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 | Yamamoto, A., J. J. Lucas, et al. (2000). "Reversal of neuropathology and motor dysfunction in a conditional model of Huntington's disease." Cell 101(1): 57-66.
Neurodegenerative disorders like Huntington's disease (HD) are characterized by progressive and putative irreversible clinical and neuropathological symptoms, including neuronal protein aggregates. Conditional transgenic models of neurodegenerative diseases therefore could be a powerful means to explore the relationship between mutant protein expression and progression of the disease. We have created a conditional model of HD by using the tet-regulatable system. Mice expressing a mutated huntingtin fragment demonstrate neuronal inclusions, characteristic neuropathology, and progressive motor dysfunction. Blockade of expression in symptomatic mice leads to a disappearance of inclusions and an amelioration of the behavioral phenotype. We thus demonstrate that a continuous influx of the mutant protein is required to maintain inclusions and symptoms, raising the possibility that HD may be reversible.
Wyttenbach, A., J. Carmichael, et al. (2000). "Effects of heat shock, heat shock protein 40 (HDJ-2), and proteasome inhibition on protein aggregation in cellular models of Huntington's disease." Proc Natl Acad Sci U S A 97(6): 2898-903.
Huntington's disease (HD), spinocerebellar ataxias types 1 and 3 (SCA1, SCA3), and spinobulbar muscular atrophy (SBMA) are caused by CAG/polyglutamine expansion mutations. A feature of these diseases is ubiquitinated intraneuronal inclusions derived from the mutant proteins, which colocalize with heat shock proteins (HSPs) in SCA1 and SBMA and proteasomal components in SCA1, SCA3, and SBMA. Previous studies suggested that HSPs might protect against inclusion formation, because overexpression of HDJ-2/HSDJ (a human HSP40 homologue) reduced ataxin-1 (SCA1) and androgen receptor (SBMA) aggregate formation in HeLa cells. We investigated these phenomena by transiently transfecting part of huntingtin exon 1 in COS-7, PC12, and SH-SY5Y cells. Inclusion formation was not seen with constructs expressing 23 glutamines but was repeat length and time dependent for mutant constructs with 43-74 repeats. HSP70, HSP40, the 20S proteasome and ubiquitin colocalized with inclusions. Treatment with heat shock and lactacystin, a proteasome inhibitor, increased the proportion of mutant huntingtin exon 1-expressing cells with inclusions. Thus, inclusion formation may be enhanced in polyglutamine diseases, if the pathological process results in proteasome inhibition or a heat-shock response. Overexpression of HDJ-2/HSDJ did not modify inclusion formation in PC12 and SH-SY5Y cells but increased inclusion formation in COS-7 cells. To our knowledge, this is the first report of an HSP increasing aggregation of an abnormally folded protein in mammalian cells and expands the current understanding of the roles of HDJ-2/HSDJ in protein folding.
Wheeler, V. C., J. K. White, et al. (2000). "Long glutamine tracts cause nuclear localization of a novel form of huntingtin in medium spiny striatal neurons in HdhQ92 and HdhQ111 knock-in mice." Hum Mol Genet 9(4): 503-13.
Huntington's disease (HD) is caused by an expanded N-terminal glutamine tract that endows huntingtin with a striatal-selective structural property ultimately toxic to medium spiny neurons. In precise genetic models of juvenile HD, HdhQ92 and HdhQ111 knock-in mice, long polyglutamine segments change huntingtin's physical properties, producing HD-like in vivo correlates in the striatum, including nuclear localization of a version of the full-length protein predominant in medium spiny neurons, and subsequent formation of N-terminal inclusions and insoluble aggregate. These changes show glutamine length dependence and dominant inheritance with recruitment of wild-type protein, critical features of the altered HD property that strongly implicate them in the HD disease process and that suggest alternative pathogenic scenarios: the effect of the glutamine tract may act by altering interaction with a critical cellular constituent or by depleting a form of huntingtin essential to medium spiny striatal neurons.
Wellington, C. L. and M. R. Hayden (2000). "Caspases and neurodegeneration: on the cutting edge of new therapeutic approaches." Clin Genet 57(1): 1-10.
Unregulated apoptosis underlies many pathological conditions, including neurodegenerative diseases. In this review, we focus on the role of cysteine aspartate-specific proteases (caspase) activity in Huntington disease (HD) and Alzheimer disease (AD) as two representative neurodegenerative disorders that normally manifest in mid- to late-life. Caspases appear to be involved in the molecular pathology of HD by directly cleaving huntingtin and generating toxic protein fragments containing the polyglutamine tract, and by being recruited and activated by polyglutamine-containing aggregates composed mainly of truncated huntingtin fragments. Several proteins involved in AD, including beta-amyloid precursor protein (APP) and presenilins (PSs), are also cleaved by caspases. For APP, caspase cleavage may contribute to toxicity by generating toxic fragments or by shifting APP processing toward an amyloidogenic pathway. For PSs, caspase cleavage disables antiapoptotic functions attributed to PS C-terminal fragments. These observations suggest that caspases actively contribute to the molecular pathogenesis of these diseases and support the development of caspase inhibitors as potential therapeutic approaches for chronic neurodegenerative disorders.
Wellington, C. L., R. Singaraja, et al. (2000). "Inhibiting caspase cleavage of huntingtin reduces toxicity and aggregate formation in neuronal and nonneuronal cells." J Biol Chem 275(26): 19831-8.
Huntington's disease is a neurodegenerative disorder caused by CAG expansion that results in expansion of a polyglutamine tract at the extreme N terminus of huntingtin (htt). htt with polyglutamine expansion is proapoptotic in different cell types. Here, we show that caspase inhibitors diminish the toxicity of htt. Additionally, we define htt itself as an important caspase substrate by generating a site-directed htt mutant that is resistant to caspase-3 cleavage at positions 513 and 530 and to caspase-6 cleavage at position 586. In contrast to cleavable htt, caspase-resistant htt with an expanded polyglutamine tract has reduced toxicity in apoptotically stressed neuronal and nonneuronal cells and forms aggregates at a much reduced frequency. These results suggest that inhibiting caspase cleavage of htt may therefore be of potential therapeutic benefit in Huntington's disease.
Wellington, C. L., B. R. Leavitt, et al. (2000). "Huntington disease: new insights on the role of huntingtin cleavage." J Neural Transm Suppl(58): 1-17.
Huntington Disease (HD) results from polyglutamine expansion within the N-terminus of huntingtin. We have produced yeast artificial chromosome (YAC) transgenic mice expressing normal (YAC18) and mutant (YAC46 and YAC72) human huntingtin in a developmentally appropriate and tissue-specific manner identical to the pattern of expression of endogenous huntingtin. YAC46 and YAC72 mice show early electrophysiological abnormalities indicating neuronal cytoplasmic dysfunction prior to developing nuclear inclusions or neurodegeneration. YAC72 mice display a hyperkinetic movement disorder by 7 months of age, and have evidence for selective and specific degeneration of medium spiny neurons in the lateral striatum by 12 months of age. A key molecular feature of pathology of these YAC72 mice is cleavage of huntingtin in the cytoplasm following by translocation of the resulting huntingtin N-terminal fragments into the nucleus of striatal neurons. Increasing nuclear localization of huntingtin N-terminal fragments within medium spiny neurons of the striatum occurs concomitantly with the onset of selective neurodegeneration. Because huntingtin is a caspase substrate and truncated huntingtin fragments are toxic in vitro, inhibiting caspase cleavage of huntingtin may be of potential therapeutic benefit in HD. We show that caspase inhibitors eliminate huntingtin cleavage in cells and protects them from an apoptotic stress. We also identify caspase-6 and caspase-3 cleavage sites in huntingtin and demonstrate that neuronal and non-neuronal cells expressing a caspase-resistant huntingtin with an expanded polyglutamine tract are less susceptible to apoptosis and aggregate formation. These results suggest that caspase cleavage of huntingtin may be a crucial step in aggregate formation and neurotoxicity in HD.
Vuillaume, I., P. Meynieu, et al. (2000). "Absence of unidentified CAG repeat expansion in patients with Huntington's disease-like phenotype." J Neurol Neurosurg Psychiatry 68(5): 672-5.
Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder caused by an expanded (CAG)n repeat on the huntingtin gene. It is characterised by motor, psychiatric and cognitive disturbances. Diagnosis can be confirmed by direct genetic testing, which is highly sensitive and specific and is now considered definitive. This study focused on 21 patients presenting with a clinical phenotype showing strong similarity to HD, but who do not have an expanded CAG in the huntingtin gene. However, other possible diagnoses could be evoked for most of them. Seven patients (3.5% of our cohort) could be considered as phenocopies of HD with no alternative diagnosis. Samples were screened for other triplet repeat diseases with similar presentation (DRPLA, SCA-1, SCA-2, SCA-3, SCA-6, and SCA-7) and were all negative. The repeat expansion detection technique (RED) was used to detect uncloned CAG repeat expansions and samples were also analysed by polymerase chain reaction for expansions of the polymorphic CAG-ERDA-1 and CTG18.1 trinucleotide repeats. RED expansion (>40 repeats) was detected in only one patient. The results suggest that unstable CAG/CTG repeat expansions corresponding to known or unknown sequences are not involved in the aetiology of HD-like disorders. It is hypothesised that some of these phenocopies could correspond to mutations in other unidentified genes with other unstable repeats (different from CAG) or in unknown genes with other mutations.
van Dellen, A., J. Welch, et al. (2000). "N-Acetylaspartate and DARPP-32 levels decrease in the corpus striatum of Huntington's disease mice." Neuroreport 11(17): 3751-7.
Huntington's disease (HD) is an autosomal dominant condition involving progressive neurodegeneration, primarily the corpus striatum and cerebral cortex. We have used in vivo magnetic resonance spectroscopy (MRS) to assess specific neuronal markers in transgenic mice (R6/1 line) expressing exon I of the human huntingtin gene with an expanded CAG repeat. Levels of N-acetylaspartate (NAA), an indicator of healthy neuronal function, were significantly reduced (26%) in the corpus striatum of HD mice relative to wild-type littermates at 5 months of age. However, levels of cholines and creatine-phosphocreatine were not altered in the HD mice. Expression of dopamine- and cAMP-regulated phosphoprotein, 32 kDa (DARPP-32), was assessed by immunohistochemistry in the striatum of HD mice and found to be downregulated by 5 months and, even more dramatically, at 11 months of age. In contrast, expression of calbindin was not significantly decreased in HD mice. Our results suggest that the observed decreases in DARPP-32 and NAA may contribute to aberrant receptor signalling and neuronal dysfunction in HD.
