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Formation of intracellular protein complexes is often mediated by Src homology 3 domain-containing proteins interacting with proline-rich target sequences on other proteins. The Sh3d2c gene or its rat/human orthologs have been implicated in synaptic vesicle recycling due to interaction with dynamin I and synaptojanin in nerve terminals. In a yeast two-hybrid system, association with a huntingtin fragment containing an elongated stretch of polyglutamines was observed recently. By genetic mapping and fluorescence in situ hybridization we demonstrate the localization of Sh3d2c on mouse chromosome 7. A processed pseudogene of Sh3d2c, Sh3d2c-ps1, was identified and mapped to mouse chromosome 2. Using RNA in situ hybridization, we show that Sh3d2c is transcribed in various regions of the brain. The striatum, hippocampus, cortex, basal hypothalamus, brain stem, and cerebellum are the most prominent sites of expression. Because huntingtin and Sh3d2c are coexpressed in most regions of the brain, it can be speculated that there is a link between the association of huntingtin/Sh3d2c and the pathogenesis of Huntington disease. Wood, J. D., J. Yuan, et al. (1998). "Atrophin-1, the DRPLA gene product, interacts with two families of WW domain-containing proteins." Mol Cell Neurosci 11(3): 149-60. Atrophin-1 contains a polyglutamine repeat, expansion of which is responsible for dentatorubral and pallidoluysian atrophy (DRPLA). The normal function of atrophin-1 is unknown. We have identified five atrophin-1 interacting proteins (AIPs) which bind to atrophin-1 in the vicinity of the polyglutamine tract using the yeast two-hybrid system. Four of the interactions were confirmed using in vitro binding assays. All five interactors contained multiple WW domains. Two are novel. The AIPs can be divided into two distinct classes. AIP1 and AIP3/WWP3 are MAGUK-like multidomain proteins containing a number of protein-protein interaction modules, namely a guanylate kinase-like region, two WW domains, and multiple PDZ domains. AIP2/WWP2, AIP4, and AIP5/WWP1 are highly homologous, each having four WW domains and a HECT domain characteristic of ubiquitin ligases. These interactors are similar to recently isolated huntingtin-interacting proteins, suggesting possible commonality of function between two proteins responsible for very similar diseases. Wellington, C. L., L. M. Ellerby, et al. (1998). "Caspase cleavage of gene products associated with triplet expansion disorders generates truncated fragments containing the polyglutamine tract." J Biol Chem 273(15): 9158-67. The neurodegenerative diseases Huntington disease, dentatorubropallidoluysian atrophy, spinocerebellar atrophy type 3, and spinal bulbar muscular atrophy are caused by expansion of a polyglutamine tract within their respective gene products. There is increasing evidence that generation of truncated proteins containing an expanded polyglutamine tract may be a key step in the pathogenesis of these disorders. We now report that, similar to huntingtin, atrophin-1, ataxin-3, and the androgen receptor are cleaved in apoptotic extracts. Furthermore, each of these proteins is cleaved by one or more purified caspases, cysteine proteases involved in apoptotic death. The CAG length does not modulate susceptibility to cleavage of any of the full-length proteins. Our results suggest that by generation of truncated polyglutamine-containing proteins, caspase cleavage may represent a common step in the pathogenesis of each of these neurodegenerative diseases. Walling, H. W., J. J. Baldassare, et al. (1998). "Molecular aspects of Huntington's disease." J Neurosci Res 54(3): 301-8. Huntington's disease (HD) is a progressive neurodegenerative disease striking principally medium spiny GABAergic neurons of the caudate nucleus of the basal ganglia. It affects about one in 10,000 individuals and is transmitted in an autosomal dominant fashion. The molecular basis of the disease is expansion of the trinucleotide CAG in the first exon of a gene on chromosome four. The CAG repeats are translated to polyglutamine repeats in the expressed protein, huntingtin. The normal function of huntingtin remains incompletely characterized, but based upon recently defined protein-protein interactions, it appears to be associated with the cytoskeleton and required for neurogenesis. Huntingtin has been