Genome-wide identification of tandem repeats associated with splicing variation across 49 tissues in humans.

Tandem repeats (TRs) are one of the largest sources of polymorphism, and their length is associated with gene regulation. Although previous studies reported several tandem repeats regulating gene splicing in cis (spl-TRs), no large-scale study has been conducted. In this study, we established a genome-wide catalog of 9537 spl-TRs with a total of 58,290 significant TR-splicing associations across 49 tissues (false discovery rate 5%) by using Genotype-Tissue expression (GTex) Project data. Regression models explaining splicing variation by using spl-TRs and other flanking variants suggest that at least some of the spl-TRs directly modulate splicing. In our catalog, two spl-TRs are known loci for repeat expansion diseases, spinocerebellar ataxia 6 (SCA6) and 12 (SCA12). Splicing alterations by these spl-TRs were compatible with those observed in SCA6 and SCA12. Thus, our comprehensive spl-TR catalog may help elucidate the pathomechanism of genetic diseases.

Subcellular localization and ER-mediated cytotoxic function of α1A and α1ACT in spinocerebellar ataxia type 6.

Spinocerebellar ataxia type 6 (SCA6) is a polyglutamine (polyQ) disease, which is caused by the elongation of CAG repeats encoding polyQ in the CACNA1A gene. The CACNA1A gene encodes two proteins, namely, α1A (a subunit of the plasma membrane calcium channel), which is translated in its entire length, and α1ACT, which is translated from the second cistron, and both proteins have a polyQ tract. The α1A-polyQ and α1ACT-polyQ proteins with an elongated polyQ stretch have been reported to form aggregates in cells and induce neuronal cell death, but the subcellular localization of these proteins and their cytotoxic properties remain unclear. In this study, we first analyzed SCA6 model mice and found that α1A-polyQlong localized mainly to the Golgi apparatus, whereas a portion of α1ACT-polyQlong localized to the nucleus. Analysis using Neuro2a cells also showed similar subcellular localizations of these proteins, and a proportion of both proteins localized to the endoplasmic reticulum (ER). Cytotoxic studies demonstrated that both proteins induce both the ER stress response and apoptosis, indicating that they are able to induce ER stress-induced apoptosis.

Spinocerebellar ataxia type 31 (SCA31).

Spinocerebellar ataxia type 31 (SCA31) is one of the most common forms of autosomal-dominant cerebellar ataxia in Japan. SCA31 has a strong founder effect, which is consistent with the fact that this disease is basically absent in other ethnicities. After searching the entire founder region of a 2-megabase (Mb), we finally identified a 2.5 to 3.8 kb-long complex penta-nucleotide repeat containing (TGGAA)n, (TAGAA)n, (TAAAA)n and (TAAAATAGAA)n as the only genetic change segregating SCA31 individuals from normal people. Furthermore, (TGGAA)n was isolated as the only repeat explaining the pathogenesis because other repeats were encountered in control Japanese. From the genomic point of view, the complex penta-nucleotide repeat lies in an intronic segment shared by two genes, BEAN1 (brain expressed, associated with Nedd4) and TK2 (thymidine kinase 2) transcribed in mutually opposite directions. While TK2 is ubiquitously expressed, BEAN1 is transcribed only in the brain. Thus, the complex repeat is bi-directionally transcribed exclusively in the brain, as two independent non-coding repeats. Furthermore, the complex repeat containing (UGGAA)n was found to form abnormal RNA structures, called RNA foci, in cerebellar Purkinje cell nuclei of SCA31 patients' brains. Subsequent investigation by over-expressing (UGGAA)n in Drosophila revealed that the RNA containing (UGGAA)n exerts toxicity in a length- and expression level-dependent manner, whereas its toxicity could be dampened by (UGGAA)n-binding proteins, TDP-43, FUS and hnRNP A2/B1. It seems rational to formulate a treatment strategy through enhancing the role of RNA-binding proteins against (UGGAA)n-toxicity in SCA31.

Thymidine Kinase 2 and Mitochondrial Protein COX I in the Cerebellum of Patients with Spinocerebellar Ataxia Type 31 Caused by Penta-nucleotide Repeats (TTCCA)n.