Turmaine, M., A. Raza, et al. (2000). "Nonapoptotic neurodegeneration in a transgenic mouse model of Huntington's disease." Proc Natl Acad Sci U S A 97(14): 8093-7.
Huntington's disease (HD) is a fatal inherited neurodegenerative disorder characterized by personality changes, motor impairment, and subcortical dementia. HD is one of a number of diseases caused by expression of an expanded polyglutamine repeat. We have developed several lines of mice that are transgenic for exon 1 of the HD gene containing an expanded CAG sequence. These mice exhibit a defined neurological phenotype along with neuronal changes that are pathognomonic for the disease. We have previously observed the appearance of neuronal intranuclear inclusions, but did not find evidence for neurodegeneration. In this study, we report that all lines of these mice develop a late onset neurodegeneration within the anterior cingulate cortex, dorsal striatum, and of the Purkinje neurons of the cerebellum. Dying neurons characteristically exhibit neuronal intranuclear inclusions, condensation of both the cytoplasm and nucleus, and ruffling of the plasma membrane while maintaining ultrastructural preservation of cellular organelles. These cells do not develop blebbing of the nucleus or cytoplasm, apoptotic bodies, or fragmentation of DNA. Neuronal death occurs over a period of weeks not hours. We also find degenerating cells of similar appearance within these same regions in brains of patients who had died with HD. We therefore suggest that the mechanism of neuronal cell death in both HD and a transgenic mouse model of HD is neither by apoptosis nor by necrosis.
Trettel, F., D. Rigamonti, et al. (2000). "Dominant phenotypes produced by the HD mutation in STHdh(Q111) striatal cells." Hum Mol Genet 9(19): 2799-809.
Lengthening a glutamine tract in huntingtin confers a dominant attribute that initiates degeneration of striatal neurons in Huntington's disease (HD). To identify pathways that are candidates for the mutant protein's abnormal function, we compared striatal cell lines established from wild-type and Hdh(Q111) knock-in embryos. Alternate versions of full-length huntingtin, distinguished by epitope accessibility, were localized to different sets of nuclear and perinuclear organelles involved in RNA biogenesis and membrane trafficking. However, mutant STHdh(Q111) cells also exhibited additional forms of the full-length mutant protein and displayed dominant phenotypes that did not mirror phenotypes caused by either huntingtin deficiency or excess. These phenotypes indicate a disruption of striatal cell homeostasis by the mutant protein, via a mechanism that is separate from its normal activity. They also support specific stress pathways, including elevated p53, endoplasmic reticulum stress response and hypoxia, as potential players in HD.
Tobin, A. J. and E. R. Signer (2000). "Huntington's disease: the challenge for cell biologists." Trends Cell Biol 10(12): 531-6.
Huntington's disease (HD) is one of eight inherited neurodegenerative diseases caused by expansions of (CAG)(n) tracts that encode polyglutamine segments in expressed proteins. Studies of pathogenic mechanisms for all these late-onset diseases suffer from a common drawback: experimental studies require massive acceleration of a process that, in affected humans, usually takes decades. But is the rapid-onset disease of transgenic mouse models and in cells the same as the slow-onset disease in humans? We review recent work on HD, noting several issues whose significance is likely to be crucial - but which are as yet unresolved. We discuss these in light of the distinction between disease-specific pathogenic mechanisms and artifacts of polyglutamine overexpression. We suggest that the initial stages of HD result from dysfunction rather than death, and we consider the potential discovery of compounds that might interfere with early pathogenic events.
Tabrizi, S. J., J. Workman, et al. (2000). "Mitochondrial dysfunction and free radical damage in the Huntington R6/2 transgenic mouse." Ann Neurol 47(1): 80-6.
Huntington's disease is a progressive neurodegenerative disease caused by an abnormally expanded (>36) CAG repeat within the ITI5 gene encoding a widely expressed 349-kd protein, huntingtin. The medium spiny neurons of the caudate preferentially degenerate in Huntington's disease, with the presence of neuronal intranuclear inclusions. Excitotoxicity is thought to be important in the pathogenesis of Huntington's disease; the recently described mitochondrial respiratory chain and aconitase defects in Huntington's disease brain are consistent with this hypothesis. A transgenic mouse model (R6/2) of Huntington's disease develops a movement disorder, muscle wasting, and premature death at about 14 to 16 weeks. Selective neuronal death in these mice is not seen until 14 weeks. Biochemical analysis of R6/2 mouse brain at 12 weeks demonstrated a significant reduction in aconitase and mitochondrial complex IV activities in the striatum and a decrease in complex IV activity in the cerebral cortex. Increased immunostaining for inducible nitric oxide synthase and nitrotyrosine was seen in the transgenic mouse model but not control mouse brains. These results extend the parallels between Huntington's disease and the transgenic mouse model to biochemical events and suggest complex IV deficiency and elevated nitric oxide and superoxide radical generation precede neuronal death in the R6/2 mouse and contribute to pathogenesis.
Steffan, J. S., A. Kazantsev, et al. (2000). "The Huntington's disease protein interacts with p53 and CREB-binding protein and represses transcription." Proc Natl Acad Sci U S A 97(12): 6763-8.
Huntington's Disease (HD) is caused by an expansion of a polyglutamine tract within the huntingtin (htt) protein. Pathogenesis in HD appears to include the cytoplasmic cleavage of htt and release of an amino-terminal fragment capable of nuclear localization. We have investigated potential consequences to nuclear function of a pathogenic amino-terminal region of htt (httex1p) including aggregation, protein-protein interactions, and transcription. httex1p was found to coaggregate with p53 in inclusions generated in cell culture and to interact with p53 in vitro and in cell culture. Expanded httex1p represses transcription of the p53-regulated promoters, p21(WAF1/CIP1) and MDR-1. httex1p was also found to interact in vitro with CREB-binding protein (CBP) and mSin3a, and CBP to localize to neuronal intranuclear inclusions in a transgenic mouse model of HD. These results raise the possibility that expanded repeat htt causes aberrant transcriptional regulation through its interaction with cellular transcription factors which may result in neuronal dysfunction and cell death in HD.
So, C. W., M. H. Sham, et al. (2000). "Expression and protein-binding studies of the EEN gene family, new interacting partners for dynamin, synaptojanin and huntingtin proteins." Biochem J 348 Pt 2: 447-58.
EEN, identified initially as a fusion partner to the mixed-lineage leukaemia gene in human leukaemia, and its related members, EEN-B1 and EEN-B2, have recently been shown to interact with two endocytic molecules, dynamin and synaptojanin, as well as with the huntingtin protein. In the present study, we show that the expression of the EEN gene-family members is differentially regulated. Multiple-spliced variants were identified for EEN-B2. In the brain, EEN-B1 and EEN-B2 mRNA are preferentially expressed in the cerebellar Purkinje and granule cells, dentate gyrus cells, hippocampal pyramidal neurons and cerebral granule cells. The expression patterns of EEN-B1 and EEN-B2 mRNA in the brain overlap with those of dynamin-I/III, synaptojanin-I and huntingtin, whereas the ubiquitous expression of EEN is consistent with that of dynamin-II. In testes, members of the EEN family are co-expressed with testis-type dynamin and huntingtin in Sertoli cells and germ cells respectively. Our results on the overlapping expression patterns are consistent with the proposed interaction of EEN family members with dynamin, synaptojanin and huntingtin protein in vivo. Although all three EEN family members bind to dynamin and synaptojanin, EEN-B1 has the highest affinity for binding, followed by EEN and EEN-B2. We also demonstrate that amphiphysin, a major synaptojanin-binding protein in brain, can compete with the EEN family for binding to synaptojanin and dynamin. We propose that recruitment of the EEN family by dynamin/synaptojanin to clathrin-coated pits can be regulated by amphiphysin.
Schimenti, J. C., B. J. Libby, et al. (2000). "Interdigitated deletion complexes on mouse chromosome 5 induced by irradiation of embryonic stem cells." Genome Res 10(7): 1043-50.
Chromosome deletions have several applications in the genetic analysis of complex organisms. They can be used as reagents in region-directed mutagenesis, for mapping of simple or complex traits, or to identify biological consequences of segmental haploidy, the latter being relevant to human contiguous gene syndromes and imprinting. We have generated three deletion complexes in ES (Embryonic Stem) cells that collectively span approximately 40 cM of proximal mouse chromosome 5. The deletion complexes were produced by irradiation of F(1) hybrid ES cells containing herpes simplex virus thymidine kinase genes (tk) integrated at the Dpp6, Hdh (Huntington disease locus), or Gabrb1 loci, followed by selection for tk-deficient clones. Deletions centered at the adjacent Hdh and Dpp6 loci ranged up to approximately 20 cM or more in length and overlapped in an interdigitated fashion. However, the interval between Hdh and Gabrb1 appeared to contain a locus haploinsufficient for ES cell viability, thereby preventing deletions of either complex from overlapping. In some cases, the deletions resolved the order of markers that were previously genetically inseparable. A subset of the ES cell-bearing deletions was injected into blastocysts to generate germline chimeras and establish lines of mice segregating the deletion chromosomes. At least 11 of the 26 lines injected were capable of producing germline chimeras. In general, those that failed to undergo germline transmission bore deletions larger than the germline-competent clones, suggesting that certain regions of chromosome 5 contain haploinsufficient developmental genes, and/or that overall embryonic viability is cumulatively decreased as more genes are rendered hemizygous. Mice bearing deletions presumably spanning the semidominant hammertoe locus (Hm) had no phenotype, suggesting that the classic allele is a dominant, gain-of-function mutation. Overlapping deletion complexes generated in the fashion described in this report will be useful as multipurpose genetic tools and in systematic functional mapping of the mouse genome.
