Intravenous scAAV9 delivery of a codon-optimized SMN1 sequence rescues SMA mice

Domı́nguez, Elisa; Marais, Thibaut; Chatauret, Nicolas; Benkhelifa‐Ziyyat, Sofia; Duqué, Sandra; Ravassard, Philippe; Carcenac, Romain; Astord, Stéphanie; Moura, A. Pereira de; Voït, Thomas; Barkats, Martine

doi:10.1093/hmg/ddq514

Cited by 263 publications

(200 citation statements)

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“…In part, this is a consequence of the identification of new serotypes, for example adenoassociated virus (AAV)9, of the adenoassociated virus which are reported to efficiently penetrate BBB of neonatal mice and infect multiple cell types [102]. Such a vector harboring SMN1 infected not only neurons, but also peripheral tissue, dramatically rescuing the SMA phenotype in severely affected model mice [80,103,104]. The promise of this strategy in preclinical murine models has prompted the development of protocols that can be applied to larger models and eventually SMA patients.…”

Section: Gene and Cell Replacement Protocolsmentioning

confidence: 99%

Spinal Muscular Atrophy: Journeying From Bench to Bedside

2014

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Spinal muscular atrophy (SMA) is a frequently fatal neuromuscular disorder and the most common inherited cause of infant mortality. SMA results from reduced levels of the survival of motor neuron (SMN) protein. Although the disease was first described more than a century ago, a precise understanding of its genetics was not obtained until the SMA genes were cloned in 1995. This was followed in rapid succession by experiments that assigned a role to the SMN protein in the proper splicing of genes, novel animal models of the disease, and the eventual use of the models in the pre clinical development of rational therapies for SMA. These successes have led the scientific and clinical communities to the cusp of what are expected to be the first truly promising treatments for the human disorder. Yet, important questions remain, not the least of which is how SMN paucity triggers a predominantly neuromuscular phenotype. Here we review how our understanding of the disease has evolved since the SMA genes were identified. We begin with a brief description of the genetics of SMA and the proposed roles of the SMN protein. We follow with an examination of how the genetics of the disease was exploited to develop genetically faithful animal models, and highlight the insights gained from their analysis. We end with a discussion of ongoing debates, future challenges, and the most promising treatments to have emerged from our current knowledge of the disease.

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Section: Gene and Cell Replacement Protocolsmentioning

confidence: 99%

Spinal Muscular Atrophy: Journeying From Bench to Bedside

2014

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“…Several groups are currently evaluating the pre-clinical efficacy of scAAV which have been shown to efficiently infect motor neurons [Foust et al, 2010;Passini et al, 2010;Valori et al, 2010;Dominguez et al, 2011]. Two distinct routes of administration, intravenous (IV) and IT injections, have been tested in pre-clinical models: a better outcome, in terms of survival of the affected mice, has been achieved by IV compared to IT [Foust et al, 2010;Passini et al, 2010;Valori et al, 2010;Dominguez et al, 2011]. However, this therapeutic approach presents some issues: while IT administration could limit the spreading of scAAV infection outside the CNS, potentially reducing the risk of immunization against the virus, it precludes provision of SMN to peripheral tissues.…”

Section: Therapeutic Window: When Will Treatment Yield the Best Benefit?mentioning

confidence: 99%

Solving the puzzle of spinal muscular atrophy: What are the missing pieces?

