression could favor the onset of the acute form of the disease.

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.

Two independent mutations of the SMN1 gene in the same spinal muscular atrophy family branch: lessons for carrier diagnosis.

PURPOSE: We present the results of carrier studies in 33 relatives of the paternal branch of a spinal muscular atrophy patient with homozygous absence of the SMN1 gene. METHODS AND RESULTS: Once linkage and quantitative analyses were performed, a number of first-, second- and third-degree relatives were identified as carriers given that they shared the at-risk haplotype and showed one SMN1 copy. In the fourth-degree relatives, linkage analysis demonstrated discordance with the quantitative results because the members with one copy were carriers of the mutation, but in a different haplotype background. We concluded that two independent mutations were present in this branch of the family. Furthermore, the combination of both methods of analysis allowed us to identify carriers with two SMN1 genes in one chromosome and none in the remaining chromosome. CONCLUSIONS: Carrier testing in spinal muscular atrophy should be performed by employing both quantitative and linkage analyses in order to guarantee accurate carrier identification.