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 | Ying, H. C., B. Hurle, et al. (1999). "High-resolution mapping of tlt, a mouse mutant lacking otoconia." Mamm Genome 10(6): 544-8.
The ability to sense gravity is enhanced by an extracellular structure that overlies the macular sensory epithelium. This complex consists of high density particles, otoconia, embedded within a gelatinous membrane. The tilted mouse specifically lacks otoconia, yet has no other detectable anatomic lesions. Furthermore, the penetrance of the tilted phenotype is nearly 100%. This mouse provides a model to identify genes that are involved in the development and function of vestibular otoconia. Using SSLP markers, we have mapped the tilted (tlt) gene on mouse Chromosome (Chr) 5 between D5Mit421 and D5Mit353/D5Mit128/D5Mit266/D5Mit267 by analysis of the progeny of an intersubspecific F2 intercross. We also mapped the fibroblast growth factor receptor 3 (Fgfr3) gene, a potential candidate for tlt, and the Huntington's disease homolog (Hdh) gene to D5Mit268, approximately 4.3 centiMorgans (cM) from the tilted locus. This study excludes both Fgfr3 and Hdh as candidate genes for tlt and identifies closely linked microsatellite markers that will be useful for the positional cloning of tlt.
Yen, L., S. M. Strittmatter, et al. (1999). "Sequence-specific cleavage of Huntingtin mRNA by catalytic DNA." Ann Neurol 46(3): 366-73.
The selective loss of neurons in Huntington's disease (HD) is caused by the abnormal expansion of the CAG triplet (>36 repeats) of the HD gene. Although the molecular events that lead to neuronal death are not clear, it is most likely that mutant HD protein operates through a "gain-of-function" mechanism. One possible therapeutic approach that does not require definition of the toxic mechanism(s) involves reduction in the levels of mutant HD protein by decreasing the quantity of translatable HD mRNA. In this report, we demonstrate the first effective destruction of the HD mRNA, using a catalytic DNA--an oligodeoxynucleotide with RNA-cleaving enzymatic activity. We show that the cleavage of HD mRNA by the catalytic DNA occurs in a sequence-specific manner, and leads to significant reduction of HD protein expression in mammalian cells. The catalytic DNAs we have developed are a valuable research tool for studying HD, and may have the therapeutic potential of reducing cellular toxicity caused by mutant HD protein.
Yang, S., M. J. Cope, et al. (1999). "Sla2p is associated with the yeast cortical actin cytoskeleton via redundant localization signals." Mol Biol Cell 10(7): 2265-83.
Sla2p, also known as End4p and Mop2p, is the founding member of a widely conserved family of actin-binding proteins, a distinguishing feature of which is a C-terminal region homologous to the C terminus of talin. These proteins may function in actin cytoskeleton-mediated plasma membrane remodeling. A human homologue of Sla2p binds to huntingtin, the protein whose mutation results in Huntington's disease. Here we establish by immunolocalization that Sla2p is a component of the yeast cortical actin cytoskeleton. Deletion analysis showed that Sla2p contains two separable regions, which can mediate association with the cortical actin cytoskeleton, and which can provide Sla2p function. One localization signal is actin based, whereas the other signal is independent of filamentous actin. Biochemical analysis showed that Sla2p exists as a dimer in vivo. Two-hybrid analysis revealed two intramolecular interactions mediated by coiled-coil domains. One of these interactions appears to underlie dimer formation. The other appears to contribute to the regulation of Sla2p distribution between the cytoplasm and plasma membrane. The data presented are used to develop a model for Sla2p regulation and interactions.
Wilkinson, F. L., T. M. Nguyen, et al. (1999). "Localization of rabbit huntingtin using a new panel of monoclonal antibodies." Brain Res Mol Brain Res 69(1): 10-20.
Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder caused by the expansion of a CAG repeat which is expressed as a polyglutamine tract near the N-terminus of the gene product, huntingtin. N-terminal huntingtin fragments form intranuclear aggregates in HD patients and these may be involved in the pathogenesis. Monoclonal antibodies (mAbs) against three different regions of huntingtin (amino acids 997-1276, 1844-2131 and 2703-2911) have been produced and two of the epitopes have been identified using phage displayed peptide libraries. All mAbs reacted with 350 kDa huntingtin on Western blots and one mAb from each region was selected for further study by strong immunoreactivity with neurons in different regions of rabbit brain and by ability to immunoprecipitate native huntingtin. Subcellular fractionation and sucrose density centrifugation of rabbit brain extract showed that most of the huntingtin exists as a high molecular weight complex in the cytoplasm. Two outstanding problems have been addressed; the location of huntingtin in tissues outside the central nervous system and whether huntingtin is present in the nucleus of normal cells. We conclude that huntingtin is present at low levels in most non-neuronal cells though we have identified an interstitial cell type in skin with very high immunoreactivity. Using both immunolocalization and nuclear purification methods, we were unable to exclude the possibility that a small proportion of full-length huntingtin is present in the nucleus.
Wheeler, V. C., W. Auerbach, et al. (1999). "Length-dependent gametic CAG repeat instability in the Huntington's disease knock-in mouse." Hum Mol Genet 8(1): 115-22.
The CAG repeats in the human Huntington's disease (HD) gene exhibit striking length-dependent intergenerational instability, typically small size increases or decreases of one to a few CAGs, but little variation in somatic tissues. In a subset of male transmissions, larger size increases occur to produce extreme HD alleles that display somatic instability and cause juvenile onset of the disorder. Initial efforts to reproduce these features in a mouse model transgenic for HD exon 1 with 48 CAG repeats revealed only mild intergenerational instability ( approximately 2% of meioses). A similar pattern was obtained when this repeat was inserted into exon 1 of the mouse Hdh gene. However, lengthening the repeats in Hdh to 90 and 109 units produced a graded increase in the mutation frequency to >70%, with instability being more evident in female transmissions. No large jumps in CAG length were detected in either male or female transmissions. Instead, size changes were modest increases and decreases, with expansions typically emanating from males and contractions from females. Limited CAG variation in the somatic tissues gave way to marked mosaicism in liver and striatum for the longest repeats in older mice. These results indicate that gametogenesis is the primary source of inherited instability in the Hdh knock-in mouse, as it is in man, but that the underlying repeat length-dependent mechanism, which may or may not be related in the two species, operates at higher CAG numbers. Moreover, the large CAG repeat increases seen in a subset of male HD transmissions are not reproduced in the mouse, suggesting that these arise by a different fundamental mechanism than the small size fluctuations that are frequent during gametogenesis in both species.
Warita, H., Y. Shiro, et al. (1999). "[Huntington's disease: clinical and molecular genetics]." Nippon Rinsho 57(4): 896-9.
Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder characterized by motor, cognitive, and psychiatric symptoms. An unstable CAG trinucleotide repeat expansion within the first exon of the responsible gene "IT15", encoding huntingtin, was identified. The clinical phenotype strongly correlates with the number of CAG repeat. The mutant huntingtin is expressed ubiquitously as same as the wild-type huntingtin, suggesting a toxic gain of function of the mutant huntingtin. The identification of huntingtin-interacting proteins and intranuclear aggregates containing a fragment of mutant huntingtin provide new insights into the pathophysiological mechanisms underlying HD. Moreover, the progress in transgenic animal models for HD will be critical for understanding the development of HD and for the testing of new therapeutics.
Wang, G. H., K. Mitsui, et al. (1999). "Caspase activation during apoptotic cell death induced by expanded polyglutamine in N2a cells." Neuroreport 10(12): 2435-8.
Huntington disease (HD) is an autosomal dominant neurodegenerative disorder. To investigate the mechanism of neurodegeneration induced by mutant huntingtin, we developed a stable neuro2a cell line expressing truncated N-terminal huntingtin (tNhtt) with EGFP using the ecdysone-inducible system. The formation of aggregates and the cell death induced by expression of tNhtt with expanded polyglutamine was repeat length- and dose-dependent. Caspases were activated, and the death substrates of caspases, lamin B and ICAD (an inhibitor of caspase-activated DNase), were cleaved in this cell death process. The cleavage of lamin B was inhibited by caspase inhibitors. These findings suggest that the cell death induced by tNhtt with expanded polyglutamine is mediated by caspases.
Usdin, M. T., P. F. Shelbourne, et al. (1999). "Impaired synaptic plasticity in mice carrying the Huntington's disease mutation." Hum Mol Genet 8(5): 839-46.
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.
Tanno, Y., T. Mori, et al. (1999). "Localization of huntingtin-interacting protein-2 (Hip-2) mRNA in the developing mouse brain." J Chem Neuroanat 17(2): 99-107.
Huntingtin-interacting protein-2 (Hip-2) was identified as a human protein specifically associated with huntingtin in vitro, a gene product affected in patients with Huntington disease (HD). It is a ubiquitin-conjugating enzyme identical to the previously characterized bovine E2-25k. We identified the mouse Hip-2 homologue (mHip-2) and examined its distribution patterns in the developing mouse brain in order to gain an insight into the functional significance of the Hip-2 protein in the normal brain as well as in the pathogenesis of HD. As reported with huntingtin, the mHip-2 mRNA expression developed in parallel with neuronal maturation and became distributed widely in the postnatal mouse brain. This spatiotemporal pattern of mHip-2 mRNA expression resembled that of huntingtin. We further demonstrated that mHip-2 mRNA was colocalized with huntingtin-like immunoreactivity in a single neuron. These findings suggested that the Hip-2 interacted with huntingtin in vivo and played an important role in HD pathogenesis.
Tabrizi, S. J., M. W. Cleeter, et al. (1999). "Biochemical abnormalities and excitotoxicity in Huntington's disease brain." Ann Neurol 45(1): 25-32.
The physiological role of huntingtin and the mechanisms by which the expanded CAG repeat in ITI5 and its polyglutamine stretch in mutant huntingtin induce Huntington's disease (HD) are unknown. Several techniques have now demonstrated abnormal metabolism in HD brain; direct measurement of respiratory chain enzyme activities has shown severe deficiency of complex II/III and a milder defect of complex IV. We confirm that these abnormalities appear to be confined to the striatum within the HD brain. Analysis of complex II/III activity in HD fibroblasts was normal, despite expression of mutant huntingtin. Although glyceraldehyde 3-phosphate dehydrogenase (a huntingtin binding protein) activity was normal in all areas studied, aconitase activity was decreased to 8% in HD caudate, 27% in putamen, and 52% in cerebral cortex, but normal in HD cerebellum and fibroblasts. We have demonstrated that although complexes II and III are those parts of the respiratory chain most vulnerable to inhibition in the presence of a nitric oxide (NO*) generator, aconitase activity was even more sensitive to inhibition. The pattern of these enzyme deficiencies and their parallel to the anatomical distribution of HD pathology support an important role for NO* and excitotoxicity in HD pathogenesis. Furthermore, based on the biochemical defects we have described, we suggest that NO* generation produces a graded response, with aconitase inhibition followed by complex II/III inhibition and the initiation of a self-amplifying cycle of free radical generation and aconitase inhibition, which results in severe ATP depletion. We propose that these events are important in determining neuronal cell death and are critical steps in the pathogenesis of HD.
Syed, V., E. Gomez, et al. (1999). "mRNAs encoding a von Ebner's-like protein and the Huntington disease protein are induced in rat male germ cells by Sertoli cells." J Biol Chem 274(16): 10737-42.
