SMN Depletion has a Differential Effect on Expression of Igf1 and Trp53 in the CNS and Peripheral Tissues of Two Different Mouse Models of Spinal Muscular Atrophy

Donoghue, Morgan

10 January 2023

Spinal Muscular Atrophy (SMA) is a debilitating neurodegenerative disease resulting in death of the lower motor neurons, muscle atrophy, and in severe cases death. Due to mutations or deletions in the Survival Motor Neuron 1 (SMN1) gene, levels of functional SMN protein product are decreased. While SMA was previously described as a motor neuron exclusive disorder, recent evidence suggests that many tissue and cell types throughout the body are affected. The objective of our study was to outline the effects of varying levels of SMN depletion on two genes of interest, namely Insulin-like growth factor 1 (Igf-1) and Tumor suppressor protein 53 (Trp53) in multiple tissues throughout disease course. The severe Smn2B/- and mild Smn2B/-; SMN2+/- mouse models of SMA were utilized in our studies to determine the levels of mRNA expression and subsequent protein output for these two genes. We employed RT-qPCR, western blot, and ELISA experimental methods. In Smn2B/- mice, Igf-1 mRNA was substantially decreased in symptomatic liver tissue. This was accompanied by widespread decrease in IGF-1 protein in peripheral tissues. Interestingly, this depletion effect on Igf-1 was not observed in the mild mouse model. Our analysis also showed that Trp53 mRNA was dramatically increased within tibialis anterior skeletal muscle of symptomatic Smn2B/- mice, alongside an upregulation of factors involved in p53 mediated apoptosis. Once again, this effect was not observed in the mild Smn2B/-; SMN2+/- mouse model. Overall, we have demonstrated that the extent of SMN depletion, determines whether the expression of Igf-1 and Trp53 is perturbed, suggesting that disease severity is an important factor in what pathways are affected. Finally, we show that alterations in gene expression patterns or subsequent protein levels act in a tissue-specific fashion. More investigation is encouraged to highlight IGF-1’s role as a potential SMN-independent therapeutic for SMA.

Spinal Muscular Atrophy

IGF-1

Trp53

Low bone mineral density and fractures are highly prevalent in pediatric patients with Spinal Muscular Atrophy regardless of disease severity

Wasserman, Halley M., M.D.

28 June 2016

No description available.

Surgery

Osteoporosis

Children

spinal muscular atrophy

Fractures

C. elegans models for the study of spinal muscular atrophy

Briese, Michael

January 2008

No description available.

616.7

Examining mechanisms underlying the selective vulnerability of motor units in a mouse model of Spinal Muscular Atrophy

Thomson, Sophie Rose

January 2014

Spinal Muscular Atrophy (SMA) is a childhood form of motor neuron disease that causes a progressive paralysis that, in its most severe form, results in death before two years of age. There is currently no cure or treatment for SMA. SMA is caused by a reduction in levels of Survival Motor Neuron (SMN) protein, which results in the degeneration of lower motor neurons. This degeneration is first observed at the neuromuscular junction (NMJ), where pre-synaptic nerve terminals belonging to the motor neuron become dysfunctional and degenerate during the early stages of disease. Several previous studies have shown that the some populations of motor neurons appear to have a resistance to SMA pathology, while other neighbouring populations are vulnerable. In this study, we attempted to elucidate the cause of this vulnerability spectrum. Initially, we characterised the relative vulnerability of ten different motor unit pools in an established mouse model of severe SMA and attempted to correlate these vulnerabilities with quantified aspects of motor unit morphology. From this study, no significant correlation could be found with any aspect of motor unit morphology examined, suggesting that morphological parameters of motor neurons do no influence their relative susceptibility. We then attempted to identify changes in basal gene expression between protected and vulnerable pools of motor units using microarray analysis. Motor unit pools were labelled using a retrograde tracer injected into muscles that had previously been identified as having highly vulnerable or resistant motor units. Labelled motor neuron cell bodies were then isolated from the spinal cord using laser capture micro-dissection and RNA was extracted for microarray analysis. From this study, we identified several molecular pathways and individual genes whose expression levels compared the gene expression profiles of vulnerable and resistant motor units. Thus, molecular differences between motor neuron pools likely underlie their relative vulnerability to degeneration in SMA. Lastly, we attempted to identify a novel peptide that could be used to label synapses, including neuromuscular junctions, in vivo. This would allow us to non-invasively visualise degenerating NMJs and other synapses in human patients without the need for a biopsy. Such a tool would be extremely valuable in assessing the effectiveness of drug trials, both in human patients and animal models, and may also contribute to earlier diagnosis of motor neuron disorders. To identify a potentially suitable peptide, we used a phage display library and panned for peptides that specifically bound to the outer surface of synapses using synaptosome preparations. From this panning we successfully enriched two peptides, the sequences of which were used to manufacture fluorescently tagged peptides.

616.7

Synaptic vulnerability in spinal muscular atrophy

Murray, Lyndsay M.