Spinocerebellar ataxia type 31 (SCA31), an autosomal-dominant neurodegenerative disorder characterized by progressive cerebellar ataxia with Purkinje cell degeneration, is caused by a heterozygous 2.5-3.8 kilobase penta-nucleotide repeat of (TTCCA)n in intron 11 of the thymidine kinase 2 (TK2) gene. TK2 is an essential mitochondrial pyrimidine-deoxyribonucleoside kinase. Bi-allelic loss-of-function mutations of TK2 lead to mitochondrial DNA depletion syndrome (MDS) in humans through severe (~ 70%) reduction of mitochondrial electron-transport-chain activity, and tk2 knockout mice show Purkinje cell degeneration and ataxia through severe mitochondrial cytochrome-c oxidase subunit I (COX I) protein reduction. To clarify whether TK2 function is altered in SCA31, we investigated TK2 and COX I expression in human postmortem SCA31 cerebellum. We confirmed that canonical TK2 mRNA is transcribed from exons far upstream of the repeat site, and demonstrated that an extended version of TK2 mRNA ("TK2-EXT"), transcribed from exons spanning the repeat site, is expressed in human cerebellum. While canonical TK2 was conserved among vertebrates, TK2-EXT was specific to primates. Reverse transcription-PCR demonstrated that both TK2 mRNAs were preserved in SCA31 cerebella compared with control cerebella. The TK2 proteins, assessed with three different antibodies including our original polyclonal antibody against TK2-EXT, were detected as ~ 26 kilodalton proteins on western blot; their levels were similar in SCA31 and control cerebella. COX I protein level was preserved in SCA31 compared to nuclear DNA-encoded protein. We conclude that the expression and function of TK2 are preserved in SCA31, suggesting a mechanism distinct from that of MDS.

Temporal Relationship between Impairment of Cerebellar Motor Learning and Deterioration of Ataxia in Patients with Cerebellar Degeneration.

Ataxia and impaired motor learning are both fundamental features in diseases affecting the cerebellum. However, it remains unclarified whether motor learning is impaired only when ataxia clearly manifests, nor it is known whether the progression of ataxia, the speed of which often varies among patients with the same disease, can be monitored by examining motor learning. We evaluated motor learning and ataxia at intervals of several months in 40 patients with degenerative conditions [i.e., multiple system atrophy (MSA), Machado-Joseph disease (MJD)/spinocerebellar ataxia type 3 (SCA3), SCA6, and SCA31]. Motor learning was quantified as the adaptability index (AI) in the prism adaptation task and ataxia was scored using the Scale for the Assessment and Rating of Ataxia (SARA). We found that AI decreased most markedly in both MSA-C and MSA-P, moderately in MJD, and mildly in SCA6 and SCA31. Overall, the AI decrease occurred more rapidly than the SARA score increase. Interestingly, AIs remained normal in purely parkinsonian MSA-P patients (n = 4), but they dropped into the ataxia range when these patients started to show ataxia. The decrease in AI during follow-up (dAI/dt) was significant in patients with SARA scores < 10.5 compared with patients with SARA scores ≥ 10.5, indicating that AI is particularly useful for diagnosing the earlier phase of cerebellar degeneration. We conclude that AI is a useful marker for progressions of cerebellar diseases, and that evaluating the motor learning of patients can be particularly valuable for detecting cerebellar impairment, which is often masked by parkinsonisms and other signs.

Analyzing schizophrenia-related phenotypes in mice caused by autoantibodies against NRXN1α in schizophrenia.

The molecular pathological mechanisms underlying schizophrenia remain unclear; however, genomic analysis has identified genes encoding important risk molecules. One such molecule is neurexin 1α (NRXN1α), a presynaptic cell adhesion molecule. In addition, novel autoantibodies that target the nervous system have been found in patients with encephalitis and neurological disorders. Some of these autoantibodies inhibit synaptic antigen molecules. Studies have examined the association between schizophrenia and autoimmunity; however, the pathological data remain unclear. Here, we identified a novel autoantibody against NRXN1α in patients with schizophrenia (n = 2.1%) in a Japanese cohort (n = 387). None of the healthy control participants (n = 362) were positive for anti-NRXN1α autoantibodies. Anti-NRXN1α autoantibodies isolated from patients with schizophrenia inhibited the molecular interaction between NRXN1α and Neuroligin 1 (NLGN1) and between NRXN1α and Neuroligin 2 (NLGN2). Additionally, these autoantibodies reduced the frequency of the miniature excitatory postsynaptic current in the frontal cortex of mice. Administration of anti-NRXN1α autoantibodies from patients with schizophrenia into the cerebrospinal fluid of mice reduced the number of spines/synapses in the frontal cortex and induced schizophrenia-related behaviors such as reduced cognition, impaired pre-pulse inhibition, and reduced social novelty preference. These changes were improved through the removal of anti-NRXN1α autoantibodies from the IgG fraction of patients with schizophrenia. These findings demonstrate that anti-NRXN1α autoantibodies transferred from patients with schizophrenia cause schizophrenia-related pathology in mice. Removal of anti-NRXN1α autoantibodies may be a therapeutic target for a subgroup of patients who are positive for these autoantibodies.