The success of spermatogenesis is dependent upon closely coordinated interactions between Sertoli cells and germ cells. To identify specific molecules that mediate interactions between somatic cells and germ cells in the rat testis, Sertoli cell-germ cell co-cultures and mRNA differential display were used. Two cDNAs, clone 1 (660 nucleotides) and clone 2 (390 nucleotides) were up-regulated when Sertoli cells were co-cultured with pachytene spermatocytes or round spermatids. Northern blot analyses confirmed the differential display expression patterns. Sequence analyses indicated that clone 1 was similar to a von Ebner's gland protein (87% at the nucleotide level and 80% at the amino acid level) and clone 2 was identical to a region of the Huntington disease protein. The von Ebner's-like protein mRNA was induced after 4 h of co-culture, while the Huntington disease protein required 18 h of co-culture for expression. The von Ebner's-like protein was induced in germ cells by a secreted Sertoli cell factor(s) smaller than 10 kDa that is sensitive to freezing and thawing or boiling. The Huntington disease protein was induced in germ cells by a Sertoli cell secreted factor(s) larger than 10 kDa which survives freezing and thawing, but is inactivated by boiling.
Sorensen, S. A., K. Fenger, et al. (1999). "Significantly lower incidence of cancer among patients with Huntington disease: An apoptotic effect of an expanded polyglutamine tract?" Cancer 86(7): 1342-6.
BACKGROUND: The authors of this study have previously observed that cancer is rarely reported on the death certificates of patients with Huntington disease. This study was undertaken to investigate whether this disorder is associated with a lower incidence of cancer. METHODS: A total of 694 patients with Huntington disease who had survived at least to age 45 years during the period 1943-1993, and 695 individuals at risk and at least age 55 years during the same period, were selected from the Danish Huntington Disease Registry. The occurrence of cancer was determined from the files of the Danish Cancer Registry and compared with national incidence rates for various categories of tumors. RESULTS: The overall incidence of cancer was significantly lower among patients with Huntington disease, but not among their healthy relatives. The standardized incidence ratio for the Huntington patients was 0.6 with a 95% confidence interval of 0.5-0.8. The lower incidence was seen for cancers of all major tissues and organs except the buccal cavity and the pharynx. CONCLUSIONS: The lower incidence of cancer among patients with Huntington disease seems to be related to intrinsic biologic factors. One explanation may be that the modified protein, huntingtin, encountered in Huntington disease protects against cancer by inducing or increasing the rate of naturally occurring programmed cell death in preneoplastic cells.
Sieradzan, K. A., A. O. Mechan, et al. (1999). "Huntington's disease intranuclear inclusions contain truncated, ubiquitinated huntingtin protein." Exp Neurol 156(1): 92-9.
Intranuclear inclusion bodies are a shared pathological feature of Huntington's disease (HD) and its transgenic mouse model. Using a panel of antibodies spanning the entire huntingtin molecule, we have investigated the pattern of immunoreactivity within the intranuclear inclusions in the frontal cortex and striatum of patients with HD. The intranuclear inclusions reacted with anti-ubiquitin and antibodies against the N-terminal portion of huntingtin (CAG53b, HP1), but not with HD1 and the 1C2 antibodies that detect the expanded polyglutamine tract nor the more C-terminal antibodies. However, the 1C2, HP1, CAG53b, and HD1 antibodies detected granular cytoplasmic deposits in cortical and striatal neurons that also contained intranuclear N-terminal huntingtin immunoreactivity. These data show a differential intracellular location of truncated huntingtin in the HD brain. Both the cytoplasmic and the nuclear aggregates of the protein fragments could be neurotoxic. The frequency of the cortical intranuclear inclusions correlated with the size of CAG expansion and was inversely related to the age at onset and death. No such correlations were detected for the striatum, which most likely reflects a more advanced neuronal loss accrued by the time of death.
Shelbourne, P. F., N. Killeen, et al. (1999). "A Huntington's disease CAG expansion at the murine Hdh locus is unstable and associated with behavioural abnormalities in mice." Hum Mol Genet 8(5): 763-74.
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.
Schilling, G., M. W. Becher, et al. (1999). "Intranuclear inclusions and neuritic aggregates in transgenic mice expressing a mutant N-terminal fragment of huntingtin." Hum Mol Genet 8(3): 397-407.
Huntington's disease (HD) is an inherited, neurodegenerative disorder caused by the expansion of a glutamine repeat in the N-terminus of the huntingtin protein. To gain insight into the pathogenesis of HD, we generated transgenic mice that express a cDNA encoding an N-terminal fragment (171 amino acids) of huntingtin with 82, 44 or 18 glutamines. Mice expressing relatively low steady-state levels of N171 huntingtin with 82 glutamine repeats (N171-82Q) develop behavioral abnormalities, including loss of coordination, tremors, hypokinesis and abnormal gait, before dying prematurely. In mice exhibiting these abnormalities, diffuse nuclear labeling, intranuclear inclusions and neuritic aggregates, all immunoreactive with an antibody to the N-terminus (amino acids 1-17) of huntingtin (AP194), were found in multiple populations of neurons. None of these behavioral or pathological phenotypes were seen in mice expressing N171-18Q. These findings are consistent with the idea that N-terminal fragments of huntingtin with a repeat expansion are toxic to neurons, and that N-terminal fragments are prone to form both intranuclear inclusions and neuritic aggregates.
Scherzinger, E., A. Sittler, et al. (1999). "Self-assembly of polyglutamine-containing huntingtin fragments into amyloid-like fibrils: implications for Huntington's disease pathology." Proc Natl Acad Sci U S A 96(8): 4604-9.
Huntington's disease is a progressive neurodegenerative disorder caused by a polyglutamine [poly(Q)] repeat expansion in the first exon of the huntingtin protein. Previously, we showed that N-terminal huntingtin peptides with poly(Q) tracts in the pathological range (51-122 glutamines), but not with poly(Q) tracts in the normal range (20 and 30 glutamines), form high molecular weight protein aggregates with a fibrillar or ribbon-like morphology, reminiscent of scrapie prion rods and beta-amyloid fibrils in Alzheimer's disease. Here we report that the formation of amyloid-like huntingtin aggregates in vitro not only depends on poly(Q) repeat length but also critically depends on protein concentration and time. Furthermore, the in vitro aggregation of huntingtin can be seeded by preformed fibrils. Together, these results suggest that amyloid fibrillogenesis in Huntington's disease, like in Alzheimer's disease, is a nucleation-dependent polymerization.
Sawa, A., G. W. Wiegand, et al. (1999). "Increased apoptosis of Huntington disease lymphoblasts associated with repeat length-dependent mitochondrial depolarization." Nat Med 5(10): 1194-8.
Huntington disease (HD) is a genetically dominant condition caused by expanded CAG repeats coding for glutamine in the HD gene product huntingtin. Although HD symptoms reflect preferential neuronal death in specific brain regions, huntingtin is expressed in almost all tissues, so abnormalities outside the brain might be expected. Although involvement of nuclei and mitochondria in HD pathophysiology has been suggested, specific intracellular defects that might elicit cell death have been unclear. Mitochondria dysfunction is reported in HD brains; mitochondria are organelles that regulates apoptotic cell death. We now report that lymphoblasts derived from HD patients showed increased stress-induced apoptotic cell death associated with caspase-3 activation. When subjected to stress, HD lymphoblasts also manifested a considerable increase in mitochondrial depolarization correlated with increased glutamine repeats.
Sathasivam, K., C. Hobbs, et al. (1999). "Formation of polyglutamine inclusions in non-CNS tissue." Hum Mol Genet 8(5): 813-22.
Huntington's disease (HD) is one of a class of inherited progressive neurodegenerative disorders that are caused by a CAG/polyglutamine repeat expansion. We have previously generated mice that are transgenic for exon 1 of the HD gene carrying highly expanded CAG repeats which develop a progressive movement disorder and weight loss with similarities to HD. Neuronal inclusions composed of the exon 1 protein and ubiquitin are present in specific brain regions prior to onset of the phenotype, which in turn occurs long before specific neurodegeneration can be detected. In this report we have extended the search for polyglutamine inclusions to non-neuronal tissues. Outside the central nervous system (CNS), inclusions were identified in a variety of post-mitotic cells. This is consistent with a concentration-dependent nucleation and aggregation model of inclusion formation and indicates that brain-specific factors are not necessary for this process. To possibly gain insights into the wasting that is observed in the human disease, we have conducted a detailed analysis of the timing and progression of inclusion formation in skeletal muscle and an investigation into the cause of the severe muscle atrophy that occurs in the mouse model. The formation of inclusions in non-CNS tissues will be particularly useful with respect to in vivo monitoring of pharmaceutical agents selected for their ability to prevent polyglutamine aggregation in vitro, without the requirement that the agent can cross the blood-brain barrier in the first instance.
Sathasivam, K., C. Hobbs, et al. (1999). "Transgenic models of Huntington's disease." Philos Trans R Soc Lond B Biol Sci 354(1386): 963-9.
Huntington's disease (HD) is an inherited neurodegenerative disorder caused by a CAG-polyglutamine repeat expansion. A mouse model of this disease has been generated by the introduction of exon 1 of the human HD gene carrying highly expanded CAG repeats into the mouse germ line (R6 lines). Transgenic mice develop a progressive neurological phenotype with a movement disorder and weight loss similar to that in HD. We have previously identified neuronal inclusions in the brains of these mice that have subsequently been established as the pathological hallmark of polyglutamine disease. Inclusions are present before symptoms, which in turn occur long before any selective neuronal cell death can be identified. We have extended the search for inclusions to skeletal muscle, which, like brain, contains terminally differentiated cells. We have conducted an investigation into the skeletal muscle atrophy that occurs in the R6 lines, (i) to provide possible insights into the muscle bulk loss observed in HD patients, and (ii) to conduct a parallel analysis into the consequence of inclusion formation to that being performed in brain. The identification of inclusions in skeletal muscle might be additionally useful in monitoring the ability of drugs to prevent inclusion formation in vivo.
Sapp, E., J. Penney, et al. (1999). "Axonal transport of N-terminal huntingtin suggests early pathology of corticostriatal projections in Huntington disease." J Neuropathol Exp Neurol 58(2): 165-73.
Aggregation of N-terminal mutant huntingtin within nuclear inclusions and dystrophic neurites occurs in the cortex and striatum of Huntington disease (HD) patients and may be involved in neurodegeneration. We examined the prevalence of inclusions and dystrophic neurites in the cortex and striatum of 15 adult onset HD patients who had mild to severe striatal cell loss (grades 1, 2 or 3) using an antibody that detects the N-terminal region of huntingtin. Nuclear inclusions were more frequent in the cortex than the striatum and were sparse or absent in the striatum of patients with low-grade striatal pathology. Dystrophic neurites occurred in both regions. Patients with low-grade striatal pathology had numerous fibers with immunoreactive puncta and large swellings within the striatal neuropil, the subcortical white matter, and the internal and external capsules. In the globus pallidus of 3 grade 1 cases, N-terminal huntingtin markedly accumulated in the perinuclear cytoplasm and in some axons but not in the nucleus. Findings suggest that in the earlier stages of HD, accumulation of N-terminal mutant huntingtin occurs in the cytoplasm and is associated with degeneration of the corticostriatal pathway.
Sansom, C. (1999). "Aggregation inhibitors: hope for Huntington's?" Mol Med Today 5(9): 372.
Ross, C. A., J. D. Wood, et al. (1999). "Polyglutamine pathogenesis." Philos Trans R Soc Lond B Biol Sci 354(1386): 1005-11.
An increasing number of neurodegenerative disorders have been found to be caused by expanding CAG triplet repeats that code for polyglutamine. Huntington's disease (HD) is the most common of these disorders and dentatorubral-pallidoluysian atrophy (DRPLA) is very similar to HD, but is caused by mutation in a different gene, making them good models to study. In this review, we will concentrate on the roles of protein aggregation, nuclear localization and proteolytic processing in disease pathogenesis. In cell model studies of HD, we have found that truncated N-terminal portions of huntingtin (the HD gene product) with expanded repeats form more aggregates than longer or full length huntingtin polypeptides. These shorter fragments are also more prone to aggregate in the nucleus and cause more cell toxicity. Further experiments with huntingtin constructs harbouring exogenous nuclear import and nuclear export signals have implicated the nucleus in direct cell toxicity. We have made mouse models of HD and DRPLA using an N-terminal truncation of huntingtin (N171) and full-length atrophin-1 (the DRPLA gene product), respectively. In both models, diffuse neuronal nuclear staining and nuclear inclusion bodies are observed in animals expressing the expanded glutamine repeat protein, further implicating the nucleus as a primary site of neuronal dysfunction. Neuritic pathology is also observed in the HD mice. In the DRPLA mouse model, we have found that truncated fragments of atrophin-1 containing the glutamine repeat accumulate in the nucleus, suggesting that proteolysis may be critical for disease progression. Taken together, these data lead towards a model whereby proteolytic processing, nuclear localization and protein aggregation all contribute to pathogenesis.