Santos, A. D. and E. A. Padlan (2000). "Does mRNA translation starting from an alternative initiation site contribute to the pathology of Huntington's disease?" Med Hypotheses 54(5): 689-90.
Huntington's disease is associated with an expanded and unstable trinucleotide repeat (CAG)(n). Various possibilities have been suggested to explain the significance of poly-(CAG) length in HD, including changes in the structure of the product (huntingtin) which result in the protein acquiring deleterious properties. We have looked at the nucleotide sequence coding for huntingtin and find that another possibility may exist for the correlation between the occurrence of HD and poly-CAG length. We have noted an alternative reading frame that includes the trinucleotide repeat, now read as (GCA)(n). Upon close examination of this alternative gene product, we observe features that suggest it can likewise have deleterious properties.
Rigamonti, D., J. H. Bauer, et al. (2000). "Wild-type huntingtin protects from apoptosis upstream of caspase-3." J Neurosci 20(10): 3705-13.
Expansion of a polyglutamine sequence in the N terminus of huntingtin is the gain-of-function event that causes Huntington's disease. This mutation affects primarily the medium-size spiny neurons of the striatum. Huntingtin is expressed in many neuronal and non-neuronal cell types, implying a more general function for the wild-type protein. Here we report that wild-type huntingtin acts by protecting CNS cells from a variety of apoptotic stimuli, including serum withdrawal, death receptors, and pro-apoptotic Bcl-2 homologs. This protection may take place at the level of caspase-9 activation. The full-length protein also modulates the toxicity of the poly-Q expansion. Cells expressing full-length mutant protein are susceptible to fewer death stimuli than cells expressing truncated mutant huntingtin.
Pramanik, S., P. Basu, et al. (2000). "Analysis of CAG and CCG repeats in Huntingtin gene among HD patients and normal populations of India." Eur J Hum Genet 8(9): 678-82.
We have analysed the distribution of CAG and adjacent polymorphic CCG repeats in the Huntingtin gene in 28 clinically diagnosed unrelated Huntington's disease (HD) patients and in normal individuals belonging to different ethnic groups of India. The range of expanded CAG repeats in HD patients varied from 41 to 56 repeats, whereas in normal individuals this number varied between 11 and 31 repeats. We identified six CCG alleles from a total of 380 normal chromosomes that were pooled across different ethnic populations of India. There were two predominant alleles: (CCG)7 (72.6%) and (CCG)10 (20%). We report here for the first time one four-repeat CCG allele which has not been found in any population so far. We found 30 haplotypes (two loci CAG-CCG) for 380 normal chromosomes. In the present study, no statistically significant preponderance of expanded HD alleles was found on either (CCG)7 or (CCG)10 backgrounds. Our studies suggest that the overall prevalence of HD in Indian populations may not be as high as in Western populations. Further studies are necessary to identify the origin of HD mutation in these populations.
Passani, L. A., M. T. Bedford, et al. (2000). "Huntingtin's WW domain partners in Huntington's disease post-mortem brain fulfill genetic criteria for direct involvement in Huntington's disease pathogenesis." Hum Mol Genet 9(14): 2175-82.
An elongated glutamine tract in mutant huntingtin initiates Huntington's disease (HD) pathogenesis via a novel structural property that displays neuronal selectivity, glutamine progressivity and dominance over the normal protein based on genetic criteria. As this mechanism is likely to involve a deleterious protein interaction, we have assessed the major class of huntingtin interactors comprising three WW domain proteins. These are revealed to be related spliceosome proteins (HYPA/FBP-11 and HYPC) and a transcription factor (HYPB) that implicate huntingtin in mRNA biogenesis. In HD post-mortem brain, specific antibody reagents detect each partner in HD target neurons, in association with disease-related N-terminal morphologic deposits but not with filter trapped insoluble-aggregate. Glutathione S:-transferase partner 'pull-down' assays reveal soluble, aberrantly migrating, forms of full-length mutant huntingtin specific to HD target tissue. Importantly, these novel mutant species exhibit exaggerated WW domain binding that abrogates partner association with other huntingtin isoforms. Thus, each WW domain partner's association with huntingtin fulfills HD genetic criteria, supporting a direct role in pathogenesis. Our findings indicate that modification of mutant huntingtin in target neurons may promote an abnormal interaction with one, or all, of huntingtin's WW domain partners, perhaps altering ribonucleoprotein function with toxic consequences.
Orr, H. T. and H. Y. Zoghbi (2000). "Reversing neurodegeneration: a promise unfolds." Cell 101(1): 1-4.
Nellemann, C., K. Abell, et al. (2000). "Inhibition of Huntington synthesis by antisense oligodeoxynucleotides." Mol Cell Neurosci 16(4): 313-23.
The Huntington disease gone encodes the protein huntington, which is widely expressed during embryonic development and in mature tissues. In order to elucidate the physiological function of huntington, which so far is unknown, we intend to study the effect of antisense down-regulated huntington expression. We have found an inhibiting effect of a phosphorothioated oligodeoxynucleotide (PS-ODN) added to the culture medium of embryonic teratocarcinoma cells (NT2) and postmitotic neurons (NT2N neurons) differentiated from the NT2 cells. Specific inhibition of expression of endogenous huntington was achieved in NT2N neurons in the concentration range of 1-5 microM PS-ODN, whereas no inhibition was obtained in NT2 cells. We describe in detail the selection of the target sequence for the antisense oligo and the uptake, intracellular distribution, and stability of the antisense PS-ODN in the two cell types. Antisense down-regulation of huntington in this model of human neurons represents a suitable approach to study its normal function.
Nasir, J., M. J. Lafuente, et al. (2000). "Human huntingtin-associated protein (HAP-1) gene: genomic organisation and an intragenic polymorphism." Gene 254(1-2): 181-7.
The huntingtin-associated protein (HAP-1) interacts with the Huntington disease gene product, huntingtin. It is predominantly expressed in the brain and shows an increased affinity for mutant huntingtin. We have sequenced an 18,656bp genomic region encompassing the entire human HAP-1 gene and determined its genomic organisation, with 11 exons spanning 12.1kb. We have also found an intragenic polymorphism within intron 6 of HAP-1. We have recently shown that HAP-1 maps to a region of the genome which has been implicated in a variety of neurological conditions, including progressive supranuclear palsy (PSP), a late-onset atypical parkinsonian disorder. The detailed characterisation of the genomic organisation of HAP-1 and the presence of an intragenic polymorphism will be helpful in evaluating its role in different disorders, using candidate gene approaches.
Nagao, Y., H. Ishiguro, et al. (2000). "DMSO and glycerol reduce bacterial death induced by expression of truncated N-terminal huntingtin with expanded polyglutamine tracts." Biochim Biophys Acta 1502(2): 247-56.
Huntington's disease (HD) is caused by CAG repeat expansion in exon 1 of a large gene, IT15, possessing 67 exons. Transgenic mice expressing a truncated N-terminal peptide of huntingtin with an expanded polyglutamine tract translated only from exon 1 develop symptoms similar to Huntington's disease. In the present study, a bacterial system (Escherichia coli) was used to express truncated peptides of huntingtin translated from exon 1 of the HD gene. Bacterial death was observed after the induction of peptides with expanded polyglutamine tracts, and both sodium dodecyl sulfate (SDS)-soluble peptides and insoluble aggregated material were detected by immunoblotting in the homogenates of such E. coli. E. coli death was partially reduced by the addition of dimethylsulfoxide (DMSO) or glycerol to the medium, with a consequent decrease in aggregated material and an increase in SDS-soluble peptide in the homogenate. These results suggest that DMSO and glycerol may decrease the toxicity of huntingtin with expanded polyglutamine tracts by acting as chemical chaperones.
Murphy, K. P., R. J. Carter, et al. (2000). "Abnormal synaptic plasticity and impaired spatial cognition in mice transgenic for exon 1 of the human Huntington's disease mutation." J Neurosci 20(13): 5115-23.
Huntington's disease (HD) is an autosomal dominant progressive and fatal neurodegenerative brain disorder caused by an expanded CAG/polyglutamine repeat in the coding region of the gene. Presymptomatic Huntington's disease patients often exhibit cognitive deficits before the onset of classical symptoms. To investigate the possibility that changes in synaptic plasticity might underlie cognitive impairment in HD, we examined hippocampal synaptic plasticity and spatial cognition in a transgenic mouse (R6/2 line) expressing exon 1 of the human Huntington's disease gene containing an expanded CAG repeat. This mouse exhibits a progressive and fatal neurological phenotype that resembles Huntington's disease. We report that R6/2 mice show marked alterations in synaptic plasticity at both CA1 and dentate granule cell synapses, and impaired spatial cognitive performance in the Morris water maze. The changes in hippocampal plasticity were age dependent, appearing at CA1 synapses several weeks before they were observed in the dentate gyrus. Deficits in synaptic plasticity at CA1 synapses occurred before an overt phenotype. This suggests that altered synaptic plasticity contributes to the pre-symptomatic changes in cognition reported in human carriers of the Huntington' disease gene. The temporal and regional changes in synaptic plasticity within the hippocampus mirror the appearance of neuronal intranuclear inclusions, suggesting a relationship between polyglutamine aggregation and dysfunction.
Mizuno, H., H. Shibayama, et al. (2000). "An autopsy case with clinically and molecular genetically diagnosed Huntington's disease with only minimal non-specific neuropathological findings." Clin Neuropathol 19(2): 94-103.