Bi-allelic CSF1R Mutations Cause Skeletal Dysplasia of Dysosteosclerosis-Pyle Disease Spectrum and Degenerative Encephalopathy with Brain Malformation.

Colony stimulating factor 1 receptor (CSF1R) plays key roles in regulating development and function of the monocyte/macrophage lineage, including microglia and osteoclasts. Mono-allelic mutations of CSF1R are known to cause hereditary diffuse leukoencephalopathy with spheroids (HDLS), an adult-onset progressive neurodegenerative disorder. Here, we report seven affected individuals from three unrelated families who had bi-allelic CSF1R mutations. In addition to early-onset HDLS-like neurological disorders, they had brain malformations and skeletal dysplasia compatible to dysosteosclerosis (DOS) or Pyle disease. We identified five CSF1R mutations that were homozygous or compound heterozygous in these affected individuals. Two of them were deep intronic mutations resulting in abnormal inclusion of intron sequences in the mRNA. Compared with Csf1r-null mice, the skeletal and neural phenotypes of the affected individuals appeared milder and variable, suggesting that at least one of the mutations in each affected individual is hypomorphic. Our results characterized a unique human skeletal phenotype caused by CSF1R deficiency and implied that bi-allelic CSF1R mutations cause a spectrum of neurological and skeletal disorders, probably depending on the residual CSF1R function.

Tandem internal models execute motor learning in the cerebellum.

In performing skillful movement, humans use predictions from internal models formed by repetition learning. However, the computational organization of internal models in the brain remains unknown. Here, we demonstrate that a computational architecture employing a tandem configuration of forward and inverse internal models enables efficient motor learning in the cerebellum. The model predicted learning adaptations observed in hand-reaching experiments in humans wearing a prism lens and explained the kinetic components of these behavioral adaptations. The tandem system also predicted a form of subliminal motor learning that was experimentally validated after training intentional misses of hand targets. Patients with cerebellar degeneration disease showed behavioral impairments consistent with tandemly arranged internal models. These findings validate computational tandemization of internal models in motor control and its potential uses in more complex forms of learning and cognition.

Comorbid argyrophilic grain disease in an 87-year-old male with spinocerebellar ataxia type 31 with dementia: a case report.

BACKGROUND: Spinocerebellar ataxia type 31 (SCA31) is not usually associated with dementia, and autopsy in a patient with both conditions is very rare. CASE PRESENTATION: An 87-year-old male patient presented with ataxia and progressive dementia. Genetic testing led to a diagnosis of SCA31. Fifteen years after his initial symptoms of hearing loss and difficulty walking, he died of aspiration pneumonia. A pathological analysis showed cerebellar degeneration consistent with SCA31 and abundant argyrophilic grains in the hippocampal formation and amygdala that could explain his dementia. CONCLUSIONS: This is the first autopsy report on comorbid argyrophilic grain disease with SCA31.

Ataxic phenotype with altered CaV3.1 channel property in a mouse model for spinocerebellar ataxia 42.