Reynolds, G. P., C. F. Dalton, et al. (1999). "Brain neurotransmitter deficits in mice transgenic for the Huntington's disease mutation." J Neurochem 72(4): 1773-6.
Huntington's disease (HD) is associated with an expansion in the CAG repeat sequence of a gene on chromosome 4, resulting in a neurodegenerative process particularly affecting the striatum and with profound but selective changes in content of various neurotransmitters. Recently, transgenic mice expressing a fragment of the human HD gene containing a large CAG expansion have been generated; these mice exhibit a progressive neurological phenotype that includes motor disturbances, as well as neuronal deficits. To investigate their underlying neurotransmitter pathology, we have determined concentrations of GABA, glutamate, and the monoamine neurotransmitters in several brain regions in these mice and control animals at times before and after the emergence of the behavioural phenotype. In contrast to the findings in HD, striatal GABA was unaffected, although a deficit was observed in the cerebellum, consistent with a dysfunction of Purkinje cells. Losses of the monoamine transmitters were observed, some of which are not seen in HD. Thus, 5-hydroxytryptamine and, to a greater extent, 5-hydroxyindoleacetic acid levels were diminished in all brain regions studied, and noradrenaline was particularly affected in the hippocampus. Dopamine was decreased in the striatum in older animals, parallelling evidence for diminished dopaminergic activity in HD.
Reddy, P. H., M. Williams, et al. (1999). "Recent advances in understanding the pathogenesis of Huntington's disease." Trends Neurosci 22(6): 248-55.
Huntington's disease (HD) is an autosomal, dominantly inherited neurodegenerative disorder that is characterized by abnormal involuntary movements (chorea), intellectual impairment and selective neuronal loss. The expansion of a polymorphic trinucleotide repeat (the sequence CAG that codes for glutamine) to a length that exceeds 40 repeat units in exon 1 of the gene, HD, correlates with the onset and progression of the disease. The protein encoded by HD, huntingtin, is normally localized in the cytoplasm, whereas the mutant protein is also found in the nucleus, suggesting that its translocation to this site is important for the pathogenesis of HD. Although several proteins that interact with huntingtin have been identified in vitro, the significance of these interactions with the mutant protein in the pathogenesis of HD has yet to be determined. Recent progress in the development of cellular and animal models for the disease have provided invaluable insights and resources for studying the disease mechanisms underlying HD, and will be useful for screening and evaluating possible therapeutic strategies.
Reddy, P. H., V. Charles, et al. (1999). "Transgenic mice expressing mutated full-length HD cDNA: a paradigm for locomotor changes and selective neuronal loss in Huntington's disease." Philos Trans R Soc Lond B Biol Sci 354(1386): 1035-45.
Huntington's disease (HD) is a progressive neurodegenerative disorder characterized clinically by motor and psychiatric disturbances and pathologically by neuronal loss and gliosis (reactive astrocytosis) particularly in the striatum and cerebral cortex. We have recently created HD full-length cDNA transgenic mouse models that may serve as a paradigm for HD. A more detailed characterization of these models is presented here. The transgene encoding normal huntingtin consists of 9417 bp of the huntingtin coding sequences including 16 tandem CAGs coding for polyglutamines as part of exon 1. The transgene is driven by a heterologous cytomegalovirus promoter. Five independent transgenic mouse lines were obtained using this construct. An additional six transgenic lines were obtained using full-length HD constructs that have been modified to include either 48 or 89 CAG repeat expansions. Southern blot and densitometric analyses indicated unique integration sites for the transgene in each of the lines with a copy number ranging from two to 22 copies. Widespread expression of the transgene in brain, heart, spleen, kidney, lung, liver and gonads from each line was determined by Western blot analyses. In the brain, transgene expression was found in cerebral cortex, striatum, hippocampus and cerebellum. Expression of the transgene was as much as five times the endogenous mouse huntingtin level. Phenotypically, only mice expressing 48 or 89 CAG repeats manifested progressive behavioural and motor dysfunction. Early behavioural abnormalities were characterized by trunk curling and clasping of both fore- and hindlimbs when the animals were suspended by their tails. Subsequently, these mice exhibited hyperkinetic movements, including heightened exploratory activities, unidirectional rotational behaviour, backflipping and excessive grooming that lasted for several weeks. Eventually, the animals progressed to a hypokinetic phase consisting of slowed movements and lack of response to sensory stimuli. Urine retention or incontinence was also a prominent feature of the hypokinetic phase. At the end stage of the disease process, HD48(B,D) and HD89(A-C) mice became akinetic just prior to death. Neuropathological examination of mice at various stages indicated that it was only during the hypokinetic phase and thereafter when selective neuronal loss was most apparent. Regions of neurodegeneration and loss included the striatum, cerebral cortex, thalamus and hippocampus. TUNEL staining indicated an apoptotic mode of cell death in these brain regions. Comparative neuronal counts after Nissl staining showed as much as 20% loss of small and medium neurons in the striatum in mice at the hypokinetic and akinetic stages. Reactive astrocytosis accompanied the areas of neurodegeneration and loss. Polyglutamine aggregates in the form of neuronal intranuclear inclusions and diffuse nuclear and perinuclear aggregations were found in a small percentage of neurons, including those in brain regions that are typically spared in HD. This observation suggests that polyglutamine aggregates may not be sufficient to cause neuronal loss in HD. In both behavioural and neuropathological analyses, wild-type and transgenic animals with 16 CAG repeats were indistinguishable from each other and do not exhibit the changes observed for mice carrying the 48 and 89 CAG repeat mutations. Thus, animals expressing the CAG repeat expansions appear to represent clinically analogous models for HD pathogenesis, and may also provide insights into the underlying pathophysiological mechanisms of other triplet repeat disorders.
Preisinger, E., B. M. Jordan, et al. (1999). "Evidence for a recruitment and sequestration mechanism in Huntington's disease." Philos Trans R Soc Lond B Biol Sci 354(1386): 1029-34.
Polyglutamine (polyQ) extension in the coding sequence of mutant huntingtin causes neuronal degeneration associated with the formation of insoluble polyQ aggregates in Huntington's disease. We constructed an array of CAG/CAA triplet repeats, coding for a range of 25-300 glutamine residues, which was used to generate expression constructs with minimal flanking sequence. Normal-length (25 glutamine residues) polyQ did not aggregate when transfected alone. Remarkably, when co-transfected with extended (100-300 glutamine residues) polyQ tracts, normal-length polyQ-containing peptides were trapped in insoluble detergent-resistant aggregates. Aggregates formed in the cytoplasm but were visible in the nucleus only when a strong nuclear localization signal was present. Intermolecular interactions between polyQ tracts mediated the localization of heterogeneous aggregates into the nucleolus by nucleolin protein. Our results suggest that extended polyQ can interact with cellular polyQ-containing proteins, transport them to ectopic cellular locations, and form heterogeneous polyQ aggregates. We provide evidence for a recruitment mechanism for pathogenesis in the polyQ neurodegenerative disorders. In susceptible cells, extended polyQ tracts in huntingtin might interact with and sequester or deplete certain endogenous polyQ-containing cellular proteins.
Petersen, A., K. Mani, et al. (1999). "Recent advances on the pathogenesis of Huntington's disease." Exp Neurol 157(1): 1-18.
We review recent advances regarding the pathogenesis of Huntington's disease (HD). This genetic neurodegenerative disorder is caused by an expanded CAG repeat in a gene coding for a protein, with unknown function, called huntingtin. There is selective death of striatal and cortical neurons. Both in patients and a transgenic mouse model of the disease, neuronal intranuclear inclusions, immunoreactive for huntingtin and ubiquitin, develop. Huntingtin interacts with the proteins GAPDH, HAP-1, HIP1, HIP2, and calmodulin, and a mutant huntingtin is specifically cleaved by the proapoptotic enzyme caspase 3. The pathogenetic mechanism is not known, but it is presumed that there is a toxic gain of function of the mutant huntingtin. Circumstantial evidence suggests that excitotoxicity, oxidative stress, impaired energy metabolism, and apoptosis play a role.
Peters, M. F., F. C. Nucifora, Jr., et al. (1999). "Nuclear targeting of mutant Huntingtin increases toxicity." Mol Cell Neurosci 14(2): 121-8.
Huntington's disease is a neurodegenerative disorder resulting from expansion of the polyglutamine region in huntingtin. Although huntingtin is normally cytoplasmic, in affected brain regions proteolytic fragments of mutant huntingtin containing the polyglutamine repeat form intranuclear inclusions. Here, we examine the contribution of nuclear localization to toxicity by transiently transfecting neuro-2a cells with an N-terminal huntingtin fragment similar in size to that believed to be present in patients. The huntingtin fragment, HD-N63, was targeted either to the cytoplasm with a nuclear export signal (NES) or to the nucleus with a nuclear localization signal (NLS). The NES decreased the number of cells with aggregates in the nucleus while an NLS had the opposite effect. By cotransfecting HD-N63 with GFP as a marker, we observed direct cell loss with constructs containing expanded polyglutamine repeats. Compared to unmodified HD-N63-75Q, adding an NES reduced cell loss by 57% while an NLS increased cell loss by 111%. These results indicate that nuclear localization of mutant huntingtin fragments plays an important role in cell toxicity.
Persichetti, F., F. Trettel, et al. (1999). "Mutant huntingtin forms in vivo complexes with distinct context-dependent conformations of the polyglutamine segment." Neurobiol Dis 6(5): 364-75.
Huntington's disease (HD) is caused by an expanded glutamine tract, which confers a novel aggregation-promoting property on the 350-kDa huntingtin protein. Using specific antibodies, we have probed the structure of the polyglutamine segment in mutant huntingtin complexes formed in cell culture from either truncated or full-length protein. Complexes formed by a mutant amino terminal fragment most frequently entail a change in conformation that eliminates reactivity with the polyglutamine-specific mAb 1F8, coincident with production of insoluble aggregate. By contrast, complexes formed by the full-length mutant protein remain soluble and are invariably 1F8-reactive, indicating a soluble polyglutamine conformation. Therefore, aggregates in HD may form by different biochemical mechanisms that invoke different possibilities for the pathogenic process. If pathogenesis is triggered by a truncated fragment, it probably involves the formation of an insoluble aggregate. However, the observation of soluble complexes in which an HD-specific pathogenic conformation of the glutamine tract remains accessible suggests that pathogenesis could also be triggered at the level of full-length huntingtin by abnormal aggregation with normal or abnormal protein partners.
Ona, V. O., M. Li, et al. (1999). "Inhibition of caspase-1 slows disease progression in a mouse model of Huntington's disease." Nature 399(6733): 263-7.