An autopsy case with clinically and molecular genetically diagnosed Huntington's disease (HD) accompanied with minimal non-specific neuropathological features was reported. When the patient was 45 years old, he had faulty memory, mood swing, personality change and agitation. Neurological and psychiatric examinations revealed choreoathetoid movements in limbs and trunk, generalized hyperreflexia and mental deterioration. However, cerebellar ataxia and muscle rigidity were not disclosed. Neuroimaging study did not show a definite atrophy of heads of caudate nuclei. Neuroacanthocytosis and Wilson's disease were ruled out by the peripheral blood examination and serum Cu and ceruloplasmin examination. At the age of 55 he died of pneumonia. Post-mortem examination revealed minimal non-specific neuropathological features for HD (Vonsattel's grade 0), that is, no visible fibrillary gliosis in the striatum, and few neuronal loss and only proliferation of astrocytes (astrocytosis) in the striatum. Molecular-genetic study the patient's brain tissues and his youngest son's blood was performed. These studies revealed 40 CAG repeats in the patient, 56 CAG repeats in his youngest son. These results suggest they may be HD. Vonsattel et al. [ 1998] insist that grade 0 comprises 1% of all HD brains, and grade 1 comprises 4% of all HD brains. But we could not find any reports in which the clinical and neuropathological features were described in detail on the cases with clinically and molecular genetically diagnosed HD without specific pathological findings. Therefore, we present in detail the clinical and neuropathological features of such case.
Metzler, M., C. D. Helgason, et al. (2000). "Huntingtin is required for normal hematopoiesis." Hum Mol Genet 9(3): 387-94.
Huntington's disease (HD) is a neurodegenerative disease associated with polyglutamine expansion in huntingtin, a widely expressed protein. The function of huntingtin is unknown although huntingtin plays a fundamental role in development since gene targeted HD (-) (/-)mouse embryos die shortly after gastrulation. Expression of huntingtin is detected in spleen and thymus but its role in hematopoiesis has not been examined. To determine the function of huntingtin and to provide insight into potential pathologic mechanisms in HD, we analyzed the role of huntingtin in hematopoietic development. Expression of huntingtin was analyzed in a variety of hematopoietic cell types, and in vitro hematopoiesis was assessed using an HD ( +/-)and several HD( -) (/-)embryonic stem (ES) cell lines. Although wild-type, HD ( +/-)and HD( -) (/-)ES cell lines formed primary embryoid bodies (EBs) with similar efficiency, the numbers of hematopoietic progenitors detected at various stages of the in vitro differentiation were reduced in HD ( +/-)and HD( -/-)() ()ES cell lines examined. Expression analyses of hematopoietic markers within the EBs revealed that primitive and definitive hematopoiesis occurs in the absence of huntingtin. However, further analysis using a suspension culture in the presence of hematopoietic cytokines demonstrated a highly significant gene dosage-dependent decrease in proliferation and/or survival of HD ( +/-)and HD( -) (/-)cells. Enrichment for the CD34(+)cells within the EB confirmed that the impairment is intrinsic to the hematopoietic cells. These obser- vations suggest that huntingtin expression is required for the generation and expansion of hematopoietic cells and provides an alternative system in which to assess the function of huntingtin.
Menalled, L., H. Zanjani, et al. (2000). "Decrease in striatal enkephalin mRNA in mouse models of Huntington's disease." Exp Neurol 162(2): 328-42.
Huntington's disease is a devastating progressive neurodegenerative illness characterized by massive neuronal loss in the striatum. It is caused by the presence of an expanded CAG repeat in the gene encoding huntingtin, a protein of unknown function. We have examined the expression of neurotransmitters and other antigens present in striatal neurons with immunohistochemistry, and the level of expression of mRNAs encoding enkephalin, substance P, and glutamic acid decarboxylases with quantitative in situ hybridization histochemistry, in the striatum of two mouse models of Huntington's disease: transgenic animals expressing exon 1 of the human huntingtin gene with 144 CAG repeats and "knock-in" mice containing a chimeric mouse/human exon 1 with 71 or 94 CAG repeats inserted by homologous targeting. Although the transgenic (but not the knock-in) mice were previously shown to display prominent huntingtin- and ubiquitin-containing nuclear inclusions in striatal neurons, in situ nick translation followed by emulsion autoradiography did not reveal any DNA damage in striatum or cortex in these mice. Immunolabeling for calbindin D 28K, enkephalin, substance P, glutamic acid decarboxylases (M(r) 65,000 or 67,000, GAD65 and GAD67), somatostatin, choline acetyltransferase, parvalbumin, and glial fibrillary acidic protein were remarkably similar in transgenic, knock-in, and wild-type mice. Both transgenic and knock-in mice, however, showed a marked decrease in the level of expression of enkephalin mRNA in striatal neurons without significant decreases in mRNAs encoding substance P, GAD65, or GAD67. The data indicate that decreased expression of enkephalin mRNA may be an early sign of neuronal dysfunction due to the Huntington's disease mutation.
McGowan, D. P., W. van Roon-Mom, et al. (2000). "Amyloid-like inclusions in Huntington's disease." Neuroscience 100(4): 677-80.
Huntington's disease is a progressive, autosomal dominantly inherited, neurodegenerative disease that is characterized by involuntary movements (chorea), cognitive decline and psychiatric manifestations. This is one of a number of late-onset neurodegenerative disorders caused by expanded glutamine repeats, with a likely similar biochemical basis. Immunohistochemical studies on Huntington's disease tissue, using antibodies raised to the N-terminal region of huntingtin (adjacent to the repeat) and ubiquitin, have recently identified neuronal inclusions within densely stained neuronal nuclei, peri-nuclear and within dystrophic neuritic processes. However, the functional significance of inclusions is unknown. It has been suggested that the disease-causing mechanism in Huntington's disease (and the other polyglutamine disorders) is the ability of polyglutamine to undergo a conformational change that can lead to the formation of very stable anti-parallel beta-sheets; more specifically, amyloid structures. We examined, using Congo Red staining and both polarizing and confocal microscopy, post mortem human brain tissue from five Huntington's disease cases, two Alzheimer's disease cases and two normal controls. Brains from five transgenic mice (R6/2)(12) expressing exon 1 of the human huntingtin gene with expanded polyglutamine, and five littermate controls, were also examined by the same techniques. We have shown that some inclusions in Huntington's disease brain tissue possess an amyloid-like structure, suggesting parallels with other amyloid-associated diseases such as Alzheimer's and prion diseases.
Matsuyama, N., S. Hadano, et al. (2000). "Identification and characterization of the miniature pig Huntington's disease gene homolog: evidence for conservation and polymorphism in the CAG triplet repeat." Genomics 69(1): 72-85.
Huntington's disease (HD) is associated with a significant expansion of a CAG trinucleotide repeat, which results in a lengthened polyglutamine tract in the single gene product, huntingtin, on human 4p16.3. We isolated cDNA clones that encompassed the entire coding sequence of the miniature pig HD gene (Sus HD) from two porcine testis cDNA libraries. The cDNA contig revealed a 12,749-nucleotide transcript coding for a 345-kDa protein (3139 amino acid residues), which exhibited 96% peptide sequence homology to human huntingtin. Northern blot analysis revealed that the Sus HD gene was ubiquitously expressed as two large transcripts of approximately 11 and 13 kb in size in all the tested tissues, much like the human HD gene. The CAG trinucleotide repeat was found to be interrupted by CAA triplets and to encode 17 or 18 consecutive glutamine residues. In our laboratory stock of miniature pig, three allotypes in the triplet repeat sequence were found. Thus, the Sus HD gene closely resembles its human counterpart in terms of sequence and expression pattern. In particular, human-miniature pig similarities in the normal length of the CAG triplet repeat as well as its repeat-number polymorphism may indicate that miniature pig would provide a good animal model for Huntington's disease.
Luthi-Carter, R., A. Strand, et al. (2000). "Decreased expression of striatal signaling genes in a mouse model of Huntington's disease." Hum Mol Genet 9(9): 1259-71.
To understand gene expression changes mediated by a polyglutamine repeat expansion in the human huntingtin protein, we used oligonucleotide DNA arrays to profile approximately 6000 striatal mRNAs in the R6/2 mouse, a transgenic Huntington's disease (HD) model. We found diminished levels of mRNAs encoding components of the neurotransmitter, calcium and retinoid signaling pathways at both early and late symptomatic time points (6 and 12 weeks of age). We observed similar changes in gene expression in another HD mouse model (N171-82Q). These results demonstrate that mutant huntingtin directly or indirectly reduces the expression of a distinct set of genes involved in signaling pathways known to be critical to striatal neuron function.
Li, H., S. H. Li, et al. (2000). "Amino-terminal fragments of mutant huntingtin show selective accumulation in striatal neurons and synaptic toxicity." Nat Genet 25(4): 385-9.
Huntington disease (HD) is caused by expansion of a glutamine repeat in the amino-terminal region of huntingtin. Despite its widespread expression, mutant huntingtin induces selective neuronal loss in striatal neurons. Here we report that, in mutant mice expressing HD repeats, the production and aggregation of N-terminal huntingtin fragments preferentially occur in HD-affected neurons and their processes and axonal terminals. N-terminal fragments of mutant huntingtin form aggregates and induce neuritic degeneration in cultured striatal neurons. N-terminal mutant huntingtin also binds to synaptic vesicles and inhibits their glutamate uptake in vitro. The specific processing and accumulation of toxic fragments of N-terminal huntingtin in HD-affected striatal neurons, especially in their neuronal processes and axonal terminals, may contribute to the selective neuropathology of HD.
Li, S. H., S. Lam, et al. (2000). "Intranuclear huntingtin increases the expression of caspase-1 and induces apoptosis." Hum Mol Genet 9(19): 2859-67.
Expansion of a polyglutamine repeat in huntingtin causes Huntington's disease (HD). Although full-length huntingtin is predominantly distributed in the cytoplasm, N-terminal fragments of huntingtin with expanded polyglutamine tracts are able to accumulate in the nucleus and kill neurons through apoptotic pathways. Transgenic mice expressing N-terminal mutant huntingtin show intranuclear huntingtin accumulation and develop progressive neurological symptoms. Inhibiting caspase-1 can prolong the survival of these HD mice. How intranuclear huntingtin is associated with caspase activation and apoptosis is unclear. Here we report that intranuclear huntingtin induces the activation of caspase-3 and the release of cytochrome c from mitochondria in cultured cells. As a result, cells expressing intranuclear huntingtin undergo apoptosis. We show that intranuclear huntingtin increases the expression of caspase-1, which may in turn activate caspase-3 and trigger apoptosis. We propose that the increased level of caspase-1 induced by intranuclear huntingtin contributes to HD-associated cell death.
