Brain pathology of spinocerebellar ataxias.

The autosomal dominant cerebellar ataxias (ADCAs) represent a heterogeneous group of neurodegenerative diseases with progressive ataxia and cerebellar degeneration. The current classification of this disease group is based on the underlying genetic defects and their typical disease courses. According to this categorization, ADCAs are divided into the spinocerebellar ataxias (SCAs) with a progressive disease course, and the episodic ataxias (EA) with episodic occurrences of ataxia. The prominent disease symptoms of the currently known and genetically defined 31 SCA types result from damage to the cerebellum and interconnected brain grays and are often accompanied by more specific extra-cerebellar symptoms. In the present review, we report the genetic and clinical background of the known SCAs and present the state of neuropathological investigations of brain tissue from SCA patients in the final disease stages. Recent findings show that the brain is commonly seriously affected in the polyglutamine SCAs (i.e. SCA1, SCA2, SCA3, SCA6, SCA7, and SCA17) and that the patterns of brain damage in these diseases overlap considerably in patients suffering from advanced disease stages. In the more rarely occurring non-polyglutamine SCAs, post-mortem neuropathological data currently are scanty and investigations have been primarily performed in vivo by means of MRI brain imaging. Only a minority of SCAs exhibit symptoms and degenerative patterns allowing for a clear and unambiguous diagnosis of the disease, e.g. retinal degeneration in SCA7, tau aggregation in SCA11, dentate calcification in SCA20, protein depositions in the Purkinje cell layer in SCA31, azoospermia in SCA32, and neurocutaneous phenotype in SCA34. The disease proteins of polyglutamine ataxias and some non-polyglutamine ataxias aggregate as cytoplasmic or intranuclear inclusions and serve as morphological markers. Although inclusions may impair axonal transport, bind transcription factors, and block protein quality control, detailed molecular and pathogenetic consequences remain to be determined.

HSPB7 is the most potent polyQ aggregation suppressor within the HSPB family of molecular chaperones.

A small number of heat-shock proteins have previously been shown to act protectively on aggregation of several proteins containing an extended polyglutamine (polyQ) stretch, which are linked to a variety of neurodegenerative diseases. A specific subfamily of heat-shock proteins is formed by the HSPB family of molecular chaperones, which comprises 10 members (HSPB1-10, also called small HSP). Several of them are known to act as anti-aggregation proteins in vitro. Whether they also act protectively in cells against polyQ aggregation has so far only been studied for few of them (e.g. HSPB1, HSPB5 and HSPB8). Here, we compared the 10 members of the human HSPB family for their ability to prevent aggregation of disease-associated proteins with an expanded polyQ stretch. HSPB7 was identified as the most active member within the HSPB family. It not only suppressed polyQ aggregation but also prevented polyQ-induced toxicity in cells and its expression reduces eye degeneration in a Drosophila polyQ model. Upon overexpression in cells, HSPB7 was not found in larger oligomeric species when expressed in cells and-unlike HSPB1-it did not improve the refolding of heat-denatured luciferase. The action of HSPB7 was also not dependent on the Hsp70 machine or on proteasomal activity, and HSPB7 overexpression alone did not increase autophagy. However, in ATG5-/- cells that are defective in macroautophagy, the anti-aggregation activity of HSPB7 was substantially reduced. Hence, HSPB7 prevents toxicity of polyQ proteins at an early stage of aggregate formation by a non-canonical mechanism that requires an active autophagy machinery.

Gene expression profiling in ataxin-3 expressing cell lines reveals distinct effects of normal and mutant ataxin-3.

Spinocerebellar ataxia type 3 (SCA3) is a late-onset neurodegenerative disorder caused by the expansion of a polyglutamine tract within the gene product, ataxin-3. We have previously shown that mutant ataxin-3 causes upregulation of inflammatory genes in transgenic SCA3 cell lines and human SCA3 pontine neurons. We report here a complex pattern of transcriptional changes by microarray gene expression profiling and Northern blot analysis in a SCA3 cell model. Twenty-three differentially expressed genes involved in inflammatory reactions, nuclear transcription, and cell surface-associated processes were identified. The identified corresponding proteins were analyzed by immunohistochemistry in human disease and control brain tissue to evaluate their implication in SCA3 pathogenesis. In addition to several inflammatory mediators upregulated in mutant ataxin-3 expressing cell lines and pontine neurons of SCA3 patients, we identified a profound repression of genes encoding cell surface-associated proteins in cells overexpressing normal ataxin-3. Correspondingly, these genes were upregulated in mutant ataxin-3 expressing cell lines and in pontine neurons of SCA3 patients. These findings identify for the first time target genes transcriptionally regulated by normal ataxin-3 and support the hypothesis that both loss of normal ataxin-3 and gain of function through protein-protein interacting properties of mutant ataxin-3 contribute to SCA3 pathogenesis.