Huntington's disease is an autosomal-dominant progressive neurodegenerative disorder resulting in specific neuronal loss and dysfunction in the striatum and cortex. The disease is universally fatal, with a mean survival following onset of 15-20 years and, at present, there is no effective treatment. The mutation in patients with Huntington's disease is an expanded CAG/polyglutamine repeat in huntingtin, a protein of unknown function with a relative molecular mass of 350,000 (M(r) 350K). The length of the CAG/polyglutamine repeat is inversely correlated with the age of disease onset. The molecular pathways mediating the neuropathology of Huntington's disease are poorly understood. Transgenic mice expressing exon 1 of the human huntingtin gene with an expanded CAG/polyglutamine repeat develop a progressive syndrome with many of the characteristics of human Huntington's disease. Here we demonstrate evidence of caspase-1 activation in the brains of mice and humans with the disease. In this transgenic mouse model of Huntington's disease, expression of a dominant-negative caspase-1 mutant extends survival and delays the appearance of neuronal inclusions, neurotransmitter receptor alterations and onset of symptoms, indicating that caspase-1 is important in the pathogenesis of the disease. In addition, we demonstrate that intracerebroventricular administration of a caspase inhibitor delays disease progression and mortality in the mouse model of Huntington's disease.
O'Kusky, J. R., J. Nasir, et al. (1999). "Neuronal degeneration in the basal ganglia and loss of pallido-subthalamic synapses in mice with targeted disruption of the Huntington's disease gene." Brain Res 818(2): 468-79.
Huntington's disease (HD) is a progressive neurodegenerative disorder associated with CAG repeat expansion within a novel gene (IT15). We have previously created a targeted disruption in exon 5 of Hdh (Hdhex5), the murine homologue of the HD gene. Homozygotes for the Hdhex5 mutation exhibit embryolethality before embryonic day 8.5, while heterozygotes survive to adulthood and display increased motor activity and cognitive deficits. Detailed morphometric and stereological analyses of the basal ganglia in adult heterozygous mice were performed by light and electron microscopy. Morphometric analyses demonstrated a significant loss of neurons from both the globus pallidus (29%) and the subthalamic nucleus (51%), with a normal complement of neurons in the caudate-putamen and substantia nigra. The ultrastructural appearance of sporadic degenerating neurons in these regions indicated apoptosis. The highest frequency of apoptotic neurons was observed in the globus pallidus and subthalamic nucleus. Stereological analyses in the subthalamic nucleus revealed a significant decrease in the numerical density of symmetric synapses (43%), suggesting a relatively selective loss of inhibitory pallido-subthalamic afferents. Immunohistochemistry using antibodies against enkephalin and substance-P was unremarkable in heterozygotes, indicating a normal complement of enkephalin-immunoreactive striatopallidal afferents and substance-P-immunoreactive striatopeduncular and striatonigral afferents in these animals. These findings show that loss of an intact huntingtin protein is associated with significant morphological alterations in the basal ganglia of adult mice, indicating an important role for this protein during development of the central nervous system.
Nukina, N. (1999). "[The function of Huntington disease gene product (huntingtin) and the pathomechanism of Huntington disease]." Nippon Rinsho 57(4): 905-11.
The recent knowledges about the functions of huntingtin and the pathomechanism of Huntington disease are reviewed. Several binding proteins such as HAP1, ubiquitin-conjugating enzyme, HIP1, glyceraldehyde-3-phosphate-dehydrogenase(GAPDH), and cystathionine beta-synthase are identified. One of the functions of huntingtin suggested by those binding proteins is organella transport. In addition huntington binds with WW domain proteins and SH3 domain. The most exciting discovery of Huntington disease pathomechanism is identification of nuclear inclusions in transgenic mouse model of Huntington disease. The discussion about the significance of nuclear inclusion for the cell death was reviewed.
Nasir, J. (1999). "To be or not to be an aggregate." Clin Genet 55(1): 9-10.
Narain, Y., A. Wyttenbach, et al. (1999). "A molecular investigation of true dominance in Huntington's disease." J Med Genet 36(10): 739-46.
Huntington's disease (HD) is thought to show true dominance, since subjects with two mutant alleles have been reported to have similar ages at onset of disease compared to heterozygous sibs. We have investigated this phenomenon using a cell culture model. Protein aggregate formation was used as an indicator for pathology, as intraneuronal huntingtin inclusions are associated with pathology in vitro and in vivo. We showed that cytoplasmic and nuclear aggregates are formed by constructs comprising part of exon 1 of huntingtin with 41, 51, 66, or 72 CAG repeats, in a rate that correlates with repeat number. No inclusions were seen with 21 CAG repeat constructs. Mutant and wild type huntingtin fragments can be sequestered into inclusions seeded by a mutant huntingtin. Wild type huntingtin did not enhance or interfere with protein aggregation. The rate of protein aggregation was dose dependent for all mutant constructs tested. These experiments suggested a model for the dominance observed in HD; the decrease in the age at onset of a mutant homozygote may be small compared to the variance in the age at onset for that specific repeat number in heterozygotes. Our experiments also provide a model, which may explain the different repeat size ranges seen in patients and healthy controls for the different polyglutamine diseases.
Nance, M. A., V. Mathias-Hagen, et al. (1999). "Analysis of a very large trinucleotide repeat in a patient with juvenile Huntington's disease." Neurology 52(2): 392-4.
A patient with juvenile Huntington's disease (HD) of probable maternal inheritance is reported. The expanded IT-15 allele was only detected with the use of modified PCR and Southern transfer techniques, which showed a CAG trinucleotide repeat expansion of approximately 250 repeats-the largest CAG expansion reported within the huntingtin gene. This case emphasizes the need for communication between the diagnostic laboratory and the clinician to define the molecular genetics of unusual cases.
Metzler, M., N. Chen, et al. (1999). "Life without huntingtin: normal differentiation into functional neurons." J Neurochem 72(3): 1009-18.
Huntington disease (HD) is a neurodegenerative disorder associated with polyglutamine expansion in a recently identified protein, huntingtin. Huntingtin is widely expressed and plays a crucial role in development, because gene-targeted HD-/- mouse embryos die early in embryogenesis. To analyze the function of normal huntingtin, we have generated HD-/- embryonic stem (ES) cells and used an in vitro model of ES cell differentiation to analyze their ability to develop into neuronal cells. Expression analysis of wild-type ES cells revealed that huntingtin is expressed at all stages during ES cell differentiation with high expression in neurons. Expression levels increased with the maturation of differentiating neurons, demonstrating that expression of huntingtin is developmentally regulated in cell culture and resembles the pattern of expression observed in differentiating neurons in the mouse brain. It is interesting that HD-/- ES cells could differentiate into mature postmitotic neurons that expressed functional voltage- and neurotransmitter-gated ion channels. Moreover, both excitatory and inhibitory spontaneous postsynaptic currents were observed, indicating the establishment of functional synapses in the absence of huntingtin. These results demonstrate that huntingtin is not required for the generation of functional neurons with features characteristic of postmitotic neurons in the developing mouse brain.
Martin, E. J., M. Kim, et al. (1999). "Analysis of Huntingtin-associated protein 1 in mouse brain and immortalized striatal neurons." J Comp Neurol 403(4): 421-30.
Huntingtin, the protein product of the Huntington's disease (HD) gene, is expressed with an expanded polyglutamine domain in the brain and in nonneuronal tissues in patients with HD. Huntingtin-associated protein 1 (HAP-1), a brain-enriched protein, interacts preferentially with mutant huntingtin and thus may be important in HD pathogenesis. The function of HAP-1 is unknown, but recent evidence supports a role in microtubule-dependent organelle transport. We examined the subcellular localization of HAP-1 with an antibody made against the NH2-terminus of the protein. In immunoblot assays of mouse brain and immortalized striatal neurons, HAP-1 subtypes A and B migrated together at about 68 kD and separately at 95 kD and 110 kD, respectively. In dividing clonal striatal cells, HAP-1 localized to the mitotic spindle apparatus, especially at spindle poles and on vesicles and microtubules of the spindle body. Postmitotic striatal neurons had punctate HAP-1 labeling throughout the cytoplasm. Western blot analysis of protein extracts obtained after subcellular fractionation and differential centrifugation of the clonal striatal cells showed that HAP-1B was preferentially enriched in membrane fractions. Electron microscopic study of adult mouse basal forebrain and striatum showed HAP-1 localized to membrane-bound organelles including large endosomes, tubulovesicular structures, and budding vesicles in neurons. HAP-1 was also strongly associated with an unusual large "dense" organelle. Microtubules were labeled in dendrites and axonal fibers. Results support a role for HAP-1 in vesicle trafficking and organelle movement in mitotic cells and differentiated neurons and implicate HAP-1B as the predominant molecular subtype associated with vesicle membranes in striatal neurons.
Maat-Schieman, M. L., J. C. Dorsman, et al. (1999). "Distribution of inclusions in neuronal nuclei and dystrophic neurites in Huntington disease brain." J Neuropathol Exp Neurol 58(2): 129-37.
Recently, an N-terminal fragment of huntingtin was localized to neuronal intranuclear inclusions (NII), presumed to cause cellular dysfunction, and to inclusions in dystrophic neurites (IDN) in the neostriatum and neocortex of Huntington disease (HD) patients. In the present immunohistochemical study of autopsy brain of 2 juvenile-onset HD patients, 5 HD patients with adult-onset, and 5 controls, NII and IDN as stained with both N-terminal antiserum to huntingtin and ubiquitin antiserum were detected in the HD neostriatum, neocortex, and allocortex, but not in the HD pallidum, cerebellum, and substantia nigra nor in control brain. The frequency of NII in the HD neocortex was highest in the juvenile patients. Within the allocortex, NII and IDN were found in the entorhinal region, subiculum, and pyramidal cell layer of Ammon's horn. N-terminal huntingtin antiserum also labeled intranuclear granular structures adjacent to the neuronal nuclear membrane in 5 HD patients, one control with idiopathic epilepsy, and one with Alzheimer disease. Our results show that NII formation in HD involves the allocortex in addition to the neostriatum and neocortex. The development of NII in the neocortex and allocortex in HD brain might contribute to the emergence of the cognitive and behavioral symptoms of the disease.
Lunkes, A., Y. Trottier, et al. (1999). "Properties of polyglutamine expansion in vitro and in a cellular model for Huntington's disease." Philos Trans R Soc Lond B Biol Sci 354(1386): 1013-9.
Eight neurodegenerative diseases have been shown to be caused by the expansion of a polyglutamine stretch in specific target proteins that lead to a gain in toxic property. Most of these diseases have some features in common. A pathological threshold of 35-40 glutamine residues is observed in five of the diseases. The mutated proteins (or a polyglutamine-containing subfragment) form ubiquitinated aggregates in neurons of patients or mouse models, in most cases within the nucleus. We summarize the properties of a monoclonal antibody that recognizes specifically, in a Western blot, polyglutamine stretches longer than 35 glutamine residues with an affinity that increases with polyglutamine length. This indicates that the pathological threshold observed in five diseases corresponds to a conformational change creating a pathological epitope, most probably involved in the aggregation property of the carrier protein. We also show that a fragment of a normal protein carrying 38 glutamine residues is able to aggregate into regular fibrils in vitro. Finally, we present a cellular model in which the induced expression of a mutated full-length huntingtin protein leads to the formation of nuclear inclusions that share many characteristics with those observed in patients: those inclusions are ubiquitinated and contain only an N-terminal fragment of huntingtin. This model should thus be useful in studying a processing step that is likely to be important in the pathogenicity of mutated huntingtin.
Li, H., S. H. Li, et al. (1999). "Ultrastructural localization and progressive formation of neuropil aggregates in Huntington's disease transgenic mice." Hum Mol Genet 8(7): 1227-36.
How aggregates of polyglutamine proteins are involved in the neurological symptoms of glutamine repeat diseases is unknown. We show that huntingtin aggregates are present in the neuronal processes of transgenic mice that express exon 1 of the Huntington's disease (HD) gene. Unlike aggregates in the nucleus, these neuropil aggregates are usually smaller and are not ubiquitinated. Electron microscopy reveals many neuropil aggregates in axons and axon terminals. Huntingtin aggregates in the axon terminal are co-localized with some synaptic vesicles, implying that they may affect synaptic transmission and neuronal communication. The formation of neuropil aggregates is highly correlated with the development of neurological symptoms. The present study raises the possibility that neuropil aggregates may cause a dysfunction in neuronal communication and con-tribute to the neurological symptoms of HD.