January 2010

Mounting evidence suggests that synaptic connections are early pathological targets in many neurodegenerative diseases, including motor neuron disease. A better understanding of synaptic pathology is therefore likely to be critical in order to develop effective therapeutic strategies. Spinal muscular atrophy (SMA) is a common autosomal recessive childhood form of motor neuron disease. Previous studies have highlighted nerve- and muscle-specific events in SMA, including atrophy of muscle fibres and postsynaptic motor endplates, loss of lower motor neuron cell bodies and denervation of neuromuscular junctions caused by loss of pre-synaptic inputs. Here I have undertaken a detailed morphological investigation of neuromuscular synaptic pathology in the Smn-/- ;SMN2 and Smn-/-;SMN2;Δ7 mouse models of SMA. Results imply that synaptic degeneration is an early and significant event in SMA, with progressive denervation and neurofilament accumulation being present at early symptomatic time points. I have identified selectively vulnerable motor units, which appear to conform to a distinct developmental subtype compared to more stable motor units. I have also identified significant postsynaptic atrophy which does no correlate with pre-synaptic denervation, suggesting that there is a requirement for Smn in both muscle and nerve and pathological events can occur in both tissues independently. Rigorous investigation of lower motor neuron development, connectivity and gene expression at pre-symptomatic time points revealed developmental abnormalities do not underlie neuromuscular vulnerability in SMA. Equivalent gene expression analysis at end-stage time points has implicated growth factor signalling and extracellular matrix integrity in SMA pathology. Using an alternative model of early onset neurodegeneration, I provide evidence that the processes regulating morphologically distinct types of synaptic degeneration are also mechanistically distinct. In summary, in this work I highlight the importance and incidence of synaptic pathology in mouse models of spinal muscular atrophy and provide mechanistic insight into the processes regulating neurodegeneration.

616.8

Mechanisms of disease pathogenesis in Spinal Muscular Atrophy

Mutsaers, Chantal

January 2014

Low levels of survival motor neuron (SMN) protein cause the autosomal recessive neurodegenerative disease spinal muscular atrophy (SMA), through mechanisms that are poorly defined. SMN protein is ubiquitously expressed, however the major pathological hallmarks of SMA are focused on the neuromuscular system, including a loss of lower motor neurons in the ventral horn of the spinal cord and atrophy of skeletal muscle. At present there is no cure for SMA. Most research to date has focused on examining how low levels of SMN lead to pathological changes in motor neurons, therefore the contribution of other tissues, for example muscle, remains unclear. In this thesis I have used proteomic techniques to identify intrinsic molecular changes in muscle of SMA mice that contribute to neuromuscular pathology in SMA. I demonstrate significant disruption to the molecular composition of skeletal muscle in pre-symptomatic SMA mice, in the absence of any detectable degenerative changes in lower motor neurons and with a molecular profile distinct from that of denervated muscle. Functional cluster analysis of proteomics data and phospho-histone H2AX labelling of DNA damage revealed increased activity of cell death pathways in SMA muscle. In addition robust up-regulation of VDAC2 and down-regulation of parvalbumin was confirmed in two mouse models of SMA as well as in patient muscle biopsies. Thus intrinsic pathology of skeletal muscle is an important event in SMA. I then used proteomics to identify individual proteins in skeletal muscle of SMA that report directly on disease status. Two proteins, GRP75 and calreticulin, showed increased expression levels over time in different muscles as well as in skin samples, a more accessible tissue for biopsies in patients. Preliminary results suggest that GRP75 and calreticulin can be detected and measured in SMA patient muscle biopsies. These results show that proteomics provides a powerful platform for biomarker identification in SMA, revealing GRP75 and calreticulin as peripherally accessible potential protein biomarkers capable of reporting on disease progression in muscle as well as in skin samples. Finally I identified a role for ubiquitin-dependent pathways in regulating neuromuscular pathology in SMA. Levels of ubiquitin-like modifier activating enzyme 1 (UBA1) were reduced in spinal cord and skeletal muscle tissue of SMA mice. Dysregulation of UBA1 and subsequently the ubiquitination pathways led to the accumulation of β-catenin. I show here that pharmacological inhibition of β-catenin robustly ameliorates neuromuscular pathology in animal models of SMA. Interestingly, downstream disruption of β-catenin was restricted to the neuromuscular system in SMA mice. Pharmacological inhibition of β-catenin failed to prevent systemic pathology in organs. Thus disruption of ubiquitin homeostasis, with downstream consequences for β-catenin signalling, contributes to the pathogenesis of SMA, thereby highlighting novel therapeutic targets for this disease.

