ABSTRACT
Formation of proteinaceous deposits composed of abnormally aggregated proteins characterizes a range of pathological conditions. Proteinaceous inclusions detected in the neurodegenerative conditions such Huntington’s chorea (HD) and Alzheimer’s disease (AD) are often referred as pathognomic and regarded as causally implicated. Despite of differences in aetiology and underlying genetics, rare cases of combined HD and AD were reported and described as admixed proteinopathies. Mixed proteopathies are characterized by the co-occurrence of at least two types of abnormal aggregation-prone variants; pathological deposition of proteinaceous inclusions might however, affect different cell populations. Here, combining plaques derived from human ß-amyloid with mutant HTT-like polyglutamine inclusions in a cell-autonomous manner, we report on the Caenorhabditis elegans model for admixed proteinopathy of Alzheimer’s and Huntington’s type. We show both types of intracellular foci are formed in vivo: non-amyloidic extended polyglutamine derived inclusions and distinguish those from the presence of mature ß- amyloid fibers. We found that polyglutamines expanded above pathogenic threshold and ß-amyloid act synergistically to promote the progression of proteotoxicity in a temperature dependent manner. We further, implicate the hsp-1 (the predominant C. elegans chaperone interacting with ER-routed Aß42) modulate the proteotoxic insults observed in combined proteopathy model. Our results demonstrate how the in vivo model of admixed proteopathy could be utilized to probe for human pathogenic variants confined to the same cellular type. In that perspective expanded aggregation-prone polyglutamines appended with fluorescent proteins could be regarded as ‘pathogenic probes’ useful in the proteotoxicity assays i.e. involving ß-amyloid and possibly other comparable models of disease-associated aggregation prone variants.We anticipate models of combined proteopathies will be informative regarding the underlying pathogenesis and provide the sensitized background for sophisticated screening. For example the combinatorial effects of multiple pathogenic aggregation-prone variants could be tested against mutant backgrounds and pharmacological compounds. Furthermore, we surmise the postulated synergistic actions might explain some of the overlaps in observed progression of clinical symptoms in HD and AD. We also formulate the conjecture regarding the polyQ containing proteins as a contributing factor in degenerative conditions associated with increased ß-amyloid formation and deposition.
Footnotes
Abbreviations: HD – Huntington disease; AD – Alzheimer disease; HTT – huntingtin; APP - amyloid precursor protein; Aß42 – ß-amyloid peptide; ER - endoplasmic reticulum; HSP – heat shock protein; YFP - yellow fluorescent protein; co-IP – co-immunoprecipitation; RNAi – RNA interference; polyQ - polyglutamine