demonstrated to interact with such proteins as HAP1, HIP1, microtubules, GADPH, calmodulin, and an ubiquitin-conjugating enzyme. Polyglutamine expansion alters many of these interactions and leads to huntingtin aggregation and the formation of neuronal nuclear inclusions, ultimately culminating in cell death. In this review, we discuss the molecular aspects of HD, including the present understanding of huntingtin-protein interactions, studies with transgenic mice, and postulated mechanisms of huntingtin aggregation. Velier, J., M. Kim, et al. (1998). "Wild-type and mutant huntingtins function in vesicle trafficking in the secretory and endocytic pathways." Exp Neurol 152(1): 34-40. Huntingtin is a cytoplasmic protein that is found in neurons and somatic cells. In patients with Huntington's disease (HD), the NH2-terminal region of huntingtin has an expanded polyglutamine tract. An abnormal protein interaction by mutant huntingtin has been proposed as a mechanism for HD pathogenesis. Huntingtin associates with vesicle membranes and interacts with proteins involved in vesicle trafficking. It is unclear where along vesicle transport pathways wild-type and mutant huntingtins are found and whether polyglutamine expansion affects this localization. To distinguish wild-type and mutant huntingtin, fibroblasts from normals and HD patients with two mutant alleles (homozygotes) were examined. Immunofluorescence confocal microscopy showed that mutant huntingtin localized with clathrin in membranes of the trans Golgi network and in clathrin-coated and noncoated endosomal vesicles in the cytoplasm and along plasma membranes. Separation of organelles in Nycodenz gradients showed that in normal and HD homozygote patient cells, huntingtin was present in membrane fractions enriched in clathrin. Similar results were obtained in fibroblasts from heterozyote juvenile HD patients who had a highly expanded polyglutamine tract in the HD allele. Western blot analysis of membrane fractions from rat brain showed that wild-type huntingtin was present in fractions that contained purified clathrin-coated membranes or a mixture of clathrin-coated and noncoated membranes. Electron microscopy of huntingtin immunoreactivity in rat brain revealed labeling along dendritic plasma membranes in association with clathrin-coated pits and clusters of noncoated endosomal vesicles 40-60 nm in diameter. These data suggest that wild-type and mutant huntingtin can influence vesicle transport in the secretory and endocytic pathways through associations with clathrin-coated vesicles. Utal, A. K., A. L. Stopka, et al. (1998). "PEP-19 immunohistochemistry defines the basal ganglia and associated structures in the adult human brain, and is dramatically reduced in Huntington's disease." Neuroscience 86(4): 1055-63. We have investigated the distribution of PEP-19, a neuron-specific protein, in the adult human brain. Immunohistochemistry for PEP-19 appears to define the basal ganglia and related structures. The strongest immunoreactivity is seen in the caudate nucleus and putamen, each of which showed both cell body and neuropil PEP-19 immunoreactivity. The substantia nigra and both segments of the globus pallidus showed PEP-19 immunoreactivity only in the neuropil. Cell bodies and dendrites of the thalamic nuclei ventralis lateralis and ventralis anterioralis were less strongly immunoreactive. Cerebellar Purkinje cells and their dendrites were immunoreactive, as were the presubiculum/subiculum regions and dentate gyrus granule cells of the hippocampus. The CA zones of the hippocampus were not immunoreactive. Preliminary data from immunoblotting experiments indicate that PEP-19 immunoreactivity is significantly reduced in cerebellum in Alzheimer's disease. While there were no apparent alterations of immunoreactivity in Down's syndrome or in Parkinson's disease, immunohistochemical analysis showed a massive loss of PEP-19 immunoreactivity in the caudate nucleus, putamen, globus pallidus and substantia nigra in Huntington's disease. These results show that PEP-19, a neuron-specific, calmodulin-binding protein, is distributed in specific areas of the adult human brain. The reduction in PEP-19 immunoreactivity in Alzheimer's disease and Huntington's disease suggests that PEP-19 may play a role in the pathophysiology of these diseases through a mechanism of calcium/calmodulin disregulation. This may be especially