CAG repeat expansion in an italian family with spinocerebellar ataxia type 2 (SCA2): a clinical and genetic study

Neurophysiological features in spinocerebellar ataxia type 2: Prospects for novel biomarkers

Electrophysiological biomarkers are useful to assess the degeneration and progression of the nervous system in pre-ataxic and ataxic stages of the Spinocerebellar Ataxia Type 2 (SCA2). These biomarkers are essentially defined by their clinical significance, discriminating patients and/or preclinical subjects from healthy controls in cross-sectional studies, their significant changes over time in longitudinal studies, and their correlation with the cytosine-guanine-adenine (CAG) repeat expansion and/or clinical ataxia scores, time of evolution and time to ataxia onset. We classified electrophysiological biomarkers into three main types: (1) preclinical, (2) disease progression and (3) genetic damage. We review the data that identify sural nerve potential amplitude, maximum saccadic velocity, sleep efficiency, rapid eye movement (REM) sleep percentage, K-complex density, REM sleep without atonia percentage, corticomuscular coherence, central motor conduction time, visual P300 latency, and antisaccadic error correction latency as reliable preclinical, progression and/or genetic damage biomarkers of SCA2. These electrophysiological biomarkers will facilitate the conduction of clinical trials that test the efficacy of emerging treatments in SCA2.

Phenotypic and molecular diversities of spinocerebellar ataxia type 2 in Japan

BACKGROUND

We intended to clarify the phenotypic and molecular diversities of spinocerebellar ataxia type 2 (SCA2) in Japan.

METHODS

DNA was extracted from the peripheral blood of 436 patients, including 126 patients with chronic neuropathy, 108 with amyotrophic lateral sclerosis, and 202 with cerebellar ataxia. We then PCR-amplified and sequenced the ATXN2 gene. The biopsied sural nerves of mutation-positive patients were subjected to light-microscopic and electron-microscopic analyses. Transfection analyses were performed using a Schwann cell line, IMS32.

RESULTS

We found PCR-amplified products potentially corresponding to expanded CAG repeats in four patients. Two patients in the chronic neuropathy group had a full repeat expansion or an intermediate expansion (39 or 32 repeats), without limb ataxia. The sural nerve biopsy findings of the two patients included axonal neuropathy and mixed neuropathy (axonal changes with demyelination). Schwann cells harbored either cytoplasmic or nuclear inclusions on electron microscopic examination. Both patients recently exhibited pyramidal signs. In the third patient in the cerebellar ataxia group, we identified a novel 21-base duplication mutation near 22 CAG repeats (c.432_452dup). The transfection study revealed that the 21-base-duplication mutant Ataxin-2 proteins aggregated in IMS32 and rendered cells susceptible to oxidative stress, similar to a CAG-expanded mutant. The fourth patient, with 41 repeats, had ataxia and spasticity. The two patients with cerebellar ataxia also had peripheral neuropathy.

CONCLUSIONS

Patients with expanded CAG repeats can exhibit a neuropathy-dominant phenotype not described previously. The novel 21-base-duplication mutant seems to share the aggregation properties of polyglutamine-expanded mutants.

Peripheral Neuropathy in Spinocerebellar Ataxia Type 1, 2, 3, and 6

Spinocerebellar ataxias (SCAs) are characterized by autosomal dominantly inherited progressive ataxia but are clinically heterogeneous due to variable involvement of non-cerebellar parts of the nervous system. Non-cerebellar symptoms contribute significantly to the burden of SCAs, may guide the clinician to the underlying genetic subtype, and might be useful markers to monitor disease. Peripheral neuropathy is frequently observed in SCA, but subtype-specific features and subclinical manifestations have rarely been evaluated. We performed a multicenter nerve conduction study with 162 patients with genetically confirmed SCA1, SCA2, SCA3, and SCA6. The study proved peripheral nerves to be involved in the neurodegenerative process in 82 % of SCA1, 63 % of SCA2, 55 % of SCA3, and 22 % of SCA6 patients. Most patients of all subtypes revealed affection of both sensory and motor fibers. Neuropathy was most frequently of mixed type with axonal and demyelinating characteristics in all SCA subtypes. However, nerve conduction velocities of SCA1 patients were slower compared to other genotypes. SCA6 patients revealed less axonal damage than patients with other subtypes. No influence of CAG repeat length or biometric determinants on peripheral neuropathy could be identified in SCA1, SCA3, and SCA6. In SCA2, earlier onset and more severe ataxia were associated with peripheral neuropathy. We proved peripheral neuropathy to be a frequent site of the neurodegenerative process in all common SCA subtypes. Since damage to peripheral nerves is readily assessable by electrophysiological means, nerve conduction studies should be performed in a longitudinal approach to assess these parameters as potential progression markers.

