Several hereditary neurological and neuromuscular diseases are caused by an abnormal expansion of trinucleotide repeats. To date, there have been ten of these trinucleotide repeat disorders associated with an expansion of the codon CAG encoding glutamine (Q). For these polyglutamine (polyQ) diseases, there is a critical threshold length of the CAG repeat required for disease, and further expansion beyond this threshold is correlated with age of onset and symptom severity. PolyQ expansion in the translated proteins promotes their self-assembly into a variety of oligomeric and fibrillar aggregate species that accumulate into the hallmark proteinaceous inclusion bodies associated with each disease. Here, we review aggregation mechanisms of proteins with expanded polyQ-tracts, structural consequences of expanded polyQ ranging from monomers to fibrillar aggregates, the impact of protein context and post translational modifications on aggregation, and a potential role for lipids membranes in aggregation. As the pathogenic mechanisms that underlie these disorders are often classified as either a gain of toxic function or loss of normal protein function, some toxic mechanisms associated with mutant polyQ tracts will also be discussed.
Huntington's disease (HD), a genetic neurodegenerative disease, is caused by an expanded polyglutamine (polyQ) domain in the first exon of the huntingtin protein (htt). PolyQ expansion destabilizes protein structure, resulting in aggregation into a variety of oligomers, protofibrils, and fibrils. Beyond the polyQ domain, adjacent protein sequences influence the aggregation process. Specifically, the first 17 N-terminal amino acids (Nt17) directly preceding the polyQ domain promote the formation of α-helix-rich oligomers that represent intermediate species associated with fibrillization. Due to its propensity to form an amphipathic α-helix, Nt17 also facilitates lipid binding. Three lysine residues (K6, K9, and K15) within Nt17 can be SUMOylated, which modifies htt's accumulation and toxicity within cells in a variety of HD models. The impact of SUMOylation on htt aggregation and direct interaction with lipid membranes was investigated. SUMOylation of htt-exon1 inhibited fibril formation while promoting larger, amorphous aggregate species. These amorphous aggregates were SDS soluble but nonetheless exhibited levels of β-sheet structure similar to that of htt-exon1 fibrils. In addition, SUMOylation prevented htt binding, aggregation, and accumulation on model lipid bilayers comprised of total brain lipid extract. Collectively, these observations demonstrate that SUMOylation promotes a distinct htt aggregation pathway that may affect htt toxicity.
Expansion of a polyglutamine (polyQ) domain
within the first exon of the huntingtin (htt) protein is the underlying
cause of Huntington’s disease, a genetic neurodegenerative
disorder. PolyQ expansion triggers htt aggregation into oligomers,
fibrils, and inclusions. The 17 N-terminal amino acids (Nt17) of htt-exon1,
which directly precede the polyQ domain enhances polyQ fibrillization
and functions as a lipid-binding domain. A variety of post-translational
modifications occur within Nt17, including oxidation of two methionine
residues. Here, the impact of oxidation within Nt17 on htt aggregation
both in the presence and absence of lipid membranes was investigated.
Treatment with hydrogen peroxide (H2O2) reduced
fibril formation in a dose-dependent manner, resulting in shorter
fibrils and an increased oligomer population. With excessive H2O2 treatments, fibrils developed a unique morphological
feature around their periphery. In the presence of total brain lipid
vesicles, H2O2 impacted fibrillization in a
similar manner. That is, oligomerization was promoted at the expense
of fibril elongation. The interaction of unoxidized and oxidized htt
with supported lipid bilayers was directly observed using in situ
atomic force microscopy. Without oxidation, granular htt aggregates
developed on the bilayer surface. However, in the presence of H2O2, distinct plateau-like regions initially developed
on the bilayer surface that gave way to rougher patches containing
granular aggregates. Collectively, these observations suggest that
oxidation of methionine residues within Nt17 plays a crucial role
in both the aggregation of htt and its ability to interact with lipid
surfaces.
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