Tiziano

Melki

Simard

2013

American J of Med Genetics Pt A

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Spinal muscular atrophy (SMA) is an autosomal recessive, lower motor neuron disease. Clinical heterogeneity is pervasive: three infantile (type I-III) and one adult-onset (type IV) forms are recognized. Type I SMA is the most common genetic cause of death in infancy and accounts for about 50% of all patients with SMA. Most forms of SMA are caused by mutations of the survival motor neuron (SMN1) gene. A second gene that is 99% identical to SMN1 (SMN2) is located in the same region. The only functionally relevant difference between the two genes identified to date is a C ! T transition in exon 7 of SMN2, which determines an alternative spliced isoform that predominantly excludes exon 7. Thus, SMN2 genes do not produce sufficient full length SMN protein to prevent the onset of the disease. Since the identification of the causative mutation, biomedical research of SMA has progressed by leaps and bounds: from clues on the function of SMN protein, to the development of different models of the disease, to the identification of potential treatments, some of which are currently in human trials. The aim of this review is to elucidate the current state of knowledge, emphasizing how close we are to the solution of the puzzle that is SMA, and, more importantly, to highlight the missing pieces of this puzzle. Filling in these gaps in our knowledge will likely accelerate the development and delivery of efficient treatments for SMA patients and be a prerequisite towards achieving our final goal, the cure of SMA. Ó 2013 Wiley Periodicals, Inc. Key words: spinal muscular atrophy; SMN INTRODUCTIONSpinal muscular atrophy (SMA) is a lower motor neuron disease that predominantly affects spinal cord anterior horn cells and brain stem nuclei [Dubowitz, 1995; reviewed in Hamilton and Gillingwater, 2013]. Alpha-motor neuron cell degeneration results in progressive, symmetrical skeletal muscle atrophy of limbs and trunk, spreading proximal to distal [Crawford and Pardo, 1996]. Clinical heterogeneity is pervasive: based on the age of onset and on the maximum motor achievement of patients, three infantile (type I-III) and one adult-onset (type IV) forms are commonly recognized. Classification criteria are summarized in Table I. However, this rigid classification does not accurately depict the range of SMA clinical phenotypes, which display a more continuous spectrum, ranging from prenatal onset to almost asymptomatic patients. SMA is a common autosomal recessive disorder (incidence is $1 in 6,000 in most ethnicities). Type I SMA is the most common genetic cause of death in infancy and accounts for about 50% of all patients with SMA [Crawford and Pardo, 1996;Prior, 2010].Most forms of SMA are caused by mutations in the survival motor neuron (SMN) gene, which was isolated in 1995 in chromosome 5q13 harboring a segmental duplication [Lefebvre et al., 1995]. Mutations in SMN1 are responsible for the four forms of SMA [Wirth, 2000;Alías et al., 2009]. A second gene that is 99% identical to SMN1, the SMN2 gene, is located in the same region [Le...

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“…Not surprisingly, extensive efforts have been undertaken to examine constructs and vectors that can safely boost SMN expression in motor neurons of SMA models Dominguez et al, 2011;Foust et al, 2010;Glascock et al, 2011;Passini et al, 2010). This has been one of the mainstream objectives in the search for drugs to treat SMA.…”

Section: Sma Animal Modelsmentioning

confidence: 99%

Targeting RNA-Splicing for SMA Treatment

Zhou

Zheng

Shen

2012

Molecules and Cells

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The central dogma of DNA-RNA-protein was established more than 40 years ago. However, important biological processes have been identified since the central dogma was developed. For example, methylation is important in the regulation of transcription. In contrast, proteins, are more complex due to modifications such as phosphorylation, glycosylation, ubiquitination, or cleavage. RNA is the mediator between DNA and protein, but it can also be modulated at several levels. Among the most profound discoveries of RNA regulation is RNA splicing. It has been estimated that 80% of pre-mRNA undergo alternative splicing, which exponentially increases biological information flow in cellular processes. However, an increased number of regulated steps inevitably accompanies an increased number of errors. Abnormal splicing is often found in cells, resulting in protein dysfunction that causes disease. Splicing of the survival motor neuron (SMN) gene has been extensively studied during the last two decades. Accumulating knowledge on SMN splicing has led to speculation and search for spinal muscular atrophy (SMA) treatment by stimulating the inclusion of exon 7 into SMN mRNA. This mini-review summaries the latest progress on SMN splicing research as a potential treatment for SMA disease.

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Intravenous scAAV9 delivery of a codon-optimized SMN1 sequence rescues SMA mice

Cited by 263 publications

References 50 publications

Spinal Muscular Atrophy: Journeying From Bench to Bedside

Spinal Muscular Atrophy: Journeying From Bench to Bedside

Solving the puzzle of spinal muscular atrophy: What are the missing pieces?

Targeting RNA-Splicing for SMA Treatment

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