Spinocerebellar ataxia 42 (SCA42) is a neurodegenerative disorder recently shown to be caused by c.5144G > A (p.Arg1715His) mutation in CACNA1G, which encodes the T-type voltage-gated calcium channel CaV3.1. Here, we describe a large Japanese family with SCA42. Postmortem pathological examination revealed severe cerebellar degeneration with prominent Purkinje cell loss without ubiquitin accumulation in an SCA42 patient. To determine whether this mutation causes ataxic symptoms and neurodegeneration, we generated knock-in mice harboring c.5168G > A (p.Arg1723His) mutation in Cacna1g, corresponding to the mutation identified in the SCA42 family. Both heterozygous and homozygous mutants developed an ataxic phenotype from the age of 11-20 weeks and showed Purkinje cell loss at 50 weeks old. Degenerative change of Purkinje cells and atrophic thinning of the molecular layer were conspicuous in homozygous knock-in mice. Electrophysiological analysis of Purkinje cells using acute cerebellar slices from young mice showed that the point mutation altered the voltage dependence of CaV3.1 channel activation and reduced the rebound action potentials after hyperpolarization, although it did not significantly affect the basic properties of synaptic transmission onto Purkinje cells. Finally, we revealed that the resonance of membrane potential of neurons in the inferior olivary nucleus was decreased in knock-in mice, which indicates that p.Arg1723His CaV3.1 mutation affects climbing fiber signaling to Purkinje cells. Altogether, our study shows not only that a point mutation in CACNA1G causes an ataxic phenotype and Purkinje cell degeneration in a mouse model, but also that the electrophysiological abnormalities at an early stage of SCA42 precede Purkinje cell loss.

Cross-Sectional Area Analysis of the Head of the Caudate Nucleus in Huntington's Disease.

BACKGROUND: Caudate nucleus atrophy is a well-known neuroimaging feature of Huntington's disease (HD). Some researchers have reported a decrease in the volume of the striatum on magnetic resonance images (MRIs) even in the presymptomatic stage of the disease. Despite the many neuroimaging studies on HD, the optimal method for measuring the caudate nucleus area on MRIs and the most effective cutoff values for diagnosing HD remain unclear. OBJECTIVES AND METHODS: To define suitable imaging sequences and cutoff values for HD, we measured the area of the head of the caudate nucleus (HCN) in 11 patients with HD, 22 age- and sex-matched individuals without neurodegenerative disorders in the central nervous system, 22 sex-matched patients with Alzheimer's disease, 22 sex-matched patients with Parkinson's disease, and 7 patients with dentatorubral-pallidoluysian atrophy. RESULTS: On T2-weighted images (T2WIs), we found significantly reduced HCN area at the rostral level in individuals with HD relative to those of the individuals in the other groups. A significant inverse correlation (ρ = -0.61, p = 0.046) was observed between the HD duration and HCN area at the rostral slice level on T2WIs. The cutoff value for distinguishing patients with HD from healthy individuals and those with other neurodegenerative diseases was 85 mm2 at the rostral level on T2WIs (100% sensitivity and specificity). CONCLUSIONS: This cutoff value can be applied clinically to evaluate brain atrophy in HD. Our method is advantageous because it is simple and can be implemented easily in daily clinical practice.

Loss of MyD88 alters neuroinflammatory response and attenuates early Purkinje cell loss in a spinocerebellar ataxia type 6 mouse model.

Spinocerebellar ataxia type 6 (SCA6) is dominantly inherited neurodegenerative disease, caused by an expansion of CAG repeat encoding a polyglutamine (PolyQ) tract in the Cav2.1 voltage-gated calcium channel. Its key pathological features include selective degeneration of the cerebellar Purkinje cells (PCs), a common target for PolyQ-induced toxicity in various SCAs. Mutant Cav2.1 confers toxicity primarily through a toxic gain-of-function mechanism; however, its molecular basis remains elusive. Here, we studied the cerebellar gene expression patterns of young Sca6-MPI(118Q/118Q) knockin (KI) mice, which expressed mutant Cav2.1 from an endogenous locus and recapitulated many phenotypic features of human SCA6. Transcriptional signatures in the MPI(118Q/118Q) mice were distinct from those in the Sca1(154Q/2Q) mice, a faithful SCA1 KI mouse model. Temporal expression profiles of the candidate genes revealed that the up-regulation of genes associated with microglial activation was initiated before PC degeneration and was augmented as the disease progressed. Histological analysis of the MPI(118Q/118Q) cerebellum showed the predominance of M1-like pro-inflammatory microglia and it was concomitant with elevated expression levels of tumor necrosis factor, interleukin-6, Toll-like receptor (TLR) 2 and 7. Genetic ablation of MyD88, a major adaptor protein conveying TLR signaling, altered expression patterns of M1/M2 microglial phenotypic markers in the MPI(118Q/118Q) cerebellum. More importantly, it ameliorated PC loss and partially rescued motor impairments in the early disease phase. These results suggest that early neuroinflammatory response may play an important role in the pathogenesis of SCA6 and its modulation could pave the way for slowing the disease progression during the early stage of the disease.

Clinical characteristics of combined cases of spinocerebellar ataxia types 6 and 31.