Krobitsch, S. and S. Lindquist (2000). "Aggregation of huntingtin in yeast varies with the length of the polyglutamine expansion and the expression of chaperone proteins." Proc Natl Acad Sci U S A 97(4): 1589-94.
Huntington's disease (HD) is an inherited neurodegenerative disorder caused by polyglutamine (polyQ) expansions in the huntingtin (Ht) protein. A hallmark of HD is the proteolytic production of an N-terminal fragment of Ht, containing the polyQ repeat, that forms aggregates in the nucleus and cytoplasm of affected neurons. Proteins with longer polyQ repeats aggregate more rapidly and cause disease at an earlier age, but the mechanism of aggregation and its relationship to disease remain unclear. To provide a new, genetically tractable model system for the study of Ht, we engineered yeast cells to express an N-terminal fragment of Ht with different polyQ repeat lengths of 25, 47, 72, or 103 residues, fused to green fluorescent protein. The extent of aggregation varied with the length of the polyQ repeat: at the two extremes, most HtQ103 protein coalesced into a single large cytoplasmic aggregate, whereas HtQ25 exhibited no sign of aggregation. Mutations that inhibit the ubiquitin/proteasome pathway at three different steps had no effect on the aggregation of Ht fragments in yeast, suggesting that the ubiquitination of Ht previously noted in mammalian cells may not inherently be required for polyQ length-dependent aggregation. Changing the expression levels of a wide variety of chaperone proteins in yeast neither increased nor decreased Ht aggregation. However, Sis1, Hsp70, and Hsp104 overexpression modulated aggregation of HtQ72 and HtQ103 fragments. More dramatically, the deletion of Hsp104 virtually eliminated it. These observations establish yeast as a system for studying the causes and consequences of polyQ-dependent Ht aggregation.
Kovtun, I. V., T. M. Therneau, et al. (2000). "Gender of the embryo contributes to CAG instability in transgenic mice containing a Huntington's disease gene." Hum Mol Genet 9(18): 2767-75.
Gender is known to influence the transmission of trinucleotide repeats in human disease. However, the molecular basis for the parent-of-origin effect associated with trinucleotide repeat expansion is not known. We have followed, during transmission, the fate of the CAG trinucleotide repeat in a transgene containing the exon 1 portion of the human Huntington's disease (HD) gene. Similar to humans, the mouse transmits expansions predominantly through the male germ line. Surprisingly, we find that the CAG repeat size of the mutant human HD gene is different in male and female progeny from identical fathers. Males predominantly expand the repeat whereas females predominantly contract the repeat. In contrast to the classic definition of imprinting, CAG expansion is influenced by the gender of the embryo. Our results raise the possibility that there are X- or Y-encoded factors that influence repair or replication of DNA in the embryo. Gender dependence in the embryo may explain why expansion in HD from premutation to disease primarily occurs through the paternal line.
Kirkwood, S. C., E. Siemers, et al. (2000). "Confirmation of subtle motor changes among presymptomatic carriers of the Huntington disease gene." Arch Neurol 57(7): 1040-4.
OBJECTIVE: To confirm that subtle changes in motor function and reaction time are present in presymptomatic individuals carrying the expanded Huntington disease (HD) allele. DESIGN: A case-control, double-blind study comparing presymptomatic HD gene carriers (PSGCs) and nongene carriers (NGCs) at risk for HD. SETTING: The Department of Medical and Molecular Genetics at a general clinical research center in a midwestern city. PARTICIPANTS: Two hundred sixteen individuals at risk for HD who were asymptomatic by self-report and who did not have manifest HD on results of clinical examination, including PSGCs (n = 61) and NGCs (n = 155). MEASURES: Molecular testing was used to determine the number of CAG repeats in the HD gene. A quantified neurologic examination and a battery of physiological measures of central nervous system function measuring speed of movement and reaction time were administered. RESULTS: On neurologic examination, the PSGCs exhibited significantly more definite or possible abnormalities than NGCs for overall oculomotor function, saccade velocity, optokinetic nystagmus, chorea of the extremities, and dystonia of the extremities (P<.05). The PSGCs also had significantly slower performance for auditory reaction time, visual reaction time, visual reaction time with decision, movement time, movement time with decision, and button-tapping time, compared with the NGCs (P<.05). CONCLUSIONS: Subtle changes in motor function, speed of movement, and reaction time are present in HD gene carriers who do not exhibit definite choreiform movements and who do not have sufficient signs to make a clinical diagnosis of HD. In addition, a trend toward slower speed of movement and reaction time was observed among this population as their neurologic abnormalities increased.
Kennedy, L. and P. F. Shelbourne (2000). "Dramatic mutation instability in HD mouse striatum: does polyglutamine load contribute to cell-specific vulnerability in Huntington's disease?" Hum Mol Genet 9(17): 2539-44.
An unstable CAG triplet repeat expansion encoding a polyglutamine stretch within the ubiquitously expressed protein huntingtin is responsible for causing Huntington's disease (HD). By quantifying the repeat sizes of individual mutant alleles in tissues derived from an accurate genetic mouse model of HD we show that the mutation becomes very unstable in striatal tissue. The expansion-biased changes increase with age, such that some striatal cells from old HD mice contain mutations that have tripled in size. If this pattern of repeat instability is recapitulated in human striatal tissue, the concomitant increased polyglutamine load may contribute to the patterns of selective neuronal cell death in HD. Our findings also suggest that trinucleotide repeat instability can occur by mechanisms that are not replication-based.
Kegel, K. B., M. Kim, et al. (2000). "Huntingtin expression stimulates endosomal-lysosomal activity, endosome tubulation, and autophagy." J Neurosci 20(19): 7268-78.
An expansion of polyglutamines in the N terminus of huntingtin causes Huntington's disease (HD) and results in the accrual of mutant protein in the nucleus and cytoplasm of affected neurons. How mutant huntingtin causes neurons to die is unclear, but some recent observations suggest that an autophagic process may occur. We showed previously that huntingtin markedly accumulates in endosomal-lysosomal organelles of affected HD neurons and, when exogenously expressed in clonal striatal neurons, huntingtin appears in cytoplasmic vacuoles causing cells to shrink. Here we show that the huntingtin-enriched cytoplasmic vacuoles formed in vitro internalized the lysosomal enzyme cathepsin D in proportion to the polyglutamine-length in huntingtin. Huntingtin-labeled vacuoles displayed the ultrastructural features of early and late autophagosomes (autolysosomes), had little or no overlap with ubiquitin, proteasome, and heat shock protein 70/heat shock cognate 70 immunoreactivities, and altered the arrangement of Golgi membranes, mitochondria, and nuclear membranes. Neurons with excess cytoplasmic huntingtin also exhibited increased tubulation of endosomal membranes. Exogenously expressed human full-length wild-type and mutant huntingtin codistributed with endogenous mouse huntingtin in soluble and membrane fractions, whereas human N-terminal huntingtin products were found only in membrane fractions that contained lysosomal organelles. We speculate that mutant huntingtin accumulation in HD activates the endosomal-lysosomal system, which contributes to huntingtin proteolysis and to an autophagic process of cell death.
Johnson, W. G. (2000). "Late-onset neurodegenerative diseases--the role of protein insolubility." J Anat 196 ( Pt 4): 609-16.
Recently, mutations of the alpha-synuclein gene were found to cause dominantly inherited Lewy-body Parkinson's disease (PD) and alpha-synuclein was identified as a major component of the Lewy body. However, the cause of the common form of PD, with a multifactorial rather than autosomal dominant inheritance pattern, remains unknown. Alpha-synuclein precipitates slowly and apparently spontaneously at high concentration in solution and the mutations that cause PD accelerate precipitation. Other dominantly inherited late-onset or adult-onset dominantly inherited neurodegenerative diseases are associated with precipitation of proteins. In Alzheimer disease, beta-amyloid and tau abnormalities are present and in prion disorders, prion proteins are found. In Huntington disease, a disorder with expanded CAG repeats, huntingtin precipitates occur. In dominantly inherited spinocerebellar ataxias, also expanded CAG repeat disorders, the corresponding ataxin protein precipitates are found. In multiple system atrophy, alpha-synuclein precipitates are encountered and in progressive supranuclear palsy, tau precipitates occur. In familial amyotrophic lateral sclerosis, a group of dominantly inherited disorders, SOD1 precipitates are found. Most of these disorders can involve the basal ganglia in some way. Since similar processes seem to affect neurons of adults or older individuals and since a relatively limited group of proteins seems to be involved, each producing a form of neurodegeneration, it is possible that certain common features are present that affect this group of proteins. Candidates include a conformational shift, as in prions, an abnormality of the ubiquitin-proteosome pathway, as seen in PD, an abnormality of a pathway preventing precipitation (e.g. chaperonins), or potentiation of a pathway promoting precipitation (e.g. gamma-glutamyl-transpeptidase) or apoptosis. Elucidation of the pathways causing this protein insolubilisation is the first step towards approaching prevention and reversal in these late-onset neurodegenerative diseases.
Jenkins, B. G., P. Klivenyi, et al. (2000). "Nonlinear decrease over time in N-acetyl aspartate levels in the absence of neuronal loss and increases in glutamine and glucose in transgenic Huntington's disease mice." J Neurochem 74(5): 2108-19.
Mice transgenic for exon I of mutant huntingtin, with 141 CAG repeats, exhibit a profound symptomatology characterized by weight loss, motor disorders, and early death. We performed longitudinal analysis of metabolite levels in these mice using NMR spectroscopy in vivo and in vitro. These mice exhibited a large (53%), nonlinear drop in in vivo N-acetyl aspartate (NAA) levels over time, commencing at approximately 6 weeks of age, coincident with onset of symptoms. These drops in NAA levels occurred in the absence of neuronal death as measured by postmortem Nissl staining and neuronal counting but in the presence of nuclear inclusion bodies. In addition to decreased NAA, these mice showed a large elevation of glucose in the brain (600%) consistent with a diabetic profile and elevations in blood glucose levels both before and after glucose loading. In vitro NMR analysis revealed significant increases in glutamine (100%), taurine (95%) cholines (200%), and scyllo-inositol (333%) and decreases in glutamate (24%) and succinate (47%). These results lead to two conclusions. NAA is reflective of the health of neurons and thus is a noninvasive marker, with a temporal progression similar to nuclear inclusion bodies and symptoms, of neuronal dysfunction in transgenic mice. Second, the presence of elevated glutamine is evidence of a profound metabolic defect. We present arguments that the elevated glutamine results from a decrease in neuronal-glial glutamate-glutamine cycling and a decrease in glutaminase activity.
