Motor neuron cell-nonautonomous rescue of spinal muscular atrophy phenotypes in mild and severe transgenic mouse models

Survival of motor neuron (SMN) deficiency causes spinal muscular atrophy (SMA), but the pathogenesis mechanisms remain elusive. Restoring SMN in motor neurons only partially rescues SMA in mouse models, although it is thought to be therapeutically essential. Here, we address the relative importance of SMN restoration in the central nervous system (CNS) versus peripheral tissues in mouse models using a therapeutic splice-switching antisense oligonucleotide to restore SMN and a complementary decoy oligonucleotide to neutralize its effects in the CNS. Increasing SMN exclusively in peripheral tissues completely rescued necrosis in mild SMA mice and robustly extended survival in severe SMA mice, with significant improvements in vulnerable tissues and motor function. Our data demonstrate a critical role of peripheral pathology in the mortality of SMA mice and indicate that peripheral SMN restoration compensates for its deficiency in the CNS and preserves motor neurons. Thus, SMA is not a cell-autonomous defect of motor neurons in SMA mice.     

Evidence for compound heterozygosity causing mild and severe forms of autosomal recessive spinal muscular atrophy.

Spinal muscular atrophy is an autosomal recessive disease of motor neurone degeneration which shows a variable phenotype. Two candidate genes show deletions in affected subjects but with no distinction between different forms of the disease. We report an unusual family in which mild and severe SMA coexists and patients are deleted for the SMN gene. The father is affected with late onset SMA; therefore this family shows pseudodominant inheritance. When typed using closely linked flanking markers the severely affected son does not share the same haplotype as his sib, who is deleted for SMN but shows no signs yet of SMA. This supports the hypothesis that differences in SMA phenotype can be explained by a multiple allele model.     

90个脊髓性肌萎缩家系的遗传学分析

目的对90个脊髓性肌萎缩(spinal muscular atrophy,SMA)家系进行基因诊断与产前诊断,为SMA的遗传学分析方法提供参考,并初步探讨SMA缺陷基因携带者基因筛査的必要性。方法应用多重连接探针扩增(multiplex ligation dependent probe amplification,MLP A)技术对90个SMA家系进行基因诊断,联合MLPA及等位基因特异性PCR(allele specific PCR,A&PCR)技术对家系进行产前诊断并对产前诊断结果进行分析。结果在90个SMA家系中,84对夫妻无SMA家族史,占比93%;85对夫妻有SMA生育史,占比94%;85个家系夫妻双方及3个家系的孕妇SMN1基因杂合缺失,为SMA缺陷基因携带者;2个家系孕妇SMN1基因纯合缺失,为SMA患者;产前诊断结果显示48名胎儿为SMA缺陷基因携带者,23名胎儿为正常胎儿,19名胎儿为SMA患者,其中无家族史夫妻双方再孕SMA胎儿18例,占总SMA胎儿95%、占总胎儿20%。结论应用MLPA对夫妻双方进行SMA缺陷基因携带者筛查,并联合使用MLPA和AS-PCR对携带者夫妻进行SMA产前诊断十分必要,对预防SMA出生缺陷具有积极意义。     

Newborn screening for spinal muscular atrophy: The views of affected families and adults

Spinal muscular atrophy (SMA) is one of the leading genetic causes of infant death worldwide. However, due to a lack of treatments, SMA has historically fallen short of Wilson‐Jungner criteria. While studies have explored the acceptability of expanded newborn screening to the general public, the views of affected families have been largely overlooked. This is in spite of the potential for direct impacts on them and their unique positioning to consider the value of early diagnosis. We have previously reported data on attitudes toward pre‐conception and prenatal genetic screening for SMA among affected families (adults with SMA [n = 82] and family members [n = 255]). Here, using qualitative interview [n = 36] and survey data [n = 337], we report the views of this same cohort toward newborn screening. The majority (70%) of participants were in favor, however, all subgroups (except adults with type II) preferred pre‐conception and/or prenatal screening to newborn screening. Key reasons for newborn screening support were: (1) the potential for improved support; (2) the possibility of enrolling pre‐symptomatic children on clinical trials. Key reasons for non‐support were: (1) concerns about impact on the early experiences of the family; (2) inability to treat. Importantly, participants did not view the potential for inaccurate typing as a significant obstacle to the launch of a population‐wide screening program. This study underscores the need to include families affected by genetic diseases within consultations on screening. This is particularly important for conditions such as SMA which challenge traditional screening criteria, and for which new therapeutics are emerging.     