apparent in Huntington's disease where the distribution of the product of the abnormal gene, huntingtin, alone is not sufficient to explain the pattern of pathology. Abnormal huntingtin associates more strongly with calmodulin than does normal huntingtin [Bao et al. (1996) Proc. natn. Acad. Sci. U.S.A., 93, 5037-5042] suggesting a disruption of calmodulin-mediated intracellular mechanism(s), very likely involving PEP-19. tom Dieck, S., L. Sanmarti-Vila, et al. (1998). "Bassoon, a novel zinc-finger CAG/glutamine-repeat protein selectively localized at the active zone of presynaptic nerve terminals." J Cell Biol 142(2): 499-509. The molecular architecture of the cytomatrix of presynaptic nerve terminals is poorly understood. Here we show that Bassoon, a novel protein of >400,000 Mr, is a new component of the presynaptic cytoskeleton. The murine bassoon gene maps to chromosome 9F. A comparison with the corresponding rat cDNA identified 10 exons within its protein-coding region. The Bassoon protein is predicted to contain two double-zinc fingers, several coiled-coil domains, and a stretch of polyglutamines (24 and 11 residues in rat and mouse, respectively). In some human proteins, e.g., Huntingtin, abnormal amplification of such poly-glutamine regions causes late-onset neurodegeneration. Bassoon is highly enriched in synaptic protein preparations. In cultured hippocampal neurons, Bassoon colocalizes with the synaptic vesicle protein synaptophysin and Piccolo, a presynaptic cytomatrix component. At the ultrastructural level, Bassoon is detected in axon terminals of hippocampal neurons where it is highly concentrated in the vicinity of the active zone. Immunogold labeling of synaptosomes revealed that Bassoon is associated with material interspersed between clear synaptic vesicles, and biochemical studies suggest a tight association with cytoskeletal structures. These data indicate that Bassoon is a strong candidate to be involved in cytomatrix organization at the site of neurotransmitter release. Thomas, P., F. Wilkinson, et al. (1998). "Full length huntingtin is not detected in intranuclear inclusions in Huntington's disease brain." Biochem Soc Trans 26(3): S243. Sittler, A., S. Walter, et al. (1998). "SH3GL3 associates with the Huntingtin exon 1 protein and promotes the formation of polygln-containing protein aggregates." Mol Cell 2(4): 427-36. The mechanism by which aggregated polygins cause the selective neurodegeneration in Huntington's disease (HD) is unknown. Here, we show that the SH3GL3 protein, which is preferentially expressed in brain and testis, selectively interacts with the HD exon 1 protein (HDex1p) containing a glutamine repeat in the pathological range and promotes the formation of insoluble polyglutamine-containing aggregates in vivo. The C-terminal SH3 domain in SH3GL3 and the proline-rich region in HDex1p are essential for the interaction. Coimmunoprecipitations and immunofluorescence studies revealed that SH3GL3 and HDex1p colocalize in transfected COS cells. Additionally, an anti-SH3GL3 antibody was also able to coimmunoprecipitate the full-length huntingtin from an HD human brain extract. The characteristics of the interaction between SH3GL3 and huntingtin and the colocalization of the two proteins suggest that SH3GL3 could be involved in the selective neuronal cell death in HD. Singhrao, S. K., P. Thomas, et al. (1998). "Huntingtin protein colocalizes with lesions of neurodegenerative diseases: An investigation in Huntington's, Alzheimer's, and Pick's diseases." Exp Neurol 150(2): 213-22. Huntington's disease (HD) is an autosomal dominant neurodegenerative disease associated with a CAG trinucleotide repeat expansion in a large gene on chromosome 4. The gene encodes the protein huntingtin with a polyglutamine tract encoded by the CAG repeat at the N-terminus. The number of CAG repeats in HD are significantly increased (36 to 120+) compared with the normal population (8-39). The pathological mechanism associated with the expanded CAG repeat in HD is not clear but there is evidence that polyglutamine is directly neurotoxic. We have immunolocalized huntingtin with an in-house, well-characterised, polyclonal antibody in HD, Alzheimer's disease (AD), and Picks disease (PiD) brains. Control brain tissue sections were from head injured and cerebral ischaemia cases. In HD, huntingtin was immunopositive in the surviving but damaged