Jana, N. R., M. Tanaka, et al. (2000). "Polyglutamine length-dependent interaction of Hsp40 and Hsp70 family chaperones with truncated N-terminal huntingtin: their role in suppression of aggregation and cellular toxicity." Hum Mol Genet 9(13): 2009-18.
Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder caused by polyglutamine expansion in the disease protein, huntingtin. In HD patients and transgenic mice, the affected neurons form characteristic ubiquitin-positive nuclear inclusions (NIs). We have established ecdysone-inducible stable mouse Neuro2a cell lines that express truncated N-terminal huntingtin (tNhtt) with different polyglutamine lengths which form both cytoplasmic and nuclear aggregates in a polyglutamine length- and inducer dose-dependent manner. Here we demonstrate that newly synthesized polyglutamine-expanded truncated huntingtin interacts with members of Hsp40 and Hsp70 families of chaperones in a polyglutamine length-dependent manner. Of these interacting chaperones, only Hdj-2 and Hsc70 frequently (Hdj-2 > Hsc70) co-localize with both the aggregates in the cellular model and with the NIs in the brains of HD exon 1 transgenic mice. However, Hdj-2 and Hsc70 do not co-localize with cytoplasmic aggregates in the brains of transgenic mice despite these chaperones being primarily localized in the cytoplasmic compartment. This strongly suggests that the chaperone interaction and their redistribution to the aggregates are two completely different phenomena of the cellular unfolded protein response. This unfolded protein response is also evident from the dramatic induction of Hsp70 on expression of polyglutamine-expanded protein in the cellular model. Transient overexpression of either Hdj-1 or Hsc70 suppresses the aggregate formation; however, suppression efficiency is much higher in Hdj-1 compared with Hsc70. Overexpression of Hdj-1 and Hsc70 is also able to protect cell death caused by polyglutamine-expanded tNhtt and their combination proved to be most effective.
Hilditch-Maguire, P., F. Trettel, et al. (2000). "Huntingtin: an iron-regulated protein essential for normal nuclear and perinuclear organelles." Hum Mol Genet 9(19): 2789-97.
Huntington's disease (HD), with its selective neuronal cell loss, is caused by an elongated glutamine tract in the huntingtin protein. To discover the pathways that are candidates for the protein's normal and/or abnormal function, we surveyed 19 classes of organelle in Hdh(ex4/5)/Hdh(ex4/5) knock-out compared with wild-type embryonic stem cells to identify any that might be affected by huntingtin deficiency. Although the majority did not differ, dramatic changes in six classes revealed that huntingtin's function is essential for the normal nuclear (nucleoli, transcription factor-speckles) and perinuclear membrane (mitochondria, endoplasmic reticulum, Golgi and recycling endosomes) organelles and for proper regulation of the iron pathway. Moreover, upmodulation by deferoxamine mesylate implicates huntingtin as an iron-response protein. However, excess huntingtin produced abnormal organelles that resemble the deficiency phenotype, suggesting the importance of huntingtin level to the protein's normal pathway. Thus, organelles that require huntingtin to function suggest roles for the protein in RNA biogenesis, trafficking and iron homeostasis to be explored in HD pathogenesis.
Heiser, V., E. Scherzinger, et al. (2000). "Inhibition of huntingtin fibrillogenesis by specific antibodies and small molecules: implications for Huntington's disease therapy." Proc Natl Acad Sci U S A 97(12): 6739-44.
The accumulation of insoluble protein aggregates in intra and perinuclear inclusions is a hallmark of Huntington's disease (HD) and related glutamine-repeat disorders. A central question is whether protein aggregation plays a direct role in the pathogenesis of these neurodegenerative diseases. Here we show by using a filter retardation assay that the mAb 1C2, which specifically recognizes the elongated polyglutamine (polyQ) stretch in huntingtin, and the chemical compounds Congo red, thioflavine S, chrysamine G, and Direct fast yellow inhibit HD exon 1 protein aggregation in a dose-dependent manner. On the other hand, potential inhibitors of amyloid-beta formation such as thioflavine T, gossypol, melatonin, and rifampicin had little or no inhibitory effect on huntingtin aggregation in vitro. The results obtained by the filtration assay were confirmed by electron microscopy, SDS/PAGE, and MS. Furthermore, cell culture studies revealed that the Congo red dye at micromolar concentrations reduced the extent of HD exon 1 aggregation in transiently transfected COS cells. Together, these findings contribute to a better understanding of the mechanism of huntingtin fibrillogenesis in vitro and provide the basis for the development of new huntingtin aggregation inhibitors that may be effective in treating HD.
Hazeki, N., T. Tukamoto, et al. (2000). "Formic acid dissolves aggregates of an N-terminal huntingtin fragment containing an expanded polyglutamine tract: applying to quantification of protein components of the aggregates." Biochem Biophys Res Commun 277(2): 386-93.
Huntington's disease (HD) is caused by an expansion of the CAG repeat that encodes polyglutamine in huntingtin. Transient expression of an N-terminal huntingtin fragment containing an expanded polyglutamine tract induced formation of protein aggregates in cultured cells. The turnover of protein components in such aggregates has been difficult to study because of their insolubility in aqueous solutions. Here we describe a method of solubilizing the aggregates and quantifying their protein components. Insoluble pellets were collected from COS7 cells expressing an N-terminal huntingtin fragment containing an expanded polyglutamine tract and subjected to treatment with various detergent, acid, and alkaline reagents. Treatment with 100% formic acid at 37 degrees C for 30 min induced essentially complete dissociation of the aggregates to monomer. We used this solubilization technique to quantify huntingtin fusion protein in the aggregates formed in transient expression experiments. The frequency of aggregate formation increased when the proteasome inhibitor beta-lactone was added to culture media. However, the total amount of accumulated huntingtin fusion protein did not differ between cells cultured with or without beta-lactone. These results suggest that other protein components which are degraded by the proteasome, in addition to huntingtin, might be related to the dynamics of polyglutamine protein aggregates.
Hattula, K. and J. Peranen (2000). "FIP-2, a coiled-coil protein, links Huntingtin to Rab8 and modulates cellular morphogenesis." Curr Biol 10(24): 1603-6.
Huntington's disease is characterised by the death of cortical and striatal neurons, and is the result of an expanded polyglutamine tract in the Huntingtin protein [1]. Huntingtin is present on both endocytic and secretory membrane organelles but its function is unclear [2,3]. Rab GTPases regulate both of these transport pathways [4]. We have previously shown that Rab8 controls polarised membrane transport by modulating cell morphogenesis [5]. To understand Rab8-mediated processes, we searched for Rab8-interacting proteins by the yeast two-hybrid system. Here, we report that Huntingtin is linked to the Rab8 protein through FIP-2, a tumour necrosis factor-alpha (TNF-alpha)-inducible coiled-coil protein related to the NEMO protein [6,7]. The activated form of Rab8 interacted with the amino-terminal region of FIP-2, whereas dominant-negative Rab8 did not. Huntingtin bound to the carboxy-terminal region of FIP-2. Coexpressed FIP-2 and Huntingtin enhanced the recruitment of Huntingtin to Rab8-positive vesicular structures, and FIP-2 promoted cell polarisation in a similar way to Rab8. We propose a model in which Huntingtin, together with FIP-2 and Rab8, are part of a protein network that regulates membrane trafficking and cellular morphogenesis.
Haque, N. S. and O. Isacson (2000). "Neurotrophic factors NGF and FGF-2 alter levels of huntingtin (IT15) in striatal neuronal cell cultures." Cell Transplant 9(5): 623-7.
A mutation of the human IT15 gene is responsible for Huntington's disease (HD) and the causative factor in the major neuronal loss observed in the striatum. The growth factors basic fibroblast growth factor (FGF-2), nerve growth factor (NGF), and brain-derived neurotrophic factor (BDNF) improve survival and promote differentiation of striatal neurons, as well as exert a neuroprotective effect when such neurons are challenged with metabolic toxins or excitatory amino acids. Using Western blotting and striatal cell cultures, we found that FGF-2 increased the level of huntingtin in a dose-dependent fashion, whereas NGF decreased huntingtin expression. The neurotrophic factor-specific, dose-dependent effect on striatal levels of huntingtin may be relevant to understanding the normal role of IT15 and developing new therapies against the disease provoking mutated IT15.
Hackam, A. S., A. S. Yassa, et al. (2000). "Huntingtin interacting protein 1 induces apoptosis via a novel caspase-dependent death effector domain." J Biol Chem 275(52): 41299-308.
Huntington disease is a devastating neurodegenerative disease caused by the expansion of a polymorphic glutamine tract in huntingtin. The huntingtin interacting protein (HIP-1) was identified by its altered interaction with mutant huntingtin. However, the function of HIP-1 was not known. In this study, we identify HIP-1 as a proapoptotic protein. Overexpression of HIP-1 resulted in rapid caspase 3-dependent cell death. Bioinformatics analyses identified a novel domain in HIP-1 with homology to death effector domains (DEDs) present in proteins involved in apoptosis. Expression of the HIP-1 DED alone resulted in cell death indistinguishable from HIP-1, indicating that the DED is responsible for HIP-1 toxicity. Furthermore, substitution of a conserved hydrophobic phenylalanine residue within the HIP-1 DED at position 398 eliminated HIP-1 toxicity entirely. HIP-1 activity was found to be independent of the DED-containing caspase 8 but was significantly inhibited by the antiapoptotic protein Bcl-x(L), implicating the intrinsic pathway of apoptosis in HIP-1-induced cell death. Co-expression of a normal huntingtin fragment capable of binding HIP-1 significantly reduced cell death. Our data identify HIP-1 as a novel proapoptotic mediator and suggest that HIP-1 may be a molecular accomplice in the pathogenesis of Huntington disease.