Li, Z., C. A. Karlovich, et al. (1999). "A putative Drosophila homolog of the Huntington's disease gene." Hum Mol Genet 8(9): 1807-15.
The Huntington's disease (HD) gene encodes a protein, huntingtin, with no known function and no detectable sequence similarity to other proteins in current databases. To gain insight into the normal biological role of huntingtin, we isolated and sequenced a cDNA encoding a protein that is a likely homolog of the HD gene product in Drosophila melanogaster. We also determined the complete sequence of 43 125 contiguous base pairs of genomic DNA that encompass the Drosophila HD gene, allowing the intron-exon structure and 5'- and 3'-flanking regions to be delineated. The predicted Drosophila huntingtin protein has 3583 amino acids, which is several hundred amino acids larger than any other previously characterized member of the HD family. Analysis of the genomic and cDNA sequences indicates that Drosophila HD has 29 exons, compared with the 67 exons present in vertebrate HD genes, and that Drosophila huntingtin lacks the polyglutamine and polyproline stretches present in its mammalian counterparts. The Drosophila HD mRNA is expressed in a broad range of developmental stages and in the adult, a temporal pattern of expression similar to that observed for mammalian HD transcripts. We can discern five regions of high similarity from multiple sequence alignments between Drosophila and vertebrate huntingtins. These regions may define functionally important domains within the protein.
Li, X. J. (1999). "The early cellular pathology of Huntington's disease." Mol Neurobiol 20(2-3): 111-24.
Huntington's disease (HD) is an inherited neurodegenerative disorder that affects about one in 10,000 individuals in North America. The genetic defect responsible for the disease is an expansion of a CAG repeat that encodes a polyglutamine tract in the expressed protein, huntingtin. The disease is characterized by involuntary movements, cognitive impairment, and emotional disturbance. Despite the widespread expression of huntingtin, the brains of HD patients show selective neuronal loss in the striatum and the deep layers of the cerebral cortex. Recent studies have shown that polyglutamine expansion causes huntingtin to aggregate, to accumulate in the nucleus, and to interact abnormally with other proteins. Several cellular and animal models for HD have revealed that intranuclear accumulation of mutant huntingtin and the formation of neuropil aggregates precede neurological symptoms and neurodegeneration. Intranuclear huntingtin may affect nuclear function and the expression of genes important for neuronal function, whereas neuropil aggregates may interfere with neuritic transport and function. These early pathological events, which occur in the absence of neurodegeneration, may contribute to the neurological symptoms of HD and ultimately lead to neuronal cell death.
Lesort, M., W. Chun, et al. (1999). "Tissue transglutaminase is increased in Huntington's disease brain." J Neurochem 73(5): 2018-27.
The polyglutamine-expanded N-terminal region of mutant huntingtin causes neurodegeneration in Huntington's disease (HD). Neuronal intranuclear and cytosolic inclusions composed of mutant huntingtin are found in brains of HD patients. Because tissue transglutaminase cross-links proteins into filamentous aggregates and polypeptide-bound glutamines are primary determining factors for tissue transglutaminase-catalyzed reactions, it has been hypothesized that tissue transglutaminase may contribute to the formation of these aggregates. In this report immunohistochemical and biochemical methods were used to demonstrate that tissue transglutaminase expression and transglutaminase activity are elevated in HD brains in a grade-dependent manner. In the striatum, tissue transglutaminase activity was significantly increased in the grade 3 HD cases compared with controls. When normalized to the neuronal marker calbindin D28k, immunoblot analysis revealed that in the striatum the levels of tissue transglutaminase were significantly increased in all HD cases compared with controls. Immunohistochemical staining of the HD striatum revealed that tissue transglutaminase immunoreactivity was markedly increased in all grades as compared with controls. In the superior frontal cortex, tissue transglutaminase activity was significantly higher in all HD cases as compared with controls. Quantitative analysis of immunoblots demonstrated that tissue transglutaminase levels were elevated in HD grades 2 and 3 cases. Tissue transglutaminase immunoreactivity within the superior frontal neocortex was also greater in all the HD cases compared with controls. These data clearly indicate that tissue transglutaminase is elevated in HD brain and may play a role in the disease process.
Leavitt, B. R., C. L. Wellington, et al. (1999). "Recent insights into the molecular pathogenesis of Huntington disease." Semin Neurol 19(4): 385-95.
Huntington disease (HD) is a neurodegenerative disorder caused by a CAG repeat expansion in the HD gene resulting in expression of an uninterrupted polyglutamine stretch within the N-terminus of its protein product huntingtin (htt). In this article we review the clinical, genetic, and neuropathological features of HD and discuss recent insights into the pathogenesis of HD. Examining the role of CAG repeat size on age of onset and penetrance in HD using a refined database of human HD patients has provided further support for the importance of the CAG repeat in the pathogenesis of HD and information leading to a predictive model for the likelihood of being affected by a specific age for a particular CAG expansion. In a YAC transgenic mouse model that replicates key elements of the HD phenotype, the development of selective striatal neurodegeneration is coincident with cleavage of htt and translocation of the N-terminal htt fragment into the nucleus. We also review in vitro evidence that htt is a substrate for cleavage by a group of cysteine proteases involved in apoptotic death-the caspases, and that caspase cleavage of htt results in the generation of a toxic N-terminal fragment. Inhibiting caspase cleavage of huntingtin eliminates the toxicity of the mutant htt protein. These results suggest that cleavage of huntingtin resulting in production of a truncated N-terminal fragment may be a crucial step in the pathogenesis of Huntington disease and that inhibition of this process may be a potential therapeutic strategy for this currently untreatable disorder.
Kuemmerle, S., C. A. Gutekunst, et al. (1999). "Huntington aggregates may not predict neuronal death in Huntington's disease." Ann Neurol 46(6): 842-9.
The mechanism by which polyglutamine expansion in Huntington's disease (HD) results in selective neuronal degeneration remains unclear. We previously reported that the immunohistochemical distribution of N-terminal huntingtin in HD does not correspond to the severity of neuropathology, such that significantly greater numbers of huntingtin aggregates are present within the cortex than in the striatum. We now show a dissociation between huntingtin aggregation and the selective pattern of striatal neuron loss observed in HD. Aggregate formation was predominantly observed in spared interneurons, with few or no aggregates found within vulnerable spiny striatal neurons. Multiple perikaryal aggregates were present in almost all cortical NADPH-diaphorase neurons and in approximately 50% of the spared NADPH-diaphorase striatal neurons from early grade HD cases. In severe grade HD patients, aggregates were more prominent as nuclear inclusions in NADPH-diaphorase neurons, with less perikaryal and neuropil aggregation. In contrast, nuclear or perikaryal huntingtin aggregates were present in less than 4% of the vulnerable calbindin striatal neurons in all HD cases. These findings support the hypothesis that polyglutamine aggregation may not be a predictor of cell loss. Rather than a harbinger of neuronal death, mutant huntingtin aggregation may be a cytoprotective mechanism against polyglutamine-induced neurotoxicity.
Kim, M., H. S. Lee, et al. (1999). "Mutant huntingtin expression in clonal striatal cells: dissociation of inclusion formation and neuronal survival by caspase inhibition." J Neurosci 19(3): 964-73.
Neuronal intranuclear inclusions are found in the brains of patients with Huntington's disease and form from the polyglutamine-expanded N-terminal region of mutant huntingtin. To explore the properties of inclusions and their involvement in cell death, mouse clonal striatal cells were transiently transfected with truncated and full-length human wild-type and mutant huntingtin cDNAs. Both normal and mutant proteins localized in the cytoplasm, and infrequently, in dispersed and perinuclear vacuoles. Only mutant huntingtin formed nuclear and cytoplasmic inclusions, which increased with polyglutamine expansion and with time after transfection. Nuclear inclusions contained primarily cleaved N-terminal products, whereas cytoplasmic inclusions contained cleaved and larger intact proteins. Cells with wild-type or mutant protein had distinct apoptotic features (membrane blebbing, shrinkage, cellular fragmentation), but those with mutant huntingtin generated the most cell fragments (apoptotic bodies). The caspase inhibitor Z-VAD-FMK significantly increased cell survival but did not diminish nuclear and cytoplasmic inclusions. In contrast, Z-DEVD-FMK significantly reduced nuclear and cytoplasmic inclusions but did not increase survival. A series of N-terminal products was formed from truncated normal and mutant proteins and from full-length mutant huntingtin but not from full-length wild-type huntingtin. One prominent N-terminal product was blocked by Z-VAD-FMK. In summary, the formation of inclusions in clonal striatal cells corresponds to that seen in the HD brain and is separable from events that regulate cell death. N-terminal cleavage may be linked to mutant huntingtin's role in cell death.
Kim, M., J. Velier, et al. (1999). "Forskolin and dopamine D1 receptor activation increase huntingtin's association with endosomes in immortalized neuronal cells of striatal origin." Neuroscience 89(4): 1159-67.
Huntingtin is a cytoplasmic protein of unknown function that associates with vesicle membranes and microtubules. Its protein interactions suggest that huntingtin has a role in endocytosis and organelle transport. In this study we sought to identify factors that regulate the transport of huntingtin in striatal neurons, which are the cells most affected in Huntington's disease. In clonal striatal cells derived from fusions of neuroblastoma and embryonic striatal neurons, huntingtin localization is diffuse and slightly punctate in the cytoplasm. When these neurons were differentiated by treatment with forskolin, huntingtin redistributed to perinuclear regions, discrete puncta along plasma membranes, and branch points and terminal growth cones in neurites. Huntingtin staining overlapped with clathrin, a coat protein involved in endocytosis. Immunoblot analysis of subcellular membrane fractions separated by differential centrifugation confirmed that huntingtin immunoreactivity in differentiated neurons markedly increased in membrane fractions enriched with clathrin and with huntingtin-interacting protein 1. Dopamine treatment altered the subcellular localization of huntingtin and increased its expression in clathrin-enriched membrane fractions. The dopamine-induced changes were blocked by the D1 antagonist SCH 23390 and were absent in a clonal cell line lacking D1 receptors. Results suggest that the transport of huntingtin and its co-expression in clathrin and huntingtin-interacting protein 1-enriched membranes is influenced by activation of adenylyl cyclase and stimulation of dopamine D1 receptors.
Karpuj, M. V., H. Garren, et al. (1999). "Transglutaminase aggregates huntingtin into nonamyloidogenic polymers, and its enzymatic activity increases in Huntington's disease brain nuclei." Proc Natl Acad Sci U S A 96(13): 7388-93.
The protein huntingtin (htt), aggregated in neuronal nuclear inclusions, is pathognomonic of Huntington's disease (HD). Constructs, translated in vitro from the N terminus of htt, containing either polyQ23 from a normal individual, or polyQ41 or polyQ67 from an HD patient, were all soluble. Transglutaminase (TGase) crosslinked these proteins, and the aggregations did not have the staining properties of amyloid. More TGase-catalyzed aggregates formed when the polyglutamine domain of htt exceeded the pathologic threshold of polyQ36. Furthermore, shorter htt constructs, containing 135 aa or fewer, formed more aggregates than did larger htt constructs. TGase activity in the HD brain was increased compared with the control, with notable increases in cell nuclei. The increased TGase activity was brain specific. In lymphoblastoid cells from HD patients, TGase activity was decreased. TGase-mediated crosslinking of htt may be involved in the formation of the nonamyloidogenic nuclear inclusions found in the HD brain. The staining properties of nuclear inclusions in the HD brain revealed that they were not amyloid.
Jones, A. L. (1999). "The localization and interactions of huntingtin." Philos Trans R Soc Lond B Biol Sci 354(1386): 1021-7.
