Intercellular Propagation and Aggregate Seeding of Mutant Ataxin-1

Intercellular propagation of aggregated protein inclusions along actin-based tunneling nanotubes (TNTs) has been reported as a means of pathogenic spread in Alzheimer’s, Parkinson’s, and Huntington’s diseases. Propagation of oligomeric-structured polyglutamine-expanded ataxin-1 (Atxn1[154Q]) has been reported in the cerebellum of a Spinocerebellar ataxia type 1 (SCA1) knock-in mouse to correlate with disease propagation. In this study, we investigated whether a physiologically relevant polyglutamine-expanded ATXN1 protein (ATXN1[82Q]) could propagate intercellularly. Using a cerebellar-derived live cell model, we observed ATXN1 aggregates form in the nucleus, subsequently form in the cytoplasm, and finally, propagate to neighboring cells along actin-based intercellular connections. Additionally, we observed the facilitation of aggregate-resistant proteins into aggregates given the presence of aggregation-prone proteins within cells. Taken together, our results support a pathogenic role of intercellular propagation of polyglutamine-expanded ATXN1 inclusions.

Serum NfL in spinocerebellar ataxia type 1 is increased already at the preataxic stage, correlating with proximity to clinical onset

Background and Objectives. Neurofilament light (NfL) appears a promising fluid biomarker in repeat-expansion spinocerebellar ataxias (SCAs), with piloting studies in mixed SCA cohorts suggesting that NfL might be increased at the ataxic stage of spinocerebellar ataxia type 1 (SCA1). We here hypothesised that NfL is increased not only at the ataxic stage of SCA1, but also at its - likely most treatment-relevant - preataxic stage. Methods. We assessed serum (sNfL) and cerebrospinal fluid (cNfL) levels of NfL in both preataxic and ataxic SCA1, leveraging a multicentric cohort of 40 SCA1 carriers (23 preataxic, 17 ataxic) and >80 controls, and clinical follow-up data including actually observed (rather than only predicted) conversion to the ataxic stage (11 carriers). Results. sNfL levels were increased with high age-corrected effect sizes at the preataxic (r=0.62) and ataxic stage (r=0.63), paralleling increases of cNfL levels. In preataxic subjects, sNfL levels increased with proximity to predicted ataxia onset, with significant sNfL elevations already 5 years before onset, and confirmed in preataxic subjects with actually observed ataxia onset. sNfL increases were detected already in preataxic SCA1 subjects without volumetric atrophy of cerebellum or pons, suggesting that sNfL might be more sensitive to early preataxic neurodegeneration than the currently known most change-sensitive regions in volumetric MRI. Using longitudinal sNfL measurements, we estimated sample sizes for clinical trials using the reduction of sNfL as endpoint. Conclusions. sNfL levels might thus provide easily accessible peripheral biomarkers in both preataxic and ataxic SCA1, allowing stratification of preataxic subjects regarding proximity-to-onset, early detection of neurodegeneration even before volumetric MRI alterations, and potentially capture of treatment response in clinical trials.

Early stage of Spinocerebellar Ataxia Type 1 (SCA1) progression exhibits region- and cell-specific pathology and is partially ameliorated by Brain Derived Neurotrophic Factor (BDNF)

Spinocerebellar ataxia type 1 (SCA1) is a progressive neurodegenerative disease caused by an abnormal expansion of CAG repeats in the gene Ataxin1 (ATXN1) and characterized by motor deficits, cognitive decline, changes in affect, and premature lethality. Due to the severe cerebellar degeneration in SCA1, the pathogenesis of Purkinje cells has been the main focus of previous studies. However, mutant ATXN1 is expressed throughout the brain, and pathology in brain regions beyond the cerebellar cortex likely contribute to the symptoms of SCA1. Here, we investigate early-stage SCA1 alterations in neurons, astrocytes, and microglia in clinically relevant brain regions including hippocampus and brain stem of Atxn1154Q/2Q mice, a knock-in mouse model of SCA1 expressing mutant ATXN1 globally. Our results indicate shared and brain region specific astrocyte pathology early in SCA1 preceding neuronal loss. We found reduced expression of homeostatic astrocytic genes Kcnj10, Aqp4, Slc1a2 and Gja1, all of which are key for neuronal function in the hippocampus and brain stem. These gene expression changes did not correlate with classical astrogliosis. Neuronal and microglial numbers were largely unaltered at this early stage of SCA1 with the exception of cerebellar white matter, where we found significant reduction in microglial density, and the brain stem where we detected an increase in microglial cell counts. Brain-derived neurotrophic factor (BDNF) is a growth factor important for the survival and function of neurons with broad therapeutic potential for many brain diseases. We report here that BDNF expression is decreased in cerebellum and medulla of patients with SCA1. Moreover, we found that BDNF had dual effect on SCA1 and wild-type mice. Motor performance, strategy development, hippocampal neurogenesis, and expression of astrocyte homeostatic genes in the hippocampus were ameliorated in BDNF-treated SCA1 mice and further enhanced in BDNF-treated wild-type mice. On the other hand, BDNF had a negative effect on memory recall and expression of homeostatic genes in the brain stem astrocytes both in wild-type and in SCA1 mice.

