Polyglutamine (polyQ) diseases are genetically inherited neurodegenerative disorders. They are caused by mutations that result in polyQ expansions of particular proteins. Mutant proteins form intranuclear aggregates, induce cytotoxicity and cause neuronal cell death. Protein interaction data suggest that polyQ regions modulate interactions between coiled‐coil (CC) domains. In the case of the polyQ disease spinocerebellar ataxia type‐1 (SCA1), interacting proteins with CC domains further enhance aggregation and toxicity of mutant ataxin‐1 (ATXN1). Here, we suggest that CC partners interacting with the (...) polyQ region of a mutant protein, increase its aggregation while partners that interact with a different region reduce the formation of aggregates. Computational analysis of genetic screens revealed that CC‐rich proteins are highly enriched among genes that enhance pathogenicity of polyQ proteins, supporting our hypothesis. We therefore suggest that blocking interactions between mutant polyQ proteins and their CC partners might constitute a promising preventive strategy against neurodegeneration. (shrink)

Activating the ERK pathway (extracellular signal‐regulated kinase pathway) has proven beneficial in several models of Huntington's disease (HD), and drugs that are protective in HD models have recently been found to activate ERK. Thus, the ERK cascade may be a potential target for therapeutic intervention in this currently untreatable disorder. HD is caused by an expanded polyglutamine repeat in the huntingtin (Htt) protein that actuates a diverse set of pathogenic mechanisms. In response to mutant Htt, ERK is activated and (...) directs a protective transcriptional response and inhibits caspase activation. Paradoxically, Htt also interferes with several signaling events of the ERK pathway. Mutant Htt compromises the ERK‐dependent transcriptional response to corticostriatal BDNF signaling. Mutant Htt also hinders glutamate uptake from the synaptic cleft by down‐regulating ERK‐dependent expression of glutamate transporters, leaving cells vulnerable to excitotoxicity. Some of this cellular complexity can be capitalized on to achieve selective activation of ERK, which can be protective. (shrink)

Glutamine repeat expansion has been established as the mutation underlying five inherited neurodegenerative diseases. The mechanism by which this apparently universal mutation, in ubiquitously expressed proteins, causes highly selective neurodegeneration is unknown. The proteins containing the glutamine expansions are otherwise unrelated and likely to have different functions. Two recently published papers(1,2) provide evidence of a conformational change occurring in polyglutamine expansions, which may allow novel interactions and is consistent with a toxic gain‐of‐function hypothesis. HAP1, a protein that interacts with (...) huntingtin (Huntington's disease protein), has an expression profile that intriguingly mirrors the selective neurodegeneration seen in Huntington's disease(2). (shrink)