neurons and reactive astrocytes of the caudate and putamen. However, in AD and PiD the immunostaining was largely restricted to the characteristic intracellular inclusion bodies associated with the disease process in each case. In AD, huntingtin was localized only in the intracellular neurofibrillary tangles and dystrophic neurites within the neuritic amyloid plaques but not with the amyloid. In PiD, strongly positive huntingtin immunostaining was present within cytoplasmic Pick bodies. Our findings suggest huntingtin selectively accumulates in association with abnormal intracytoplasmic and cytoskeletal filaments of neurons and glia in neurodegenerative diseases such as HD, AD, and PiD. Cells in the CNS appear sensitive to damage by the aggregated, toxic levels of huntingtin and evidence of its interaction with neurofilaments could provide information about its potential role in the aetiology of HD. Shibuya, H., P. C. Liu, et al. (1998). "A BbvI mismatch PCR/RFLP marker for the canine huntingtin gene." Anim Genet 29(3): 239-40. Seki, N., M. Muramatsu, et al. (1998). "Cloning, expression analysis, and chromosomal localization of HIP1R, an isolog of huntingtin interacting protein (HIP1)." J Hum Genet 43(4): 268-71. Huntington disease (HD) is an inherited neurodegenerative disorder which is associated with CAG expansion in the coding region of the gene for huntingtin protein. Recently, a huntingtin interacting protein, HIP1, was isolated by the yeast two-hybrid system. Here we report the isolation of a cDNA clone for HIP1R (huntingtin interacting protein-1 related), which encodes a predicted protein product sharing a striking homology with HIP1. RT-PCR analysis showed that the messenger RNA was ubiquitously expressed in various human tissues. Based on PCR-assisted analysis of a radiation hybrid panel and fluorescence in situ hybridization, HIP1R was localized to the q24 region of chromosome 12. Schapira, A. H. (1998). "Mitochondrial dysfunction in neurodegenerative disorders." Biochim Biophys Acta 1366(1-2): 225-33. Mutations of mitochondrial DNA (mtDNA) are associated with a wide spectrum of disorders encompassing the myopathies, encephalopathies and cardiomyopathies, in addition to organ specific presentations such as diabetes mellitus and deafness. The pathogenesis of mtDNA mutations is not fully understood although it is assumed that their final common pathway involves impaired oxidative phosphorylation. The identification of a specific respiratory chain defect (complex I deficiency) in Parkinson's disease (PD) 10 years ago focused attention on the aetiological and pathogenetic roles that mitochondria may play in neurodegenerative diseases. There is evidence now emerging that mtDNA abnormalities may determine the complex I defect in a proportion of PD patients and it may prove possible to use biochemical analysis of platelet and cybrid complex I function to identify those that lie within this group. Respiratory chain defects of a different pattern have been identified in Huntington's disease (HD) (complex II/III deficiency) and Friedreich's ataxia (FA) complex I-III deficiency). In both these disorders, the mitochondrial abnormality is secondary to the primary nuclear mutation:CAG repeat in the huntingtin gene in HD, and GAA repeat in the frataxin gene in FA. Nevertheless, it appears that the mitochondrion may be the target of the biochemical defects that are the consequence of these mutations. There is a close and reciprocal relationship between respiratory chain dysfunction and free radical generation, and there is evidence for oxidative stress and damage in PD, HD and FA, which together with the mitochondrial defect may result in cell damage. Impaired oxidative phosphorylation and free radical generation may independently adversely affect the maintenance of mitochondrial transmembrane potential (Deltapsim). A fall in Deltapsim is an early event (preceding nuclear fragmentation) in the apoptotic pathway. It is possible therefore that mitochondrial dysfunction in the neurodegenerative disorders may result in a fall in the apoptotic threshold of neurones which, in some, may be sufficient to induce cell death whilst, in others, additional factors may be required. In any event, mitochondria present an important target for future strategies for 'neuroprotection' to prevent or retard neurodegeneration. Saudou, F., S. Finkbeiner, et al. (1998). "Huntingtin