Gutekunst, C. A., F. Norflus, et al. (2000). "Recent advances in Huntington's disease." Curr Opin Neurol 13(4): 445-50.
Huntington's disease is a progressive and fatal neurological disorder caused by the expansion of a CAG trinucleotide repeat in exon 1 of the gene coding for a protein of unknown function that has been named huntingtin. The exact cause of neuronal death in Huntington's disease is unknown; however, the leading hypothesis is that of excitotoxicity and apoptosis induced by a defect in energy metabolism that may be caused by oxidative stress. How mutant huntingtin might cause these processes is unknown. New animal and cell models provide insights into the mechanism of pathogenesis and the search for the development of effective therapies.
Guidetti, P., P. H. Reddy, et al. (2000). "Early kynurenergic impairment in Huntington's disease and in a transgenic animal model." Neurosci Lett 283(3): 233-5.
Several neuroactive metabolites of the kynurenine pathway of tryptophan degradation have been speculatively linked to the pathophysiology of Huntington's Disease (HD). Here we demonstrate that the levels of two of these metabolites, the free radical generator 3-hydroxykynurenine (3HK) and the neuroprotectant kynurenate (KYNA), are increased in the neostriatum of stage 1 HD patients and in the brain of mice transgenic for full-length mutant huntingtin. In both cases, the elevation in 3HK was far more pronounced, resulting in significant increases in the 3HK/KYNA ratios. These data suggest that abnormal kynurenine pathway metabolism may play a role during the early phases of the neurodegenerative process in HD.
Furlong, R. A., Y. Narain, et al. (2000). "alpha-synuclein overexpression promotes aggregation of mutant huntingtin." Biochem J 346 Pt 3: 577-81.
Protein aggregates are a neuropathological feature of Huntington's disease and Parkinson's disease. Mutant huntingtin exon 1 with 72 CAG repeats fused to enhanced green fluorescent protein (EGFP) forms hyperfluorescent inclusions in PC12 cells. Inclusion formation is enhanced in cells co-transfected with EGFP-huntingtin-(CAG)(72) and alpha-synuclein, a major component of Parkinson's disease aggregates. However, alpha-synuclein does not form aggregates by itself, nor does it appear in huntingtin inclusions in vitro.
Freeman, T. B., F. Cicchetti, et al. (2000). "Transplanted fetal striatum in Huntington's disease: phenotypic development and lack of pathology." Proc Natl Acad Sci U S A 97(25): 13877-82.
Neural and stem cell transplantation is emerging as a potential treatment for neurodegenerative diseases. Transplantation of specific committed neuroblasts (fetal neurons) to the adult brain provides such scientific exploration of these new potential therapies. Huntington's disease (HD) is a fatal, incurable autosomal dominant (CAG repeat expansion of huntingtin protein) neurodegenerative disorder with primary neuronal pathology within the caudate-putamen (striatum). In a clinical trial of human fetal striatal tissue transplantation, one patient died 18 months after transplantation from cardiovascular disease, and postmortem histological analysis demonstrated surviving transplanted cells with typical morphology of the developing striatum. Selective markers of both striatal projection and interneurons such as dopamine and c-AMP-related phosphoprotein, calretinin, acetylcholinesterase, choline acetyltransferase, tyrosine hydroxylase, calbindin, enkephalin, and substance P showed positive transplant regions clearly innervated by host tyrosine hydroxylase fibers. There was no histological evidence of immune rejection including microglia and macrophages. Notably, neuronal protein aggregates of mutated huntingtin, which is typical HD neuropathology, were not found within the transplanted fetal tissue. Thus, although there is a genetically predetermined process causing neuronal death within the HD striatum, implanted fetal neural cells lacking the mutant HD gene may be able to replace damaged host neurons and reconstitute damaged neuronal connections. This study demonstrates that grafts derived from human fetal striatal tissue can survive, develop, and are unaffected by the disease process, at least for 18 months, after transplantation into a patient with HD.
Ferrante, R. J., O. A. Andreassen, et al. (2000). "Neuroprotective effects of creatine in a transgenic mouse model of Huntington's disease." J Neurosci 20(12): 4389-97.
Huntington's disease (HD) is a progressive neurodegenerative illness for which there is no effective therapy. We examined whether creatine, which may exert neuroprotective effects by increasing phosphocreatine levels or by stabilizing the mitochondrial permeability transition, has beneficial effects in a transgenic mouse model of HD (line 6/2). Dietary creatine supplementation significantly improved survival, slowed the development of brain atrophy, and delayed atrophy of striatal neurons and the formation of huntingtin-positive aggregates in R6/2 mice. Body weight and motor performance on the rotarod test were significantly improved in creatine-supplemented R6/2 mice, whereas the onset of diabetes was markedly delayed. Nuclear magnetic resonance spectroscopy showed that creatine supplementation significantly increased brain creatine concentrations and delayed decreases in N-acetylaspartate concentrations. These results support a role of metabolic dysfunction in a transgenic mouse model of HD and suggest a novel therapeutic strategy to slow the pathological process.
Duan, W., Z. Guo, et al. (2000). "Participation of par-4 in the degeneration of striatal neurons induced by metabolic compromise with 3-nitropropionic acid." Exp Neurol 165(1): 1-11.
Huntington's disease (HD) is a progressive neurodegenerative disorder characterized by chorea, psychiatric disturbances, and dementia. It is caused by a polyglutamine repeat expansion in the huntingtin protein. The striatum is a major site of neuronal loss in HD, but the mechanisms underlying the neurodegenerative process have not been established. Systemic administration of the succinate dehydrogenase inhibitor 3-nitropropionic acid (3NP) to rodents results in motor dysfunction and degeneration of striatal neurons with features similar to those of HD. Here we report that levels of prostate apoptosis response-4 (Par-4; a protein recently linked to neuronal apoptosis) increase in striatum, and to a lesser extent in cortex and hippocampus, after systemic administration of 3NP to adult rats. The increase in Par-4 levels occurred within 6 h of 3NP administration and was followed by an increase in caspase activation which preceded neuronal loss. Exposure of cultured primary striatal neurons to 3NP induced a rapid increase of Par-4 levels and caspase activation. Treatment of striatal neurons with a Par-4 antisense oligonucleotide blocked Par-4 induction by 3NP, suppressed caspase activation, and attenuated neuronal apoptosis. The caspase-3 inhibitor DEVD suppressed 3NP-induced apoptosis of striatal neurons, but did not prevent induction of Par-4, indicating that Par-4 acts upstream of caspase-3 activation in the cell death pathway. Our results suggest that Par-4 plays an important role in the degeneration of striatal neurons in an experimental model of HD.
Dragatsis, I., P. Dietrich, et al. (2000). "Expression of the Huntingtin-associated protein 1 gene in the developing and adult mouse." Neurosci Lett 282(1-2): 37-40.
Huntingtin-associated protein 1 (HAP1) interacts with the product of the Huntington's disease gene. To investigate the function of Hap1 in development and in the adult mouse, we have examined the expression of Hap1 by northern analysis and in situ hybridization histochemistry. Hap1 expression is first detected in the embryonic day 8.5 (E8.5) neuroepithelium. Expression persists throughout development, predominantly in the brain and spinal cord, and to a lesser extent in enteric neurons and abdominal sympathetic ganglia. In the adult, Hap1 expression is detected not only in the brain but also in the ovary, testis, and the intermediate lobe of the pituitary.
Dragatsis, I., M. S. Levine, et al. (2000). "Inactivation of Hdh in the brain and testis results in progressive neurodegeneration and sterility in mice." Nat Genet 26(3): 300-6.
Inactivation of the mouse homologue of the Huntington disease gene (Hdh) results in early embryonic lethality. To investigate the normal function of Hdh in the adult and to evaluate current models for Huntington disease (HD), we have used the Cre/loxP site-specific recombination strategy to inactivate Hdh expression in the forebrain and testis, resulting in a progressive degenerative neuronal phenotype and sterility. On the basis of these results, we propose that huntingtin is required for neuronal function and survival in the brain and that a loss-of-function mechanism may contribute to HD pathogenesis.
DiFiglia, M. (2000). "Genetics of childhood disorders: X. Huntington disease." J Am Acad Child Adolesc Psychiatry 39(1): 120-2.
Diamond, M. I., M. R. Robinson, et al. (2000). "Regulation of expanded polyglutamine protein aggregation and nuclear localization by the glucocorticoid receptor." Proc Natl Acad Sci U S A 97(2): 657-61.
Spinobulbar muscular atrophy and Huntington's disease are caused by polyglutamine expansion in the androgen receptor and huntingtin, respectively, and their pathogenesis has been associated with abnormal nuclear localization and aggregation of truncated forms of these proteins. Here we show, in diverse cell types, that glucocorticoids can up- or down-modulate aggregation and nuclear localization of expanded polyglutamine polypeptides derived from the androgen receptor and huntingtin through specific regulation of gene expression. Wild-type glucocorticoid receptor (GR), as well as C-terminal deletion derivatives, suppressed the aggregation and nuclear localization of these polypeptides, whereas mutations within the DNA binding domain and N terminus of GR abolished this activity. Surprisingly, deletion of a transcriptional regulatory domain within the GR N terminus markedly increased aggregation and nuclear localization of the expanded polyglutamine proteins. Thus, aggregation and nuclear localization of expanded polyglutamine proteins are regulated cellular processes that can be modulated by a well-characterized transcriptional regulator, the GR. Our findings suggest approaches to study the molecular pathogenesis and selective neuronal degeneration of polyglutamine expansion diseases.
Di Prospero, N. A. and D. A. Tagle (2000). "Normal and mutant huntingtin: partners in crime." Nat Med 6(11): 1208-9.
Coles, R., M. Birdsall, et al. (2000). "12-O-tetradecanoyl-phorbol-13-acetate down-regulates the Huntingtin promoter at Sp1 sites." Neuroreport 11(14): 3157-61.