Intermediate-length polyglutamine in ATXN2 is a possible risk factor among Eastern Chinese patients with amyotrophic lateral sclerosis

An effective treatment for amyotrophic lateral sclerosis (ALS) has not yet been found because the pathogenesis of this fatal disease is not well understood. A number of previous studies demonstrated that intermediate-length polyglutamine repeats within the ataxin-2 gene (ATXN2) might be a risk factor among patients with ALS in Western countries. Here, we aim to determine whether this sequence is a risk factor in Eastern Chinese ALS patients. Therefore, 379 unrelated sporadic ALS patients, 15 unrelated familial ALS patients, and 900 neurologically normal controls were studied. The ATXN2 CAG repeats were amplified using polymerase chain reaction. The products were separated on an 8% polyacrylamide gel and confirmed using Sanger sequencing. The results were evaluated using SPSS 17.0. We found that ATXN2 intermediate-length polyglutamine expansions greater than 24 and 27 repeats were associated with sporadic ALS. Our finding supports the hypothesis that ATXN2 plays an important role in the pathogenesis of ALS.

Neuropathological staging of spinocerebellar ataxia type 2 by semiquantitative 1C2-positive neuron typing. Nuclear translocation of cytoplasmic 1C2 underlies disease progression of spinocerebellar ataxia type 2

Spinocerebellar ataxia type 2 (SCA2) is a hereditary neurodegenerative disorder caused by the expansion of the trinucleotide CAG repeats encoding elongated polyglutamine tract in ataxin-2, the SCA2 gene product. Polyglutamine diseases comprise nine genetic entities, including seven different forms of spinocerebellar ataxias, Huntington's disease, and spinal and bulbar muscular atrophy. These are pathologically characterized by neuronal loss and intranuclear aggregates or inclusions of mutant proteins including expanded polyglutamine in selected neuronal groups. Previously, we examined immunolocalization of ubiquitin, expanded polyglutamine (probed by 1C2 antibody), and ataxin-2 in genetically confirmed SCA2 patients. In the present study, we expanded this approach by distinguishing different patterns of subcellular 1C2 immunoreactivity ("granular cytoplasmic," "cytoplasmic and nuclear" and "nuclear with inclusions.") and by quantifying their regional frequencies in three autopsied SCA2 brains at different stage of the disease. Comparison with neuronal loss and gliosis revealed that overall 1C2 immunoreactivity was paralleled with their severity. Furthermore, appearance of granular cytoplasmic pattern corresponded to early stage, cytoplasmic and nuclear pattern to active stage, and nuclear with inclusions pattern to final stage. We conclude that this 1C2-immunoreactive typing may be useful for evaluating the overall severity and extent of affected regions and estimating the neuropathological stage of SCA2.

Spinocerebellar ataxia 2 (SCA2)

