Abstract
Many diverse human diseases are associated with protein aggregation in ordered fibrillar structures called amyloid. Amyloid formation may mediate aberrant protein interactions that culminate in neurodegeneration in Alzheimer, Huntington, and Parkinson diseases and in prion encephalopathies. Studies of protein aggregation in the brain are hampered by limitations in imaging techniques and often require invasive methods that can only be performed postmortem. Here we describe transgenic mice in which aggregation-prone proteins that cause Huntington and Parkinson disease are expressed in the ocular lens. Expression of a mutant huntingtin fragment or alpha-synuclein in the lens leads to protein aggregation and cataract formation, which can be monitored in real time by noninvasive, highly sensitive optical techniques. Expression of a mutant huntingtin fragment in mice lacking the major lens chaperone, alphaB-crystallin, markedly accelerated the onset and severity of aggregation, demonstrating that the endogenous chaperone activity of alphaB-crystallin suppresses aggregation in vivo. These novel mouse models will facilitate the characterization of protein aggregation in vivo and are being used in efficient and economical screens for chemical and genetic modifiers of disease-relevant protein aggregation.
Highlights
Disease (HD), is the lack of cost-effective animal models for rapid tests of drug bioavailability, pharmacokinetics, and efficacy
A neuropathological hallmark of HD is intranuclear and cytoplasmic inclusion bodies that contain a mutant form of huntingtin, the protein encoded by IT-15 [2]
Expression of Mutant htt Fragments or ␣-Synuclein in the Lens Causes Cataract Formation—We generated transgenic mice that express htt exon 1 with a polyQ repeat in the normal (25Q) and disease-causing (46Q, 72Q, 97Q) range fused at the carboxyl terminus to green fluorescent protein (GFP) under the control of the lens-specific
Summary
Generation of Transgenic Mice—To generate mice expressing mutant htt fragments with 25Q, 46Q, 72Q, and 97Q, the first exon of the IT-15 gene with DNA sequence encoding selected polyglutamine (polyQ) repeat lengths (25Q, 46Q, 72Q, or 97Q) fused to enhanced green fluorescent protein (GFP) at the carboxyl terminus was excised from parental vectors [7] with Bsp120I, filled in with Klenow, and gel-purified. To generate GFP, wild-type ␣-synuclein (␣-Syn-WT), and ␣-Syn-A53T mice, a vector containing the chicken B1-crystallin promoter [9], was digested with XbaI and XhoI, treated with shrimp alkaline phosphatase, and gel-purified before DNA ligations. DNA sequences encoding ␣-Syn-WT and ␣-SynA53T fused to GFP were excised from p426GPD vectors [10] with SpeI and XhoI and were gel-purified. Lenses of ␣-Syn-WT and ␣-Syn-A53T mice contain a large opacity, whereas the mouse that expresses GFP alone has no opacity/cataract
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