Different molecular basis for spinal muscular atrophy in South African black patients

Spinal muscular atrophy (SMA) is an autosomal recessive disorder occurring at a rate of between 1/5,000 and 1/10,000 births in most European countries. The phenotype results from the degeneration of the anterior horn cells of the spinal cord, resulting in symmetrical muscle weakness and wasting. The disorder can be classified according to the severity of the disease and the age of onset into three major types. Two candidate SMA genes, NAIP and SMN, isolated from the 5q13 region, have been reported to be homozygously deleted in ∼30% and >95% of SMA patients, respectively. Black SMA patients have been reported to have facial muscle weakness more commonly. This study aimed to determine the molecular basis of SMA in South African black SMA patients. The SMN gene was found to be homozygously deleted in 65.5% (19/29) of patients, significantly less frequently than in previous studies. Similarly, the NAIP gene was homozygously deleted in a smaller number, 14% (4/29) of patients; 47% (9/19) of SMN deletion patients appeared to have deletions of telomeric exon 7, but not exon 8. In at least six of these patients a gene conversion event has occurred. No detectable deletions were found in 35% (10/29) of patients. Haplotype analysis in the nondeletion patients, using six closely linked markers, provided no evidence for a founder mutation. No mutations were found in exons 3 and intron 6 through exon 8 by sequence analysis of these nondeletion patients. It is proposed that the differences in the SMA phenotype observed in black patients may in part be explained by a different molecular basis. Am. J. Med. Genet. 86:420–426, 1999. © 1999 Wiley-Liss, Inc.     

Severe neuromuscular denervation of clinically relevant muscles in a mouse model of spinal muscular atrophy

Spinal muscular atrophy (SMA), a motoneuron disease caused by a deficiency of the survival of motor neuron (SMN) protein, is characterized by motoneuron loss and muscle weakness. It remains unclear whether widespread loss of neuromuscular junctions (NMJs) is involved in SMA pathogenesis. We undertook a systematic examination of NMJ innervation patterns in >20 muscles in the SMNΔ7 SMA mouse model. We found that severe denervation (<50% fully innervated endplates) occurs selectively in many vulnerable axial muscles and several appendicular muscles at the disease end stage. Since these vulnerable muscles were located throughout the body and were comprised of varying muscle fiber types, it is unlikely that muscle location or fiber type determines susceptibility to denervation. Furthermore, we found a similar extent of neurofilament accumulation at NMJs in both vulnerable and resistant muscles before the onset of denervation, suggesting that neurofilament accumulation does not predict subsequent NMJ denervation. Since vulnerable muscles were initially innervated, but later denervated, loss of innervation in SMA may be attributed to defects in synapse maintenance. Finally, we found that denervation was amendable by trichostatin A (TSA) treatment, which increased innervation in clinically relevant muscles in TSA-treated SMNΔ7 mice. Our findings suggest that neuromuscular denervation in vulnerable muscles is a widespread pathology in SMA, and can serve as a preparation for elucidating the biological basis of synapse loss, and for evaluating therapeutic efficacy.     

Gene deletions in spinal muscular atrophy.

Two candidate genes (NAIP and SMN) have recently been reported for childhood onset spinal muscular atrophy (SMA). Although affected subjects show deletions of these genes, these deletions can lead to either a very mild or a severe phenotype. We have analysed a large number of clinically well defined patients, carriers, and normal controls to assess the frequency and extent of deletions encompassing both of these genes. A genotype analysis indicates that more extensive deletions are seen in the severe form of SMA than in the milder forms. In addition, 1 center dot 9% of phenotypically normal carriers are deleted for the NAIP gene; no carriers were deleted for the SMN gene. Our data suggest that deletions in both of these genes, using the currently available assays, are associated with both a severe and very mild phenotype.     