Huntingtin was localized by using a series of antibodies that detected different areas of the protein from the immediate N-terminus to the C-terminal region of the protein. The more C-terminal antibodies gave a cytoplasmic localization in neurons of the brain in controls and cases of Huntington's disease (HD). The N-terminal antibody, however, gave a distinctive pattern of immunoreactivity in the HD brain, with marked staining of axon tracts and white matter and the detection of densely staining intranuclear inclusions. This implies some processing differences between mutated and normal huntingtin. We have also localized two interacting proteins, cystathionine beta-synthase and the nuclear receptor co-repressor (N-CoR), in brain. Cystathionine beta-synthase was not relocalized in HD brain, but the N-CoR was excluded from neuronal nuclei in HD brain, and a further protein that exists in the same repression complex, mSin3, was similarly excluded. We conclude that the co-repressor might have a part in HD pathology.
Hurlbert, M. S., W. Zhou, et al. (1999). "Mice transgenic for an expanded CAG repeat in the Huntington's disease gene develop diabetes." Diabetes 48(3): 649-51.
The autosomal dominant neurological syndrome of Huntington's disease has been modeled in transgenic mice by the expression of a portion of the human huntingtin gene together with 140 CAG repeats (the R6/2 strain). The mice develop progressive chorea with onset at approximately 9 weeks of age and with death at approximately 13 weeks. Associated symptoms include weight loss and polyuria in the absence of eating or drinking deficits. We have found that these mice have insulin-responsive diabetes. Fasting glucose was 211 + 19 mg/dl in R6/2 mice compared with 93 + 5 mg/dl in C57/B6 controls (n = 12, both groups; P < 0.01). Administration of insulin intraperitoneally led to a reduction in blood glucose. At 12.5 weeks, animals were killed and pancreas weighed and analyzed for insulin and glucagon. Pancreatic mass in R6/2 mice was the same as controls, and islets appeared normal in morphology without lymphocytic infiltration. Immunohistochemical staining showed dramatic reductions in glucagon in the alpha-cells and in insulin in the beta-cells. Direct tissue assays showed glucagon and insulin content were reduced to only 10 and 15% of controls, respectively. Diabetes has been reported as being more common in Huntington's disease and other triplet repeat disorders. The R6/2 mouse should prove useful for elucidating the mechanism of diabetes in these genetic diseases.
Hollenbach, B., E. Scherzinger, et al. (1999). "Aggregation of truncated GST-HD exon 1 fusion proteins containing normal range and expanded glutamine repeats." Philos Trans R Soc Lond B Biol Sci 354(1386): 991-4.
We have shown previously by electron microscopy that the purified glutathione S-transferase (GST)-Huntington's disease (HD) exon 1 fusion protein with 51 glutamine residues (GST-HD51) is an oligomer, and that site-specific proteolytic cleavage of this fusion protein results in the formation of insoluble more highly ordered protein aggregates with a fibrillar or ribbon-like morphology (E. Scherzinger et al. (1997) Cell 90, 549-558). Here we report that a truncated GST HD exon 1 fusion protein with 51 glutamine residues, which lacks the proline-rich region C-terminal to the polyglutamine (polyQ) tract (GST-HD51 delta P) self-aggregates into high-molecular-mass protein aggregates without prior proteolytic cleavage. Electron micrographs of these protein aggregates revealed thread-like fibrils with a uniform diameter of ca. 25 nm. In contrast, proteolytic cleavage of GST-HD51 delta P resulted in the formation of numerous clusters of high-molecular-mass fibrils with a different, ribbon-like morphology. These structures were reminiscent of prion rods and beta-amyloid fibrils in Alzheimer's disease. In agreement with our previous results with full-length GST-HD exon 1, the truncated fusion proteins GST-HD20 delta P and GST-HD30 delta P did not show any tendency to form more highly ordered structures, either with or without protease treatment.
Hodgson, J. G., N. Agopyan, et al. (1999). "A YAC mouse model for Huntington's disease with full-length mutant huntingtin, cytoplasmic toxicity, and selective striatal neurodegeneration." Neuron 23(1): 181-92.
We have produced yeast artificial chromosome (YAC) transgenic mice expressing normal (YAC18) and mutant (YAC46 and YAC72) huntingtin (htt) in a developmental and tissue-specific manner identical to that observed in Huntington's disease (HD). YAC46 and YAC72 mice show early electrophysiological abnormalities, indicating cytoplasmic dysfunction prior to observed nuclear inclusions or neurodegeneration. By 12 months of age, YAC72 mice have a selective degeneration of medium spiny neurons in the lateral striatum associated with the translocation of N-terminal htt fragments to the nucleus. Neurodegeneration can be present in the absence of macro- or microaggregates, clearly showing that aggregates are not essential to initiation of neuronal death. These mice demonstrate that initial neuronal cytoplasmic toxicity is followed by cleavage of htt, nuclear translocation of htt N-terminal fragments, and selective neurodegeneration.
Hernando, I., V. Alvarez, et al. (1999). "[Huntington chorea: clniical and molecular analysis in Asturian patients]." Neurologia 14(1): 11-5.
AIM AND PATIENTS: To analyse 38 patients with Huntington's disease from 27 families. RESULTS: The CAG repeat at the huntingtin gene was expanded between 40 and 72 times. The size in normal chromosomes varied from 12 to 30 repeats. We found a significantly negative correlation between the number of CAG-repeats and the age of clinical manifestations. However, age and clinical characteristics of the first symptoms were highly variable between patients with a similar size of the expanded allele. Patients who inherited the disease from their fathers showed a higher number of repeats than those who received the disease from their mothers. However, in one case of father to son transmission we observed a reduction of the number of CAG repeats. CONCLUSIONS: These data make it difficult to use the molecular analysis for the presymptomatic diagnosis of clinical course in individuals carrying the expansion.
Hebb, M. O., E. M. Denovan-Wright, et al. (1999). "Expression of the Huntington's disease gene is regulated in astrocytes in the arcuate nucleus of the hypothalamus of postpartum rats." Faseb J 13(9): 1099-106.
Huntington's disease (HD) is one of a number of neurodegenerative disorders caused by expansion of polyglutamine-encoding CAG repeats within specific genes. Huntingtin, the protein product of the HD gene, is widely expressed in neural and nonneural human and rodent tissue. The function of the wild-type or mutated form of huntingtin is currently unknown. We have observed that relative to naive and male animals, huntingtin protein was significantly increased in the arcuate nucleus of postpartum rats. Using an oligonucleotide probe, in situ and Northern blot hybridization confirmed the expression of huntingtin mRNA. Quantification of the in situ hybridization signal in the arcuate nucleus revealed an approximate sevenfold increase in the expression of huntingtin mRNA in postpartum, lactating animals compared with naive female or male animals. Emulsion autoradiography and immunohistochemistry revealed that the cells with elevated huntingtin expression had a stellate conformation that morphologically resembled astrocytes. Dual label immunofluorescence immunohistochemistry demonstrated the colocalization of huntingtin and glial fibrillary acidic protein in these cells, confirming that they were astrocytes. Astrocytes expressing huntingtin were consistently found in close apposition to neuronal soma, suggesting interactions between these cell types. During the perinatal and postnatal period, the hypothalamus undergoes alterations in metabolic function. Our results support the idea of glia-induced metabolic changes in the hypothalamus. These results provide the first demonstration of naturally occurring changes in the expression of the Huntington's disease gene in the brain and suggest that huntingtin may play an important role in the processes that regulate neuroendocrine function.
Hazeki, N., K. Nakamura, et al. (1999). "Rapid aggregate formation of the huntingtin N-terminal fragment carrying an expanded polyglutamine tract." Biochem Biophys Res Commun 256(2): 361-6.
Huntington's disease (HD) is caused by an expansion of the CAG repeat in the HD gene. The repeat is translated to the polyglutamine tract as huntingtin, the product of HD gene. Several studies showed that the expansion of polyglutamine tract leads to formation of cytoplasminc and/or intranuclear aggregates in vivo or in vitro. To understand the molecular mechanism of the aggregate formation, we studied the transient expression of HD exon 1-GFP fusion proteins in COS-7 cells. The fusion protein carrying 77 glutamine repeats aggregated in a time-dependent manner, while the fusion protein carrying 25 glutamine tract remained to be distributed diffusely in the cytoplasm even 72 hours after transfection. Initially, fluorescent signals were diffusely distributed in the COS-7 cells that were transfected with the construct containing the 77 CAG repeats. Approximately 40 hours later after the transfection, large aggregates grew very rapidly in those cells and the diffuse cytoplasmic fluorescence faded out. This process was completed within 40 minutes from the appearance of small aggregates in the perinuclear regions. The addition of cycloheximide reduced the frequencies of aggregate formation. A possibility was discussed that the aggregate formation was via nucleation. The focal concentration of mutated proteins in neurons may trigger the aggregate formation.
Harper, P. S. (1999). "Huntington's disease: a clinical, genetic and molecular model for polyglutamine repeat disorders." Philos Trans R Soc Lond B Biol Sci 354(1386): 957-61.
Hackam, A. S., R. Singaraja, et al. (1999). "In vitro evidence for both the nucleus and cytoplasm as subcellular sites of pathogenesis in Huntington's disease." Hum Mol Genet 8(1): 25-33.
A unifying feature of the CAG expansion diseases is the formation of intracellular aggregates composed of the mutant polyglutamine-expanded protein. Despite the presence of aggregates in affected patients, the precise relationship between aggregates and disease pathogenesis is unresolved. Results from in vivo and in vitro studies of mutant huntingtin have lead to the hypothesis that nuclear localization of aggregates is critical for the pathology of Huntington's disease (HD). We tested this hypothesis using a 293T cell culture model system that compared the frequency and toxicity of cytoplasmic and nuclear huntingtin aggregates. We first assessed the mode of nuclear transport of N-terminal fragments of huntingtin, and show that the predicted endogenous NLS is not functional, providing data in support of passive nuclear transport. This result suggests that proteolysis is a necessary step for nuclear entry of huntingtin. Additionally, insertion of nuclear import or export sequences into huntingtin fragments containing 548 or 151 amino acids was used to reverse the normal localization of these proteins. Changing the subcellular localization of the fragments did not influence their total aggregate frequency. There were also no significant differences in toxicity associated with the presence of nuclear compared with cytoplasmic aggregates. The findings of nuclear and cytoplasmic aggregates in affected brains, together with these in vitro data, support the nucleus and cytosol as subcellular sites for pathogenesis in HD.
Hackam, A. S., J. G. Hodgson, et al. (1999). "Evidence for both the nucleus and cytoplasm as subcellular sites of pathogenesis in Huntington's disease in cell culture and in transgenic mice expressing mutant huntingtin." Philos Trans R Soc Lond B Biol Sci 354(1386): 1047-55.
A unifying feature of the CAG expansion diseases is the formation of intracellular aggregates composed of the mutant polyglutamine-expanded protein. Despite the presence of aggregates in affected patients, the precise relationship between aggregates and disease pathogenesis is unresolved. Results from in vivo and in vitro studies of mutant huntingtin have led to the hypothesis that nuclear localization of aggregates is critical for the pathology of Huntington's disease (HD). We tested this hypothesis using a 293T cell culture model system by comparing the frequency and toxicity of cytoplasmic and nuclear huntingtin aggregates. Insertion of nuclear import or export sequences into huntingtin fragments containing 548 or 151 amino acids was used to reverse the normal localization of these proteins. Changing the subcellular localization of the fragments did not influence their total aggregate frequency. There were also no significant differences in toxicity associated with the presence of nuclear compared with cytoplasmic aggregates. These studies, together with findings in transgenic mice, suggest two phases for the pathogenesis of HD, with the initial toxicity in the cytoplasm followed by proteolytic processing of huntingtin, nuclear translocation with increased nuclear concentration of N-terminal fragments, seeding of aggregates and resultant apoptotic death. These findings support the nucleus and cytosol as subcellular sites for pathogenesis in HD.
Gutekunst, C. A., S. H. Li, et al. (1999). "Nuclear and neuropil aggregates in Huntington's disease: relationship to neuropathology." J Neurosci 19(7): 2522-34.