This study reports the first family in which spinocerebellar ataxia type 6 (SCA6) and spinocerebellar ataxia type 31 (SCA31) mutations were seen. An index patient first presented to our hospital due to gait and speech disturbances. Subsequent clinical investigation of this patient and her family members revealed consistent pure cerebellar ataxia transmitted in an autosomal-dominant manner. Genetic examination unexpectedly demonstrated that two of the five affected individuals had expansions of SCA6 and SCA31, while two others had SCA31 alone and the remaining had SCA6. Clinical manifestations were more severe in individuals with combined mutations relative to those with single mutation, suggesting that the SCA6 and SCA31 mutations have a cumulative pathogenic effect.

Spinocerebellar ataxia type 36 exists in diverse populations and can be caused by a short hexanucleotide GGCCTG repeat expansion.

OBJECTIVE: Spinocerebellar ataxia 36 (SCA36) is an autosomal-dominant neurodegenerative disorder caused by a large (>650) hexanucleotide GGCCTG repeat expansion in the first intron of the NOP56 gene. The aim of this study is to clarify the prevalence, clinical and genetic features of SCA36. METHODS: The expansion was tested in 676 unrelated SCA index cases and 727 controls from France, Germany and Japan. Clinical and neuropathological features were investigated in available family members. RESULTS: Normal alleles ranged between 5 and 14 hexanucleotide repeats. Expansions were detected in 12 families in France (prevalence: 1.9% of all French SCAs) including one family each with Spanish, Portuguese or Chinese ancestry, in five families in Japan (1.5% of all Japanese SCAs), but were absent in German patients. All the 17 SCA36 families shared one common haplotype for a 7.5 kb pairs region flanking the expansion. While 27 individuals had typically long expansions, three affected individuals harboured small hexanucleotide expansions of 25, 30 and 31 hexanucleotide repeat-units, demonstrating that such a small expansion could cause the disease. All patients showed slowly progressive cerebellar ataxia frequently accompanied by hearing and cognitive impairments, tremor, ptosis and reduced vibration sense, with the age at onset ranging between 39 and 65 years, and clinical features were indistinguishable between individuals with short and typically long expansions. Neuropathology in a presymptomatic case disclosed that Purkinje cells and hypoglossal neurons are affected. CONCLUSIONS: SCA36 is rare with a worldwide distribution. It can be caused by a short GGCCTG expansion and associates various extracerebellar symptoms.

A novel mutation of PDE8B Gene in a Japanese family with autosomal-dominant striatal degeneration.

BACKGROUND: Autosomal-dominant striatal degeneration is a rare autosomal-dominant neurodegenerative movement disorder characterized by slowly progressive parkinsonism. Recently, a mutation of the cyclic nucleotide phosphodiesterase 8B gene was reported to be a causal gene mutation of this disease. METHODS: We report on the clinical characteristics of 2 patients of a Japanese family with autosomal-dominant striatal degeneration and the result of gene mutation analysis of this family. RESULTS: Clinical features of the patients are slowly progressive parkinsonism and brain MRI showing high signal intensity in T2-weighted images in the striatum. We found a heterozygous nonsense mutation in the first exon of cyclic nucleotide phosphodiesterase 8B gene, which is predicted to disrupt all important functional domains of the cyclic nucleotide phosphodiesterase 8B protein. CONCLUSIONS: This family is the second family with autosomal-dominant striatal degeneration after the first German family, confirming that cyclic nucleotide phosphodiesterase 8B gene is the causative gene for this disease.

Development of Purkinje cell degeneration in a knockin mouse model reveals lysosomal involvement in the pathogenesis of SCA6.

Spinocerebellar ataxia type 6 (SCA6) is a neurodegenerative disease caused by the expansion of a polyglutamine tract in the Ca(v)2.1 voltage-gated calcium channel. To elucidate how the expanded polyglutamine tract in this plasma membrane protein causes the disease, we created a unique knockin mouse model that modestly overexpressed the mutant transcripts under the control of an endogenous promoter (MPI-118Q). MPI-118Q mice faithfully recapitulated many features of SCA6, including selective Purkinje cell degeneration. Surprisingly, analysis of inclusion formation in the mutant Purkinje cells indicated the lysosomal localization of accumulated mutant Ca(v)2.1 channels in the absence of autophagic response. The lack of cathepsin B, a major lysosomal cysteine proteinase, exacerbated the loss of Purkinje cells and was accompanied by an acceleration of inclusion formation in this model. Thus, the pathogenic mechanism of SCA6 involves the endolysosomal degradation pathway, and unique pathological features of this model further illustrate the pivotal role of protein context in the pathogenesis of polyglutamine diseases.