Perspectives and diagnostic considerations in spinal muscular atrophy

Spinal muscular atrophy is an autosomal recessive neurodegenerative disease and the most common genetic cause of infant mortality. The disease results in motor neuron loss and skeletal muscle atrophy. Spinal muscular atrophy is caused by mutations in the telomeric copy of the survival motor neuron 1 (SMN1) gene, but all patients retain a centromeric copy of the gene, SMN2. In the majority of cases, the disease severity correlates inversely with an increased SMN2 gene copy number. Because spinal muscular atrophy is both a severe and common disorder, a direct carrier testing has been beneficial to many families. The survival motor neuron protein is ubiquitously expressed and performs a role in the assembly of the spliceosome. It is still not understood why mutations in the SMN1 gene only seem to affect motor neurons. Progress has been made by developing therapeutic strategies based on understanding the pathogenesis of the disease. This review attempts to highlight some of the recent advances in the understanding of the disease with a focus on molecular diagnostics.     

Neurotransmitter release in motor nerve terminals of a mouse model of mild spinal muscular atrophy

Spinal muscular atrophy is a genetic disease which severity depends on the amount of SMN protein, the product of the genes SMN1 and SMN2. Symptomatology goes from severe neuromuscular impairment leading to early death in infants to slow progressing motor deficits during adulthood. Much of the knowledge about the pathophysiology of SMA comes from studies using genetically engineered animal models of the disease. Here we investigated one of the milder models, the homozygous A2G SMA mice, in which the level of the protein is restored to almost normal levels by the addition of a mutated transgene to the severe SMN-deficient background. We examined neuromuscular function and found that calcium-dependent neurotransmitter release was significantly decreased. In addition, the amplitude of spontaneous endplate potentials was decreased, the morphology of NMJ altered, and slight changes in short-term synaptic plasticity were found. In spite of these defects, excitation contraction coupling was well preserved, possibly due to the safety factor of this synapse. These data further support that the quasi-normal restoration of SMN levels in severe cases preserves neuromuscular function, even when neurotransmitter release is significantly decreased at motor nerve terminals. Nevertheless, this deficit could represent a greater risk of motor impairment during aging or after injuries.     

Different molecular basis for spinal muscular atrophy in South African black patients.

Spinal muscular atrophy (SMA) is an autosomal recessive disorder occurring at a rate of between 1/5,000 and 1/10,000 births in most European countries. The phenotype results from the degeneration of the anterior horn cells of the spinal cord, resulting in symmetrical muscle weakness and wasting. The disorder can be classified according to the severity of the disease and the age of onset into three major types. Two candidate SMA genes, NAIP and SMN, isolated from the 5q13 region, have been reported to be homozygously deleted in approximately 30% and >95% of SMA patients, respectively. Black SMA patients have been reported to have facial muscle weakness more commonly. This study aimed to determine the molecular basis of SMA in South African black SMA patients. The SMN gene was found to be homozygously deleted in 65.5% (19/29) of patients, significantly less frequently than in previous studies. Similarly, the NAIP gene was homozygously deleted in a smaller number, 14% (4/29) of patients; 47% (9/19) of SMN deletion patients appeared to have deletions of telomeric exon 7, but not exon 8. In at least six of these patients a gene conversion event has occurred. No detectable deletions were found in 35% (10/29) of patients. Haplotype analysis in the nondeletion patients, using six closely linked markers, provided no evidence for a founder mutation. No mutations were found in exons 3 and intron 6 through exon 8 by sequence analysis of these nondeletion patients. It is proposed that the differences in the SMA phenotype observed in black patients may in part be explained by a different molecular basis.     

