ABSTRACT
An unstable CAG triplet repeat expansion encoding a polyglutamine stretch within the ubiquitously expressed protein huntingtin is responsible for causing Huntington's disease (HD). By quantifying the repeat sizes of individual mutant alleles in tissues derived from an accurate genetic mouse model of HD we show that the mutation becomes very unstable in striatal tissue. The expansion-biased changes increase with age, such that some striatal cells from old HD mice contain mutations that have tripled in size. If this pattern of repeat instability is recapitulated in human striatal tissue, the concomitant increased polyglutamine load may contribute to the patterns of selective neuronal cell death in HD. Our findings also suggest that trinucleotide repeat instability can occur by mechanisms that are not replication-based.
Subject(s)
Corpus Striatum/metabolism , Huntington Disease/genetics , Mutation , Nerve Tissue Proteins/genetics , Nuclear Proteins/genetics , Peptides/metabolism , Trinucleotide Repeats , Alleles , Animals , Corpus Striatum/pathology , Female , Huntingtin Protein , Huntington Disease/metabolism , Huntington Disease/pathology , Male , Mice , Mice, Inbred C57BL , Nerve Degeneration , Nerve Tissue Proteins/metabolism , Neurons/metabolism , Neurons/pathology , Nuclear Proteins/metabolism , Peptides/genetics , Polymerase Chain ReactionABSTRACT
Huntington disease (HD) is caused by expansion of a glutamine repeat in the amino-terminal region of huntingtin. Despite its widespread expression, mutant huntingtin induces selective neuronal loss in striatal neurons. Here we report that, in mutant mice expressing HD repeats, the production and aggregation of N-terminal huntingtin fragments preferentially occur in HD-affected neurons and their processes and axonal terminals. N-terminal fragments of mutant huntingtin form aggregates and induce neuritic degeneration in cultured striatal neurons. N-terminal mutant huntingtin also binds to synaptic vesicles and inhibits their glutamate uptake in vitro. The specific processing and accumulation of toxic fragments of N-terminal huntingtin in HD-affected striatal neurons, especially in their neuronal processes and axonal terminals, may contribute to the selective neuropathology of HD.
Subject(s)
Corpus Striatum/metabolism , Nerve Tissue Proteins/metabolism , Neurons/metabolism , Nuclear Proteins/metabolism , Synaptic Vesicles/metabolism , Animals , Corpus Striatum/cytology , Corpus Striatum/ultrastructure , Huntingtin Protein , Mice , Mice, Mutant Strains , Mutation , Nerve Tissue Proteins/chemistry , Nerve Tissue Proteins/genetics , Neurites/metabolism , Neurites/pathology , Neurons/pathology , Neurons/ultrastructure , Nuclear Proteins/chemistry , Nuclear Proteins/genetics , Peptide Fragments/genetics , Peptide Fragments/metabolism , Peptides/genetics , Rats , Recombinant Fusion Proteins/genetics , Recombinant Fusion Proteins/metabolism , Synaptic Vesicles/pathology , Synaptic Vesicles/ultrastructureABSTRACT
Recent advances in the manipulation of mouse embryos provide opportunities for the disciplines of neuroscience and molecular genetics to join forces and tackle some previously intractable questions in this area of research. Even Huntington's disease has started to yield clues to its complex pathophysiology as a result of the recent application of transgenic technologies. This short review, while necessarily providing some background clinical information on Huntington's disease, will focus on how modifications of the mouse genome have contributed, and are continuing to contribute, to our understanding of the complex disease process. Such new insights may well turn the hope of developing the first effective treatment for this devastating disease into reality.
Subject(s)
Disease Models, Animal , Huntington Disease/genetics , Mice, Transgenic , Trinucleotide Repeats , Animals , Basal Ganglia/metabolism , Humans , Huntington Disease/metabolism , Mice , MutationABSTRACT
Huntington's disease (HD) is a dominant disorder characterized by premature and progressive neurodegeneration. In order to generate an accurate model of the disease, we introduced an HD-like mutation (an extended stretch of 72-80 CAG repeats) into the endogenous mouse Hdh gene. Analysis of the mutation in vivo reveals significant levels of germline instability, with expansions, contractions and sex-of-origin effects in evidence. Mice expressing full-length mutant protein display abnormal social behaviour in the absence of acute neurodegeneration. Given that psychiatric changes, including irritability and aggression, are common findings in HD patients, our data are consistent with the hypothesis that some clinical features of HD may be caused by pathological processes that precede gross neuronal cell death. This implies that effective treatment of HD may require an understanding and amelioration of these dysfunctional processes, rather than simply preventing the premature death of neurons in the brain. These mice should facilitate the investigation of the molecular mechanisms that underpin the pathway from genotype to phenotype in HD.
Subject(s)
Germ-Line Mutation/genetics , Huntington Disease/genetics , Mental Disorders/genetics , Mice, Mutant Strains/genetics , Nerve Tissue Proteins/genetics , Nuclear Proteins/genetics , Animals , Behavior, Animal , Brain/pathology , Female , Humans , Huntingtin Protein , Male , Mice , Mice, Inbred C57BL , Mice, Inbred Strains , Trinucleotide RepeatsABSTRACT
Cognitive impairment is an early symptom of Huntington's disease (HD). Mice engineered to carry the HD mutation in the endogenous huntingtin gene showed a significant reduction in long-term potentiation (LTP), a measure of synaptic plasticity often thought to be involved in memory. However, LTP could be induced in mutant slices by an 'enhanced' tetanic stimulus, implying that the LTP-producing mechanism is intact in mutant mice, but that their synapses are less able to reach the threshold for LTP induction. Mutant mice showed less post-tetanic potentiation than wild-type animals, and also showed decreased paired pulse facilitation, suggesting that excitatory synapses in HD mutant mice are impaired in their ability to sustain transmission during repetitive stimulation. We show that mutants, while normal in their ability to transmit at low frequencies, released significantly less glutamate during higher frequency synaptic activation. Thus, a reduced ability of Huntington synapses to respond to repetitive synaptic demand of even moderate frequency could result not only in a functional impairment of LTP induction, but could also serve as a substrate for the cognitive symptoms that comprise the early-stage pathology of HD.