616.7

Targeting the ubiquitin proteasome system to develop novel therapeutic approaches for spinal muscular atrophy

Powis, Rachael Anita

January 2016

Spinal muscular atrophy (SMA) is a severe genetic neuromuscular disorder characterised by lower motor neuron degeneration and paralysis. Although it is a leading genetic cause of childhood death no approved treatment options currently exist. As SMA is caused by low levels of the survival motor neuron (SMN) protein the majority of therapeutic strategies under development are therefore aimed at trying to elevate SMN levels. However, a number of limitations with these approaches exist demonstrating a need for the investigation of SMN-independent therapeutics. Of these non-classical pathways, the ubiquitin proteasome system (UPS) is an exciting new area of SMA research. The UPS is a system which degrades unwanted or damaged proteins and alterations in the UPS (including reduced levels of ubiquitin-like modifier activating enzyme 1 [Uba1] and increased levels of ubiquitin carboxyl-terminal esterase L1 [Uchl1] and β-catenin) have been recently identified in the neuromuscular system of SMA mice, providing promising new targets for therapy development. In this thesis I demonstrate that UPS perturbations are also present in other organ systems of severe ‘Taiwanese’ SMA mice and in other SMA models including intermediate Smn2B/− mice, zebrafish and patient derived iPSC motor neurons. Given the previously demonstrated improved neuromuscular phenotype in SMA mice treated with the β-catenin inhibitor quercetin I have been establishing whether other compounds with β-catenin inhibition offer similar or even better therapeutic options. Aspirin, indomethacin and iCRT-14 trials did not improve the SMA phenotype with likely off-target adverse effects meaning that quercetin remains the most tolerable β- catenin inhibitor in SMA mice to date. Another potential target of the UPS for SMA therapeutics is the deubiquitinating enzyme Uchl1, levels of which are increased in SMA. In this thesis I show that pharmacological inhibition of Uchl1 did not improve survival or motor performance in SMA mice and instead had a detrimental impact on the disease phenotype which could be explained by worsening SMA ubiquitin defects. Histological analysis revealed that there was no improvement in lower motor neuron count numbers, neuromuscular junction deficits or muscle fibre diameters. Mimicking the UPS phenotype in primary neuronal cells suggested that targeting UPS perturbations observed in SMA that are upstream of Uchl1, particularly the loss of Uba1, may therefore offer a more effective therapeutic option. Finally, I therefore examined whether increasing Uba1 levels in SMA mice using gene therapy technology was able to improve the SMA phenotype. My initial studies indicate that delivery of AAV9-UBA1 to SMA mice may be beneficial as intraperitoneal injection of AAV9-UBA1 was found to increase the weight and improve motor performance of SMA mice. Intravenous delivery of AAV9-UBA1 was found to further improve expression levels and biodistribution of AAV9-UBA1 in the central nervous system as well as systemically in all body organs and tissues. Western blot and proteomic analysis revealed that AAV9-UBA1 gene therapy is also able to correct downstream UPS perturbations found in SMA as well as increase SMN levels. Together, these results suggest that AAV9-UBA1 gene therapy is an exciting novel therapeutic approach for SMA.

Characterizing the Role of HuR in Skeletal Muscle of Mice with Spinal Muscular Atrophy

Haghandish, Amir

January 2017

Spinal muscular atrophy (SMA) is a debilitating neuromuscular disorder characterized by insufficient SMN protein, resulting in motoneuron death. Initially, it was thought that motoneuronal death is followed by muscle atrophy; however, recent research is beginning to reveal possible muscle intrinsic defects, independent of motoneuron defects, in SMA. Previous studies have elucidated the cooperative involvement of CARM1, HuD and SMN in motoneurons, revealing HuD as a possible key player in the SMA phenotype. In this study, we focus on HuR, a ubiquitous family member of HuD, and the possibility that it plays a similar key role with CARM1 and SMN in skeletal muscle. Through the use of an shCARM1 stable line of C2C12s, we show that CARM1 is necessary for HuR functionality during differentiation. We further show that the methylation of HuR is necessary for its capability to translocate cytoplasmically during differentiation. We confirm an interaction between HuR and SMN, suggestive of a similar mechanism as was shown previously with HuD. In light of these findings, we next progressed to determine whether HuR is misregulated in an SMA mouse model. We report increased CARM1 levels in skeletal muscles of these mice. We further discovered that a deficiency in SMN protein impairs HuR upregulation and cytoplasmic translocation in response to HuR activation through sciatic nerve denervation. These findings were correlated with aberrant mRNA expression of HuR targets upon denervation. Taken together, these results show that HuR methylation is essential for proper myogenesis, and that the mechanism by which it acts likely requires sufficient SMN protein levels. In a deficiency of SMN, HuR shows signs of misregulation that may play a role in the inability to maintain or repair muscle in SMA.

Spinal Muscular Atrophy

HuR

CARM1

SMA

Skeletal Muscle

Differentiation

Production and characterization of recombinant mouse proGDNF

Wang, Mingxi.

January 2006

Thesis (Ph. D.)--University of Hong Kong, 2007. / Title proper from title frame. Also available in printed format.

A study of readthrough therapy for spinal muscular atrophy in a transgenic mouse model

Terryberry, Melissa S. Lorson, Christian Garcia, Michael L.

January 2009

Title from PDF of title page (University of Missouri--Columbia, viewed on Feb 19, 2010). The entire thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file; a non-technical public abstract appears in the public.pdf file. Thesis advisor: Dr. Christian Lorson and Dr. Michael Garcia. Includes bibliographical references.