Developmental and degenerative cardiac defects in the Taiwanese mouse model of severe spinal muscular atrophy

Spinal muscular atrophy (SMA), an autosomal recessive disease caused by a decrease in levels of the survival motor neuron (SMN) protein, is the most common genetic cause of infant mortality. Although neuromuscular pathology is the most severe feature of SMA, other organs and tissues, including the heart, are also known to be affected in both patients and animal models. Here, we provide new insights into changes occurring in the heart, predominantly at pre‐ and early symptomatic ages, in the Taiwanese mouse model of severe SMA. Thinning of the interventricular septum and dilation of the ventricles occurred at pre‐ and early symptomatic ages. However, the left ventricular wall was significantly thinner in SMA mice from birth, occurring prior to any overt neuromuscular symptoms. Alterations in collagen IV protein from birth indicated changes to the basement membrane and contributed to the abnormal arrangement of cardiomyocytes in SMA hearts. This raises the possibility that developmental defects, occurring prenatally, may contribute to cardiac pathology in SMA. In addition, cardiomyocytes in SMA hearts exhibited oxidative stress at pre‐symptomatic ages and increased apoptosis during early symptomatic stages of disease. Heart microvasculature was similarly decreased at an early symptomatic age, likely contributing to the oxidative stress and apoptosis phenotypes observed. Finally, an increased incidence of blood retention in SMA hearts post‐fixation suggests the likelihood of functional defects, resulting in blood pooling. These pathologies mirror dilated cardiomyopathy, with clear consequences for heart function that would likely contribute to potential heart failure. Our findings add significant additional experimental evidence in support of the requirement to develop systemic therapies for SMA capable of treating non‐neuromuscular pathologies.     

Altered expression of ARPP protein in skeletal muscles of patients with muscular dystrophy, congenital myopathy and spinal muscular atrophy.

OBJECTIVES: Ankyrin-repeated protein with PEST and a proline-rich region (ARPP) is a recently identified protein with 4 ankyrin-repeated motifs in its central portion. Type 1 myofibers of skeletal muscle express high levels of ARPP. Recently, we have found that ARPP expression was induced in mouse denervated skeletal muscle. This led us to hypothesize that ARPP expression might be induced in skeletal muscle under some pathological conditions. METHODS: In this study, we performed immunohistochemical analysis of ARPP expression in biopsy specimens of muscle tissue from 15 patients with muscular dystrophies (MDs), 13 with congenital myopathies and 11 with spinal muscular atrophies (SMAs). RESULTS: The ARPP expression levels of all the specimens from MD patients appeared to be lower than control muscle levels. In contrast, the specimens from the 13 patients with congenital myopathies were all ARPP positive. We also found increased numbers of ARPP-positive myofibers in patients with congenital myopathies, and these myofibers co-expressed the slow myosin heavy chain. Indeed, it has been reported that type 1 myofibers are predominant in patients with congenital myopathies, suggesting that increased numbers of ARPP-positive myofibers in such patients may be associated with increased numbers of type 1 fibers. In patients with SMAs, we found that ARPP-positive myofibers tended to be distributed in groups. As grouped myofibers have been reported to result from the process of denervation, innervation and subsequent denervation of re-innervated myofibers, the grouped ARPP-positive myofibers in SMA patients may result from denervation of the motor units. CONCLUSIONS: These findings suggest that evaluation of ARPP may be helpful for the histological diagnosis of muscle diseases.     

脊髓性肌萎缩患儿的NAIP基因分析

目的探讨脊髓性肌萎缩的基因型与临床表型（ｓｕｒｖｉｖａｌｍｏｔｏｒｎｅｕｒｏｎｅ,ＳＭＮ）的关系。方法应用ＰＣＲ技术对１３例运动神经元型基因缺失的脊髓性肌萎缩患儿进一步进行神经原性细胞凋亡抑制蛋白（ｎｅｕｒｏｎａｌａｐｏｐｔｏｓｉｓｉｎｈｉｂｉｔｏｒｙｐｒｏｔｅｉｎＮＡＩＰ）基因分析（Ⅰ型５例,Ⅱ型４例,Ⅲ型４例）。结果２例Ⅰ型患儿携有ＮＡＩＰ基因缺失（２／５,４０％）。结论ＮＡＩＰ基因缺失可能与脊髓性肌萎缩的临床表型严重程度有关