The data we report in this study concern the types, location, numbers, forms, and composition of microscopic huntingtin aggregates in brain tissues from humans with different grades of Huntington's disease (HD). We have developed a fusion protein antibody against the first 256 amino acids that preferentially recognizes aggregated huntingtin and labels many more aggregates in neuronal nuclei, perikarya, and processes in human brain than have been described previously. Using this antibody and human brain tissue ranging from presymptomatic to grade 4, we have compared the numbers and locations of nuclear and neuropil aggregates with the known patterns of neuronal death in HD. We show that neuropil aggregates are much more common than nuclear aggregates and can be present in large numbers before the onset of clinical symptoms. There are also many more aggregates in cortex than in striatum, where they are actually uncommon. Although the striatum is the most affected region in HD, only 1-4% of striatal neurons in all grades of HD have nuclear aggregates. Neuropil aggregates, which we have identified by electron microscopy to occur in dendrites and dendritic spines, could play a role in the known dendritic pathology that occurs in HD. Aggregates increase in size in advanced grades, suggesting that they may persist in neurons that are more likely to survive. Ubiquitination is apparent in only a subset of aggregates, suggesting that ubiquitin-mediated proteolysis of aggregates may be late or variable.
Grunewald, T. and M. F. Beal (1999). "Bioenergetics in Huntington's disease." Ann N Y Acad Sci 893: 203-13.
Huntington's disease (HD) is an autosomal dominant inherited neurodegenerative disorder with relentless course and prototypical clinical symptoms. In 1993 HD was associated with an expanded CAG triplet repeat stretch on chromosome 4 in the coding region of its target protein, huntington. The length of the resulting polyglutamine++ extensions correlates with lower age of onset and a higher density of ubiquitin-positive neuronal intranuclear inclusions. Recently it has been proposed that mutant huntington induces progressive neuronal cell death by an apoptotic mechanism. There is strong evidence that disturbances in cellular energy homeostasis and oxidative damage contribute to neurodegeneration. This review will summarize and discuss the current concepts that point towards an involvement of free radical-induced oxidative stress, glutamate excitotoxicity and mitochondrial respiratory chain defects in pathogenesis of HD.
Fusco, F. R., Q. Chen, et al. (1999). "Cellular localization of huntingtin in striatal and cortical neurons in rats: lack of correlation with neuronal vulnerability in Huntington's disease." J Neurosci 19(4): 1189-202.
Immunohistochemistry and single-cell RT-PCR were used to characterize the localization of huntingtin and/or its mRNA in the major types of striatal neurons and in corticostriatal projection neurons in rats. Single-label immunohistochemical studies revealed that striatum contains scattered large neurons rich in huntingtin and more numerous medium-sized neurons moderate in huntingtin. Double-label immunohistochemical studies showed that the large huntingtin-rich striatal neurons include nearly all cholinergic interneurons and some parvalbuminergic interneurons. Somatostatinergic striatal interneurons, which are medium in size, rarely contained huntingtin. Calbindin immunolabeling showed that the vast majority of the medium-sized striatal neurons that contain huntingtin are projection neurons, but only approximately 65% of calbindin-labeled projection neurons (localized to the matrix compartment of striatum) were labeled for huntingtin. Calbindin-containing projection neurons of the matrix compartment and calbindin-negative projection neurons of the striatal patch compartment contained huntingtin with comparable frequency. Single-cell RT-PCR confirmed that striatal cholinergic interneurons contain huntingtin, but only approximately 65% of projection neurons contained detectable huntingtin message. The finding that huntingtin is not consistently found in striatal projection neurons [which die in Huntington's disease (HD)] but is abundant in striatal cholinergic interneurons (which survive in Huntington's disease) suggests that the mutation in huntingtin that causes HD may not directly kill neurons. In contrast to the heterogeneous expression of huntingtin in the different striatal neuron types, we found all corticostriatal neurons to be rich in huntingtin protein and mRNA. One possibility raised by our findings is that the HD mutation may render corticostriatal neurons destructive rather than render striatal neurons vulnerable.
Frontali, M., A. Novelletto, et al. (1999). "CAG repeat instability, cryptic sequence variation and pathogeneticity: evidence from different loci." Philos Trans R Soc Lond B Biol Sci 354(1386): 1089-94.
Different aspects of expanded polyglutamine tracts and of their pathogenetic role are taken into consideration here. (i) The (CAG)n length of wild-type alleles of the Huntington disease gene was analysed in instability-prone tumour tissue from colon cancer patients to test whether the process leading to the elongation of alleles towards the expansion range involves single-unit stepwise mutations or larger jumps. The analysis showed that length changes of a single unit had a relatively low frequency. (ii) The observation of an expanded spinocerebellar ataxia (SCA)1 allele with an unusual pattern of multiple CAT interruptions showed that cryptic sequence variations are critical not only for sequence length stability but also for the expression of the disease phenotype. (iii) Small expansions of the (CAG)n sequence at the CACNA1A gene have been reported as causing SCA6. The analysis of families with SCA6 and episodic ataxia type 2 showed that these phenotypes are, in fact, expressions of the same disorder caused either by point mutations or by small (CAG)n expansions. A gain of function has been hypothesized for all proteins containing an expanded polyglutamine stretch, including the alpha 1A subunit of the voltage-gated calcium channel type P/Q coded by the CACNA1A gene. Because point mutations at the same gene with similar phenotypic consequences are highly unlikely to have this effect, an alternative common pathogenetic mechanism for all these mutations, including small expansions, can be hypothesized.
Faber, P. W., J. R. Alter, et al. (1999). "Polyglutamine-mediated dysfunction and apoptotic death of a Caenorhabditis elegans sensory neuron." Proc Natl Acad Sci U S A 96(1): 179-84.
The effect of expressing human huntingtin fragments containing polyglutamine (polyQ) tracts of varying lengths was assessed in Caenorhabditis elegans ASH sensory neurons in young and old animals. Expression of a huntingtin fragment containing a polyQ tract of 150 residues (Htn-Q150) led to progressive ASH neurodegeneration but did not cause cell death. Progressive cell death and enhanced neurodegeneration were observed in ASH neurons that coexpressed Htn-Q150 and a subthreshold dose of a toxic OSM-10::green fluorescent protein (OSM-10::GFP) fusion protein. Htn-Q150 huntingtin protein fragments formed protein aggregates in ASH neurons, and the number of ASH neurons containing aggregates increased as animals aged. ASH neuronal cell death required ced-3 caspase function, indicating that the observed cell death is apoptotic. Of interest, ced-3 played a critical role in Htn-Q150-mediated neurodegeneration but not in OSM10::GFP-mediated ASH neurodegeneration. ced-3 function was important but not essential for the formation of protein aggregates. Finally, behavioral assays indicated that ASH neurons, coexpressing Htn-Q150 and OSM10::GFP, were functionally impaired at 3 days before the detection of neurodegeneration, cell death, and protein aggregates.
Engqvist-Goldstein, A. E., M. M. Kessels, et al. (1999). "An actin-binding protein of the Sla2/Huntingtin interacting protein 1 family is a novel component of clathrin-coated pits and vesicles." J Cell Biol 147(7): 1503-18.
The actin cytoskeleton has been implicated in endocytosis, yet few molecules that link these systems have been identified. Here, we have cloned and characterized mHip1R, a protein that is closely related to huntingtin interacting protein 1 (Hip1). These two proteins are mammalian homologues of Sla2p, an actin binding protein important for actin organization and endocytosis in yeast. Sequence alignments and secondary structure predictions verified that mHip1R belongs to the Sla2 protein family. Thus, mHip1R contains an NH(2)-terminal domain homologous to that implicated in Sla2p's endocytic function, three predicted coiled-coils, a leucine zipper, and a talin-like actin-binding domain at the COOH terminus. The talin-like domain of mHip1R binds to F-actin in vitro and colocalizes with F-actin in vivo, indicating that this activity has been conserved from yeast to mammals. mHip1R shows a punctate immunolocalization and is enriched at the cell cortex and in the perinuclear region. We concluded that the cortical localization represents endocytic compartments, because mHip1R colocalizes with clathrin, AP-2, and endocytosed transferrin, and because mHip1R fractionates biochemically with clathrin-coated vesicles. Time-lapse video microscopy of mHip1R-green fluorescence protein (GFP) revealed a blinking behavior similar to that reported for GFP-clathrin, and an actin-dependent inward movement of punctate structures from the cell periphery. These data show that mHip1R is a component of clathrin-coated pits and vesicles and suggest that it might link the endocytic machinery to the actin cytoskeleton.
Dorsman, J. C., M. A. Smoor, et al. (1999). "Analysis of the subcellular localization of huntingtin with a set of rabbit polyclonal antibodies in cultured mammalian cells of neuronal origin: comparison with the distribution of huntingtin in Huntington's disease autopsy brain." Philos Trans R Soc Lond B Biol Sci 354(1386): 1061-7.
Huntington's disease (HD) is a neurodegenerative disorder with a midlife onset. The disease is caused by expansion of a CAG (glutamine) repeat within the coding region of the HD gene. The molecular mechanism by which the mutated protein causes this disease is still unclear. To study the protein we have generated a set of rabbit polyclonal antibodies raised against different segments of the N-terminal, central and C-terminal parts of the protein. The polyclonal antibodies were affinity purified and characterized in ELISA and Western blotting experiments. All antibodies can react with mouse and human proteins. The specificity of these antibodies is underscored by their recognition of huntingtin with different repeat sizes in extracts prepared from patient-derived lymphoblasts. The antibodies were used in immunofluorescence experiments to study the subcellular localization of huntingtin in mouse neuroblastoma NIE-115 cells. The results indicate that most huntingtin is present in the cytoplasm, whereas a minor fraction is present in the nucleus. On differentiation of the NIE-115 cells in vitro, the subcellular distribution of huntingtin does not change significantly. These results suggest that full-length huntingtin with a normal repeat length can be detected in the nucleus of cycling and non-cycling cultured mammalian cells of neuronal origin. However, in HD autopsy brain the huntingtin-containing neuronal intranuclear inclusions can be detected only with antibodies raised against the N-terminus of huntingtin. Thus several forms of huntingtin display the propensity for nuclear localization, possibly with different functional consequences.
Davies, S. W., M. Turmaine, et al. (1999). "From neuronal inclusions to neurodegeneration: neuropathological investigation of a transgenic mouse model of Huntington's disease." Philos Trans R Soc Lond B Biol Sci 354(1386): 981-9.
Huntington's disease (HD) is an inherited progressive neurodegenerative disease caused by the expansion of a polyglutamine repeat sequence within a novel protein. Recent work has shown that abnormal intranuclear inclusions of aggregated mutant protein within neurons is a characteristic feature shared by HD and several other diseases involving glutamine repeat expansion. This suggests that in each of the these disorders the affected nerve cells degenerate as a result of these abnormal inclusions. A transgenic mouse model of HD has been generated by introducing exon 1 of the HD gene containing a highly expanded CAG sequence into the mouse germline. These mice develop widespread neuronal intranuclear inclusions and neurodegeneration specifically within those areas of the brain known to degenerate in HD. We have investigated the sequence of pathological changes that occur after the formation of nuclear inclusions and that precede neuronal cell death in these cells. Although the relation between inclusion formation and neurodegeneration has recently been questioned, a full characterization of the pathways linking protein aggregation and cell death will resolve some of these controversies and will additionally provide new targets for potential therapies.
Chen, N., T. Luo, et al. (1999). "Subtype-specific enhancement of NMDA receptor currents by mutant huntingtin." J Neurochem 72(5): 1890-8.