We have studied the effects of the phorbol ester, 12-O-tetradecanoyl-phorbol-13-acetate (TPA) on Huntington's disease (HD) gene transcription in neuronal and non-neuronal cell lines, to investigate pathways regulating HD gene expression. TPA reduced transcription from the HD gene promoter in SK-N-SH (neuroblastoma) and HeLa cells but not in JEG3 (choriocarcinoma) cells. In SK-N-SH cells, the responsible cis-acting promoter sequences comprise the tandemly duplicated Sp1 sites in the region from -213 to -174, relative to the translation start site. The TPA-down-regulating region in HeLa cells was mapped to the sequence from -141 to -126. In conclusion, this demonstrates that HD gene transcription can be down-regulated in vitro in a cell-specific manner.
Chopra, V. S., M. Metzler, et al. (2000). "HIP12 is a non-proapoptotic member of a gene family including HIP1, an interacting protein with huntingtin." Mamm Genome 11(11): 1006-15.
Huntingtin-interacting protein I (HIP1) is a membrane-associated protein that interacts with huntingtin, the protein altered in Huntington disease. HIP1 shows homology to Sla2p, a protein essential for the assembly and function of the cytoskeleton and endocytosis in Saccharomyces cerevisiae. We have determined that the HIP1 gene comprises 32 exons spanning approximately 215 kb of genomic DNA and gives rise to two alternate splice forms termed HIP1-1 and HIP1-2. Additionally, we have identified a novel protein termed HIP12 with significant sequence and biochemical similarities to HIP1 and high sequence similarity to Sla2p. HIP12 differs from HIP1 in its pattern of expression both at the mRNA and protein level. However, HIP1 and HIP12 are both found within the brain and show a similar subcellular distribution pattern. In contrast to HIP1, which is toxic in cell culture, HIP12 does not confer toxicity in the same assay systems. Interestingly, HIP12 does not interact with huntingtin but can interact with HIP1. suggesting a potential interaction in vivo that may influence the function of each respective protein.
Charles, V., E. Mezey, et al. (2000). "Alpha-synuclein immunoreactivity of huntingtin polyglutamine aggregates in striatum and cortex of Huntington's disease patients and transgenic mouse models." Neurosci Lett 289(1): 29-32.
Polyglutamine expansions in proteins are implicated in at least eight inherited neurodegenerative disorders, including Huntington's disease. These mutant proteins can form aggregates within the nucleus and processes of neurons possibly due to misfolding of the proteins. Polyglutamine aggregates are ubiquitinated and sequester molecular chaperone proteins and proteasome components. To investigate other protein components of polyglutamine aggregates, cerebral cortex and striata from patients with Huntington's disease and full-length cDNA transgenic mouse models for this disease were examined immunohistochemically for alpha-synuclein reactivity. Our findings demonstrate that alpha-synuclein can be used as a marker for huntingtin polyglutamine aggregates in both human and mice. Moreover in the HD transgenic mice, the intensity of immunoreactivity increases with age. The significance of recruitment of alpha-synuclein into huntingtin aggregates and its translocation away from the synapses remains to be determined. We propose that aberrant interaction of mutant huntingtin with other proteins, including alpha-synuclein, may influence disease progression.
Cha, J. H. (2000). "Transcriptional dysregulation in Huntington's disease." Trends Neurosci 23(9): 387-92.
Although the gene responsible for Huntington's disease was discovered in 1993, the pathogenic mechanisms by which mutant huntingtin causes neuronal dysfunction and death remain unclear. However, increasing evidence suggests that mutant huntingtin disrupts the normal transcriptional program of susceptible neurons. Thus, transcriptional dysregulation might be an important pathogenic mechanism in Huntington's disease.
Carmichael, J., J. Chatellier, et al. (2000). "Bacterial and yeast chaperones reduce both aggregate formation and cell death in mammalian cell models of Huntington's disease." Proc Natl Acad Sci U S A 97(17): 9701-5.
Huntington's disease (HD) is an autosomal dominant neurodegenerative condition caused by expansions of more than 35 uninterrupted CAG repeats in exon 1 of the huntingtin gene. The CAG repeats in HD and the other seven known diseases caused by CAG codon expansions are translated into long polyglutamine tracts that confer a deleterious gain of function on the mutant proteins. Intraneuronal inclusions comprising aggregates of the relevant mutant proteins are found in the brains of patients with HD and related diseases. It is crucial to determine whether the formation of inclusions is directly pathogenic, because a number of studies have suggested that aggregates may be epiphenomena or even protective. Here, we show that fragments of the bacterial chaperone GroEL and the full-length yeast heat shock protein Hsp104 reduce both aggregate formation and cell death in mammalian cell models of HD, consistent with a causal link between aggregation and pathology.
Brouillet, E. (2000). "Animal models of Huntington's disease: from basic research on neuronal death to assessment of new therapeutic strategies." Funct Neurol 15(4): 239-51.
Bonilla, E. (2000). "[Huntington disease. A review]." Invest Clin 41(2): 117-41.
Huntington's disease (HD) is a hereditary autosomal dominant neurodegenerative disease characterized by motor, cognitive and psychiatric symptoms. It affects about 1 in 10,000 individuals. The onset of symptoms typically occurs in the third or fourth decade of life, though it may appear at any age. The molecular basis of the disease is the expansion of the trinucleotide CAG in the first exon of a gene on chromosome four (4p 16.3). This gene encodes the protein huntingtin of 3136 amino acids. The mutation of huntingtin produces an expanded stretch of glutamine (Gln) residues. This CAG/polyGln expansion has 6 to 39 units in normal individuals and 36 to 180 units in HD patients. The normal function of huntingtin and the pathogenic mechanisms caused by the expanded polyGln of mutant huntingtin remain incompletely characterized. Huntingtin appears to be associated with synaptic vesicles and/or microtubules and seems to have an important role in vesicular transport and/or the binding to the cytoskeleton. It is thought that this protein is important in embryogenesis and that its mutant form alters the function of the mitochondrial respiratory chain. The toxic gain of function caused by huntingtin could either be an overactivity of the normal function or the introduction of a novel function. Its interactions with other proteins could lead to an impairment of the cellular function or to its own polymerization to form insoluble aggregates. The intraneuronal aggregates could affect gene transcription, protein interactions, protein transport inside the nucleus and cytoplasm, and the vesicular transport. However, since a dissociation between the aggregation of huntingtin and the selective pattern of striatal neuronal loss has been demonstrated, it is believed that other properties of the mutant huntingtin, like proteolysis and the interactions with other proteins that affect vesicular trafficking and nuclear transport, could be responsible for the neurodegeneration. On gross examination, 80% of HD brains show atrophy of the frontal lobes. A bilateral, symmetric atrophy of the striatum is observed in 95% of the HD brains. The mean brain weight in HD patients is approximately 30% lower than in normal individuals. Striatal degeneration has an ordered and topographic distribution. The tail of the caudate nucleus shows more degeneration than the head. The caudate atrophy is associated to a gradual atrophy and neuronal loss in other brain regions as the disease progresses. The striatal and cerebral cortex projection neurons are much more susceptible to the disease than interneurons. In the neostriatum, the levels of GABA, dynorphin and substance P are decreased, but the concentrations of somatostatin and neuropeptide Y increase. An impairment of energy metabolism in HD and a sensitivity to oxidative stress and to the cytotoxic effects of glutamate seem to contribute to the neuronal death in HD. It is proposed that melatonin should be assayed in cell cultures and in transgenic animals due to its potent antioxidant and free radical scavenger properties.
Boado, R. J., A. Kazantsev, et al. (2000). "Antisense-mediated down-regulation of the human huntingtin gene." J Pharmacol Exp Ther 295(1): 239-43.
The present study determines whether the expression of the huntingtin gene might be subject to antisense (AS)-mediated down-regulation. A series of AS oligodeoxynucleotides (ODNs) complementary to the huntingtin transcript [i.e., nucleotide (nt) -25 to 35] were designed and synthesized, and the AS efficacy was investigated by using a combination of in vitro transcription and translation to mimic in vivo conditions. An oligomer directed to nt -1 to 15 (ODN III) markedly reduced the incorporation of [(3)H]leucine into the huntingtin gene product in a dose-dependent manner (ED(50) of approximately 11.5 microM). ODNs that overlap with ODN III on both 5'- and 3'-flanking regions also produced translation arrest of the huntingtin protein; however, the AS-mediated effect of these ODNs represented approximately 50% of the effect of ODN III. In contrast, an ODN directed to nt 19 to 35 had no AS effect. The efficacy of ODN III also was investigated in an inducible, stably transfected PC-12 cell line expressing a truncated huntingtin exon 1 protein. In accordance with the cell free translation studies, ODN III (1-10 microM) markedly decreased the abundance of the huntingtin-green fluorescence fusion protein to 40 to 46% of the control levels. In summary, a series of putative AS candidates were screened for down-regulation of the huntingtin gene, and an ODN molecule directed to the methionine initiation codon was identified with maximum AS effects.
Bibb, J. A., Z. Yan, et al. (2000). "Severe deficiencies in dopamine signaling in presymptomatic Huntington's disease mice." Proc Natl Acad Sci U S A 97(12): 6809-14.
In Huntington's disease (HD), mutation of huntingtin causes selective neurodegeneration of dopaminoceptive striatal medium spiny neurons. Transgenic HD model mice that express a portion of the disease-causing form of human huntingtin develop a behavioral phenotype that suggests dysfunction of dopaminergic neurotransmission. Here we show that presymtomatic mice have severe deficiencies in dopamine signaling in the striatum. These include selective reductions in total levels of dopamine- and cAMP-regulated phosphoprotein, M(r) 32 kDA (DARPP-32) and other dopamine-regulated phosphoprotein markers of medium spiny neurons. HD mice also show defects in dopamine-regulated ion channels and in the D(1) dopamine/DARPP-32 signaling cascade. These presymptomatic defects may contribute to HD pathology.
Bates, G. (2000). "Huntington's disease. In reverse gear." Nature 404(6781): 944-5.
Bates, G. and J. Eberwine (2000). "Hunting in the calm before the storm." Nat Genet 25(4): 365-6.
(2000). "Untangling huntingtin's mysteries." Nat Med 6(10): 1063.
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