Spinocerebellar ataxia type 2 (SCA2) is an autosomal dominantly inherited, neurodegenerative disease. It can manifest either with a cerebellar syndrome or as Parkinson's syndrome, while later stages involve mainly brainstem, spinal cord and thalamus. This particular atrophy pattern resembles sporadic multi-system-atrophy (MSA) and results in some clinical features indicative of SCA2, such as early saccade slowing, early hyporeflexia, severe tremor of postural or action type, and early myoclonus. For treatment, levodopa is temporarily useful for rigidity/bradykinesia and for tremor, magnesium for muscle cramps, but neuroprotective therapy will depend on the elucidation of pathogenesis. The disease cause lies in the polyglutamine domain of the protein ataxin-2, which can expand in families over successive generations resulting in earlier onset age and faster progression. Genetic testing in SCA2 and other polyglutamine disorders like the well-studied Huntington's disease is now readily available for family planning. Although these disorders differ clinically and in the affected neuron populations, it is not understood how the different polyglutamine proteins mediate such tissue specificity. The neuronal intranuclear inclusion bodies described in other polyglutamine disorders are not frequent in SCA2. For the quite ubiquitously expressed ataxin-2, a subcellular localization at the Golgi, the endoplasmic reticulum and the plasma membrane, in interaction with proteins of mRNA translation and of endocytosis have been observed. As a first victim of SCA2 degeneration, cerebellar Purkinje neurons may be preferentially susceptible to alterations of these subcellular pathways, and therefore our review aims to portray the particular profile of the SCA2 disease process and correlate it to the specific features of ataxin-2.

Varied electrophysiologic patterns in spinocerebellar ataxia type 2

The autosomal dominant ataxias are a heterogenous group of disorders. Almost 30 different genetic loci have been identified. Spinocerebellar ataxia type 2 (SCA2) is one of many autosomal dominant cerebellar ataxias. Electrophysiologic studies in SCA2 have shown mainly a sensory neuropathy or neuronopathy. To determine if electrophysiologic testing reveals concomitant or isolated involvement of motor nerves in SCA2 we reviewed historic and electrophysiologic data on all cases of genetically confirmed SCA2 who underwent nerve conduction studies and needle electromyographic during initial evaluation at our institution. We performed electrophysiologic studies in six genetically confirmed, unrelated, cases of SCA2 and discovered that in three patients, there were findings consistent with motor neuronopathy or neuropathy without sensory involvement. One patient had normal results and only one had a pure sensory neuropathy or neuronopathy. The sixth patients had mixed sensorimotor neuropathy. This is the first study that demonstrates isolated involvement of motor neurons and/or axons occur in SCA2. Therefore, electrophysiologic findings in SCA2 are not limited to mainly a sensory neuropathy but are varied and can even mimic slowly progressive motor neuron disease.

Characterization of ataxias with magnetic resonance imaging and spectroscopy

A wide variety of autosomal transmitted ataxias exist and their ultimate characterization requires genetic testing. Common clinical characteristics among different ataxia types complicate the choice of the appropriate genetic test. Magnetic resonance imaging (MRI) and magnetic resonance spectroscopy (MRS) generally show cerebellar or cerebral atrophy and perturbed metabolite levels which differ between ataxias. In order to help the clinician accurately identify the ataxia type, reported MRI and MRS data in different brain regions are summarized for more than 60 different types of autosomal inherited and sporadic ataxias.

Genetic testing for ataxia in North America

BACKGROUND

The Ataxia Molecular Diagnostics Testing Group was established to generate quantitative proficiency and outcomes data regarding molecular testing for the autosomal dominant cerebellar ataxias (spinocerebellar ataxia types 1 [SCA-1] through -3, -6, and -7, and dentatorubral-pallidoluysian atrophy) in North America.

METHODS AND RESULTS

Twenty-four North American laboratories that offered diagnostic testing for one or more ataxia genes were initially identified through GeneTests (Children's Health Care System, Seattle, WA). Eighteen laboratories agreed to participate in the study, which consisted of completing a technical survey, clinical survey, and molecular proficiency test. One laboratory returned the completed surveys but did not perform the proficiency testing. Ten of 18 laboratories (56%) provided data on test volumes, and these laboratories collectively performed 2,240 tests; approximately 5% of the tests yielded a positive result (i.e., identification of a pathological trinucleotide (CAG) repeat expansion). In proficiency testing, 100% of the laboratories correctly genotyped all samples, and 93% of the laboratories were within 1 SD of the mean for sizing normal alleles (one repeat unit or less). Ninety percent of the laboratories were within 1 SD for sizing expanded alleles.

CONCLUSIONS

Proficiency testing showed little difference between laboratories with respect to allele sizing. However, additional phenotype/genotype correlations are necessary to define CAG repeat-length descriptors for SCA-1, SCA-2, and SCA-7 alleles of intermediate size.