Evidence suggests that NMDA receptor-mediated neurotoxicity plays a role in the selective neurodegeneration underlying Huntington's disease (HD). The gene mutation that causes HD encodes an expanded polyglutamine tract of >35 in huntingtin, a protein of unknown function. Both huntingtin and NMDA receptors interact with cytoskeletal proteins, and, for NMDA receptors, such interactions regulate surface expression and channel activity. To determine whether mutant huntingtin alters NMDA receptor expression or function, we coexpressed mutant or normal huntingtin, containing 138 or 15 glutamine repeats, respectively, with NMDA receptors in a cell line and then assessed receptor channel function by patch-clamp recording and surface expression by western blot analysis. It is interesting that receptors composed of NR1 and NR2B subunits exhibited significantly larger currents when coexpressed with mutant compared with normal huntingtin. Moreover, this effect was selective for NR1/NR2B, as NR1/NR2A showed similar currents when coexpressed with mutant versus normal huntingtin. However, ion channel properties and total surface expression of the NR1 subunit were unchanged in cells cotransfected with NR1/NR2B and mutant huntingtin. Our results suggest that mutant huntingtin may increase numbers of functional NR1/NR2B-type receptors at the cell surface. Because NR1/NR2B is the predominant NMDA receptor subtype expressed in medium spiny neostriatal neurons, our findings may help explain the selective vulnerability of these neurons in HD.
Cha, J. H., A. S. Frey, et al. (1999). "Altered neurotransmitter receptor expression in transgenic mouse models of Huntington's disease." Philos Trans R Soc Lond B Biol Sci 354(1386): 981-9.
Alterations in neurotransmitter receptors are a pathological hallmark of the neurodegeneration seen in Huntington's disease (HD). However, the significance of these alterations has been uncertain, possibly reflecting simply the loss of brain cells. It is not known for certain whether the alteration of neurotransmitter receptors occurs before the onset of symptoms in human HD. Recently we developed transgenic mice that contain a portion of a human HD gene and develop a progressive abnormal neurological phenotype. Neurotransmitter receptors that are altered in HD (receptors for glutamate, dopamine, acetylcholine and adenosine) are decreased in the brain transgenic mice, in some cases before the onset of behavioural or motor symptoms. In transgenic mice, neurotransmitter receptor alterations occur before neuronal death. Further, receptor alterations are selective in that certain receptors, namely N-methyl-D-aspartate and gamma-aminobutyric acid receptors, are unaltered. Finally, receptor decreases are preceded by selective decreases in the corresponding mRNA species, suggesting the altered transcription of specific genes. These results suggest that (i) receptor decreases precede, and therefore might contribute to, the development of clinical symptoms, and (ii) altered transcription of specific genes might be a key pathological mechanism in HD.
Bruland, O., E. W. Almqvist, et al. (1999). "Accurate determination of the number of CAG repeats in the Huntington disease gene using a sequence-specific internal DNA standard." Clin Genet 55(3): 198-202.
We have developed a sequence-specific internal DNA size standard for the accurate determination of the number of CAG repeats in the Huntington disease (HD) gene by cloning key fragments (between 15 and 64 CAG repeats) of the HD gene. These fragments, pooled to produce a sequence-specific DNA ladder, enabled us to observe the true number of CAG repeats directly, with no need for calculations. Comparison of the calculated numbers of CAG repeats in the HD gene using this sequence-specific DNA standard with a commercially available standard (GENESCAN-500 TAMRA) showed that the latter underestimated the number of CAG repeats by three when analyzed by capillary electrophoresis on the ABI 310 Genetic Analyzer (POP4 polymer). In contrast, the use of the same standard overestimated the number of CAG repeats by one when the samples were analyzed by denaturing polyacrylamide electrophoresis on ABI 377 DNA Sequencer (6% denaturing polyacrylamide gel). This suggests that our sequence-specific standard provides greater accuracy for the determination of the true number of CAG repeats in the HD gene than commercially available standards. The sequence-specific standard can be radioactively labeled and successfully replace conventional DNA size standards when analyzing polymerase chain reaction (PCR)-amplified HD alleles by denaturing polyacrylamide electrophoresis.
Browne, S. E., R. J. Ferrante, et al. (1999). "Oxidative stress in Huntington's disease." Brain Pathol 9(1): 147-63.
It has been five years since the elucidation of the genetic mutation underlying the pathogenesis of Huntington's disease (HD) (97), however the precise mechanism of the selective neuronal death it propagates still remains an enigma. Several different etiological processes may play roles, and strong evidence from studies in both humans and animal models suggests the involvement of energy metabolism dysfunction, excitotoxic processes, and oxidative stress. Importantly, the recent development of transgenic mouse models of HD led to the identification of neuronal intranuclear inclusion bodies in affected brain regions in both mouse models and in HD brain, consisting of protein aggregates containing fragments of mutant huntingtin protein. These observations opened new avenues of investigation into possible huntingtin protein interactions and their putative pathogenetic sequelae. Amongst these studies, findings of elevated levels of oxidative damage products such as malondialdehyde, 8-hydroxydeoxyguanosine, 3-nitrotyrosine and heme oxygenase in areas of degeneration in HD brain, and of increased free radical production in animal models, indicate the involvement of oxidative stress either as a causative event, or as a secondary constituent of the cell death cascade in the disease. Here we review the evidence for oxidative damage and potential mechanisms of neuronal death in HD.
Brouillet, E., F. Conde, et al. (1999). "Replicating Huntington's disease phenotype in experimental animals." Prog Neurobiol 59(5): 427-68.
Huntington's disease (HD) is an inherited, autosomal dominant, neurodegenerative disorder characterized by involuntary choreiform movements, cognitive decline and a progressive neuronal degeneration primarily affecting the striatum. There is at present no effective therapy against this disorder. The gene responsible for the disease (IT15) has been cloned and the molecular defect identified as an expanded polyglutamine tract in the N-terminal region of a protein of unknown function, named huntingtin (The Huntington's Disease Collaborative Research Group, 1993. Cell 72, 971-983). An intense, search for the cell pathology attached to this molecular defect is currently under way [see Sharp and Ross (1996, Neurobiol. Dis. 3, 3-15) for review]. Huntingtin interacts with a number of proteins, some of which have well identified functions, and it has thus been suggested that alterations in glycolysis, vesicle trafficking or apoptosis play a role in the physiopathology of HD. On the other hand data derived from positron emission tomography (PET), magnetic resonance spectroscopy and post-mortem biochemical evidence for a defect in succinate oxidation have suggested the implication of a primary impairment of mitochondrial energy metabolism. All these hypotheses are not necessarily to be opposed and recent findings indicate that the HD mutation could possibly directly alter mitochondrial functions which would in turn activate apoptotic pathways. To test this mitochondrial hypothesis, we studied the effects in rodents and non-human primates of a chronic blockade of succinate oxidation by systemic administration of the mitochondrial toxin 3-nitropropionic acid (3NP). Extensive behavioural and neuropathological evaluations showed that a partial but prolonged energy impairment induced by 3NP is sufficient to replicate most of the clinical and pathophysiological hallmarks of HD, including spontaneous choreiform and dystonic movements, frontal-type cognitive deficits, and progressive heterogeneous striatal degeneration at least partially by apoptosis. 3NP produces the preferential degeneration of the medium-sized spiny GABAergic neurons with a relative sparing of interneurons and afferents, as was observed in HD striatum. The present manuscript reviews the different aspects of this neurotoxic treatment in rodents and non-human primates, and its interest as a phenotypic model of HD to understand the degenerative process of HD and test new therapeutic strategies.
Boutell, J. M., P. Thomas, et al. (1999). "Aberrant interactions of transcriptional repressor proteins with the Huntington's disease gene product, huntingtin." Hum Mol Genet 8(9): 1647-55.
We detected an interaction of the N-terminus of huntingtin (htt171) with the C-terminal region of the nuclear receptor co-repressor (N-CoR) using the yeast two-hybrid system. This interaction was repeat length dependent and specific to htt171; the co-repressor did not interact with the repeat carrying a section of atrophin 1 nor with the androgen receptor or polyglutamine alone. The interaction was confirmed using His-tagged Escherichia coli -expressed C-terminal human and rat co-repressor protein which pulled full-length huntingtin out of homogenized rat brain and in pull-down assays. The N-CoR represses transcription from sequence-specific ligand-activated receptors such as the retinoid X-thyroid hormone receptor dimers and other nuclear receptors including Mad-Max receptor dimers. The mechanism of this repression appears to be through the formation of a complex of repressor proteins including the N-CoR, mSin3 and histone deacetylases. We have used N-CoR and mSin3A antibodies in immunohistochemical studies and find that in Huntington's disease (HD) cortex and caudate, the cellular localization of these proteins is exclusively cytoplasmic whilst in control brain they are localized in the nucleus as well as the cytoplasm; mSin3A immunoreactivity also occurred in a subset of huntingtin positive intranuclear inclusions. The relocalization of repressor proteins in HD brain may alter transcription and be involved in the pathology of the disease.
Bailleul, P. A., G. P. Newnam, et al. (1999). "Genetic study of interactions between the cytoskeletal assembly protein sla1 and prion-forming domain of the release factor Sup35 (eRF3) in Saccharomyces cerevisiae." Genetics 153(1): 81-94.
Striking similarities between cytoskeletal assembly and the "nucleated polymerization" model of prion propagation suggest that similar or overlapping sets of proteins may assist in both processes. We show that the C-terminal domain of the yeast cytoskeletal assembly protein Sla1 (Sla1C) specifically interacts with the N-terminal prion-forming domain (Sup35N) of the yeast release factor Sup35 (eRF3) in the two-hybrid system. Sla1C and several other Sup35N-interacting proteins also exhibit two-hybrid interactions with the poly-Gln-expanded N-proximal fragment of human huntingtin, which promotes Huntington disease-associated aggregation. The Sup35N-Sla1C interaction is inhibited by Sup35N alterations that make Sup35 unable to propagate the [PSI(+)] state and by the absence of the chaperone protein Hsp104, which is essential for [PSI] propagation. In a Sla1(-) background, [PSI] curing by dimethylsulfoxide or excess Hsp104 is increased, while translational readthrough and de novo [PSI] formation induced by excess Sup35 or Sup35N are decreased. These data show that, in agreement with the proposed function of Sla1 during cytoskeletal formation, Sla1 assists in [PSI] formation and propagation, but is not required for these processes. Sla1(-) strains are sensitive to some translational inhibitors, and some sup35 mutants, obtained in a Sla1(-) background, are sensitive to Sla1, suggesting that the interaction between Sla1 and Sup35 proteins may play a role in the normal function of the translational apparatus. We hypothesize that Sup35N is involved in regulatory interactions with intracellular structural networks, and [PSI] prion may be formed as a by-product of this process.
Aronin, N., M. Kim, et al. (1999). "Are there multiple pathways in the pathogenesis of Huntington's disease?" Philos Trans R Soc Lond B Biol Sci 354(1386): 995-1003.
Studies of huntingtin localization in human post-mortem brain offer insights and a framework for basic experiments in the pathogenesis of Huntington's disease. In neurons of cortex and striatum, we identified changes in the cytoplasmic localization of huntingtin including a marked perinuclear accumulation of huntingtin and formation of multivesicular bodies, changes conceivably pointing to an altered handling of huntingtin in neurons. In Huntington's disease, huntingtin also accumulates in aberrant subcellular compartments such as nuclear and neuritic aggregates co-localized with ubiquitin. The site of protein aggregation is polyglutamine-dependent, both in juvenile-onset patients having more aggregates in the nucleus and in adult-onset patients presenting more neuritic aggregates. Studies in vitro reveal that the genesis of these aggregates and cell death are tied to cleavage of mutant huntingtin. However, we found that the aggregation of mutant huntingtin can be dissociated from the extent of cell death. Thus properties of mutant huntingtin more subtle than its aggregation, such as its proteolysis and protein interactions that affect vesicle trafficking and nuclear transport, might suffice to cause neurodegeneration in the striatum and cortex. We propose that mutant huntingtin engages multiple pathogenic pathways leading to neuronal death.
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