Sphingolipid metabolism governs Purkinje cell patterned degeneration in Atxn1[82Q]/+ mice

Patterned degeneration of Purkinje cells (PCs) can be observed in a wide range of neuropathologies, but mechanisms behind nonrandom cerebellar neurodegeneration remain unclear. Sphingolipid metabolism dyshomeostasis typically leads to PC neurodegeneration; hence, we questioned whether local sphingolipid balance underlies regional sensitivity to pathological insults. Here, we investigated the regional compartmentalization of sphingolipids and their related enzymes in the cerebellar cortex in healthy and pathological conditions. Analysis in wild-type animals revealed higher sphingosine kinase 1 (Sphk1) levels in the flocculonodular cerebellum, while sphingosine-1-phosphate (S1P) levels were higher in the anterior cerebellum. Next, we investigated a model for spinocerebellar ataxia type 1 (SCA1) driven by the transgenic expression of the expanded Ataxin 1 protein with 82 glutamine (82Q), exhibiting severe PC degeneration in the anterior cerebellum while the flocculonodular region is preserved. In Atxn1[82Q]/+ mice, we found that levels of Sphk1 and Sphk2 were region-specific decreased and S1P levels increased, particularly in the anterior cerebellum. To determine if there is a causal link between sphingolipid levels and neurodegeneration, we deleted the Sphk1 gene in Atxn1[82Q]/+ mice. Analysis of Atxn1[82Q]/+; Sphk1−/− mice confirmed a neuroprotective effect, rescuing a subset of PCs in the anterior cerebellum, in domains reminiscent of the modules defined by AldolaseC expression. Finally, we showed that Sphk1 deletion acts on the ATXN1[82Q] protein expression and prevents PC degeneration. Taken together, our results demonstrate that there are regional differences in sphingolipid metabolism and that this metabolism is directly involved in PC degeneration in Atxn1[82Q]/+ mice.

Intercellular Propagation and Aggregate Seeding of Mutant Ataxin-1

Intercellular propagation of aggregated protein inclusions along actin-based tunneling nanotubes (TNTs) has been reported as a means of pathogenic spread in Alzheimer’s, Parkinson’s and Huntington’s Disease. Propagation of oligomeric-structured polyglutamine-expanded ataxin-1 (Atxn1[154Q]) has been reported in the cerebellum of a Spinocerebellar ataxia type 1 (SCA1) knock-in mouse to correlate with disease propagation. In this study, we investigated whether a physiologically-relevant polyglutamine-expanded ATXN1 protein (ATXN1[82Q]) could propagate intercellularly. Using a cerebellar-derived live cell model, we observed ATXN1 aggregates form in the nucleus, export out of the nucleus into the cytoplasm, and finally, propagate to neighboring cells along actin-based intercellular connections. Additionally, we observed the facilitation of aggregate-resistant proteins into aggregates given the presence of aggregation-prone proteins within a cell. Taken together, our results support a pathogenic role of intercellular propagation of polyglutamine-expanded ATXN1 inclusions.

Multimodal Retinal Imaging in Spinocerebellar Ataxia Type 1 Maculopathy

Objectives: The objective of the study was to investigate and report the multimodal ocular imaging findings associated with spinocerebellar ataxia type 1 (SCA 1) associated maculopathy. Methods: A full ophthalmologic assessment was completed in a 70-year-old male with confirmed SCA1 and noted progressive bilateral vision loss. Investigations included dilated fundus examination, full-field electroretinography, and swept-source optical coherence tomography (OCT). Results: On neurologic and ophthalmologic examination, he was found to have hypermetric saccades, horizontal nystagmus, and reduced color vision bilaterally. His best-corrected visual acuity was confirmed to be 20/80 OD and 20/100 OS at the time of consultation. Initial fundus photography was most notable for bilateral hypopigmentation of the fovea. Corresponding OCT imaging demonstrated an attenuation of the ellipsoid zone, in keeping with photoreceptor loss. Conclusion: The ocular imaging results suggest that the vision loss in the presented case occurred in the context of pigmentary macular dystrophy secondary to photoreceptor dysfunction and retinal pigment epithelial degeneration. This association offers an explanation with respect to the progressive vision loss, but further analyses would be required to determine the temporal correlation of clinical symptoms with imaging abnormalities. These findings suggest that SCA1 be considered as a potential cause for vision impairment, with possible benefits of visual assessment at the time of diagnosis.

Genetic Modeling of the Neurodegenerative Disease Spinocerebellar Ataxia Type 1 in Zebrafish

Dominant spinocerebellar ataxias (SCAs) are progredient neurodegenerative diseases commonly affecting the survival of Purkinje cells (PCs) in the human cerebellum. Spinocerebellar ataxia type 1 (SCA1) is caused by the mutated ataxin1 (Atx1) gene product, in which a polyglutamine stretch encoded by CAG repeats is extended in affected SCA1 patients. As a monogenetic disease with the Atx1-polyQ protein exerting a gain of function, SCA1 can be genetically modelled in animals by cell type-specific overexpression. We have established a transgenic PC-specific SCA1 model in zebrafish coexpressing the fluorescent reporter protein mScarlet together with either human wild type Atx1[30Q] as control or SCA1 patient-derived Atx1[82Q]. SCA1 zebrafish display an age-dependent PC degeneration starting at larval stages around six weeks postfertilization, which continuously progresses during further juvenile and young adult stages. Interestingly, PC degeneration is observed more severely in rostral than in caudal regions of the PC population. Although such a neuropathology resulted in no gross locomotor control deficits, SCA1-fish with advanced PC loss display a reduced exploratory behaviour. In vivo imaging in this SCA1 model may help to better understand such patterned PC death known from PC neurodegeneration diseases, to elucidate disease mechanisms and to provide access to neuroprotective compound characterization in vivo.