CADASIL with a novel NOTCH3 mutation (Cys478Tyr).

Recently, an increasing number of NOTCH3 mutations have been described to cause cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL). Here, we report 2 CADASIL patients from a Japanese family, who were found to possess a novel NOTCH3 mutation. The proband only had chronic headache, and her mother had previously suffered a minor stroke. Although the patients' clinical symptoms were mild, their distinctive magnetic resonance imaging (MRI) features suggested CADASIL. Genetic analysis revealed that both patients had a novel heterozygous NOTCH3 mutation (p.Cys478Tyr) leading to stereotypical cysteine loss. The present finding suggests that genetic testing for NOTCH3 mutations in patients with distinctive MRI features, even if the symptoms are as mild as chronic headache, should help to broaden the mutational and clinical spectrum of CADASIL.

A case of dermatomyositis with rhabdomyolysis, rescued by intravenous immunoglobulin.

We describe a case of severe dermatomyositis (DM) complicated by rhabdomyolysis, acute tubular necrosis, and hemophagocytosis. The case failed to respond to corticosteroids, but showed rapid and significant improvement after the addition of intravenous immunoglobulin (IVIG). While the prognosis of DM is poor when it is complicated by rhabdomyolysis, the early administration of IVIG has the potential to be the cornerstone of its management.

Abnormal RNA structures (RNA foci) containing a penta-nucleotide repeat (UGGAA)n in the Purkinje cell nucleus is associated with spinocerebellar ataxia type 31 pathogenesis.

Spinocerebellar ataxia type 31 (SCA31) is an autosomal-dominant cerebellar ataxia showing a Purkinje cell (PC)-predominant neurodegeneration in humans. The mutation is a complex penta-nucleotide repeat containing (TGGAA)n , (TAGAA)n , (TAAAA)n and (TAGAATAAAA)n inserted in an intron shared by two different genes BEAN1 and TK2 located in the long arm of the human chromosome 16. Previous studies have shown that (TGGAA)n is the critical component of SCA31 pathogenesis while the three other repeats, also present in normal Japanese, are not essential. Importantly, it has been shown that BEAN1 and TK2 are transcribed in mutually opposite directions in the human brain. Furthermore, abnormal RNA structures called "RNA foci" are observed by a probe against (UAGAAUAAAA)n in SCA31 patients' PC nuclei, indicating that the BEAN1-direction mutant transcript appears instrumental for the pathogenesis. However, it is not known whether the critical repeat (TGGAA)n contributes to the formation of RNA foci, neither do we understand how the RNA foci formation is relevant to the pathogenesis. To address these issues, we investigated two SCA31 cerebella by fluorescence in situ hybridization using a probe against (UGGAA)n . We also asked whether the mutant BEAN1-transcript containing (UGGAA)n exerts toxicity compared to the other three repeats in cultured cells. Histopathologically, we confirm that the PC is the main target of SCA31 pathogenesis. We find that the RNA foci containing (UGGAA)n are indeed observed in PC nuclei of both SCA31 patients, whereas similar foci were not observed in control individuals. In both transiently and stably expressed cultured cell models, we also find that the mutation transcribed in the BEAN1-direction yields more toxicity than control transcripts and forms RNA foci detected with probes against (UGGAA)n and (UAGAAUAAAA)n . Taking these findings together, we conclude that the RNA foci containing BEAN1-direction transcript (UGGAA)n are associated with PC degeneration in SCA31.

How Certain Are You When Making the Diagnosis of Multiple System Atrophy?

Multiple system atrophy (MSA) is a multisystem neurodegenerative disorder affecting adults older than 30 years and presenting with a constellation of symptoms, including parkinsonian features, ataxia, and autonomic disturbances. The pathophysiology of MSA has gradually been unveiled. It is characterized by α-synuclein protein aggregates in neurons and glial cells that are different from those seen in Parkinson disease (PD).1 MSA is the most common condition, after PD, that has parkinsonism as a cardinal feature, and it is also one of the most common causes of sporadic cerebellar ataxias. Because the clinical presentation is heterogeneous, we as clinicians must always be certain of the probability of an MSA diagnosis for each patient we are facing.