Protein aggregation is a key mechanism involved in neurodegeneration associated with Alzheimer's, Parkinson's and Huntington's diseases. Nine diseases (including Huntington's) arise from polyglutamine (polyQ) expansion above a repeat threshold of approximately 37 glutamines, and neuronal toxicity correlates with the process of protein aggregation. The similar toxic gain-of-function mechanism of the nine diseases supports the hypothesis that disease onset and progression is dependent upon polyQ expansion. However, there is an increasing body of literature demonstrating that the protein context of the polyQ tract has an essential role in the disease process. The composition of regions flanking repeats can alter the biochemical and biophysical properties of the polyQ region. A number of the disease proteins are proteolytically cleaved, with release of the polyQ-containing fragment initiating aggregation. Interactions of flanking domains with other molecules can also influence aggregation and cellular localization, which are critical factors for toxicity. More recently, there is evidence that domains flanking the polyQ tract can also aggregate independent of the polyQ tract, and that this significantly alters the rate at which the polyQ regions form fibrillar aggregates and the properties of these aggregates. In this review we consider the role of protein context in modulating the polyQ diseases and the therapeutic potential of targeting non-polyQ protein properties.