acts in the nucleus to induce apoptosis but death does not correlate with the formation of intranuclear inclusions." Cell 95(1): 55-66. The mechanisms by which mutant huntingtin induces neurodegeneration were investigated using a cellular model that recapitulates features of neurodegeneration seen in Huntington's disease. When transfected into cultured striatal neurons, mutant huntingtin induces neurodegeneration by an apoptotic mechanism. Antiapoptotic compounds or neurotrophic factors protected neurons against mutant huntingtin. Blocking nuclear localization of mutant huntingtin suppressed its ability to form intranuclear inclusions and to induce neurodegeneration. However, the presence of inclusions did not correlate with huntingtin-induced death. The exposure of mutant huntingtin-transfected striatal neurons to conditions that suppress the formation of inclusions resulted in an increase in mutant huntingtin-induced death. These findings suggest that mutant huntingtin acts within the nucleus to induce neurodegeneration. However, intranuclear inclusions may reflect a cellular mechanism to protect against huntingtin-induced cell death. Ross, T. S., O. A. Bernard, et al. (1998). "Fusion of Huntingtin interacting protein 1 to platelet-derived growth factor beta receptor (PDGFbetaR) in chronic myelomonocytic leukemia with t(5;7)(q33;q11.2)." Blood 91(12): 4419-26. We report the fusion of the Huntingtin interactin protein 1 (HIP1) gene to the platelet-derived growth factor betareceptor (PDGFbetaR) gene in a patient with chronic myelomonocytic leukemia (CMML) with a t(5;7)(q33;q11.2) translocation. Southern blot analysis of patient bone marrow cells with a PDGFbetaR gene probe demonstrated rearrangement of the PDGFbetaR gene. Anchored polymerase chain reaction using PDGFbetaR primers identified a chimeric transcript containing the HIP1 gene located at 7q11.2 fused to the PDGFbetaR gene on 5q33. HIP1 is a 116-kD protein recently cloned by yeast two-hybrid screening for proteins that interact with Huntingtin, the mutated protein in Huntington's disease. The consequence of t(5;7)(q33;q11.2) is an HIP1/PDGFbetaR fusion gene that encodes amino acids 1 to 950 of HIP1 joined in-frame to the transmembrane and tyrosine kinase domains of the PDGFbetaR. The reciprocal PDGFbetaR/HIP1 transcript is not expressed. HIP1/PDGFbetaR is a 180-kD protein when expressed in the murine hematopoietic cell line, Ba/F3, and is constitutively tyrosine phosphorylated. Furthermore, HIP1/PDGFbetaR transforms the Ba/F3 cells to interleukin-3-independent growth. These data are consistent with an alternative mechanism for activation of PDGFbetaR tyrosine kinase activity by fusion with HIP1, leading to transformation of hematopoietic cells, and may implicate Huntingtin or HIP1 in the pathogenesis of hematopoietic malignancies. Rosenblatt, A., N. G. Ranen, et al. (1998). "Patients with features similar to Huntington's disease, without CAG expansion in huntingtin." Neurology 51(1): 215-20. OBJECTIVE: To describe characteristics of gene-negative patients with clinical features of Huntington's disease (HD), exploring likely etiologies. BACKGROUND: When a direct gene test became definitive for diagnosis of HD, we discovered a number of patients in our clinics in Baltimore, MD, and Cambridge, UK, believed or suspected to have HD who did not have the triplet repeat expansion. METHODS: Patients were examined using standardized instruments, and given full neurologic and psychiatric evaluations. Those negative for HD were tested for dentatorubro-pallidoluysian atrophy, SCA-1, SCA-3, SCA-2, SCA-6, and other conditions as indicated. RESULTS: Of 15 patients, 7 received specific diagnoses or appear to be sporadic cases, 4 have a possible but uncertain relation to HD, and 4 have unknown familial progressive movement disorders. CONCLUSIONS: This last group of patients might be properly described as phenocopies of HD, some of which may be caused by unidentified triplet repeat expansions. Reddy, P. H., M. Williams, et al. (1998). "Behavioural abnormalities and selective neuronal loss in HD transgenic mice expressing mutated full-length HD cDNA." Nat Genet 20(2): 198-202. Huntington disease (HD) is an adult-onset, autosomal dominant inherited human neurodegenerative disorder characterized by hyperkinetic involuntary movements, including motor restlessness and chorea, slowing of voluntary movements and cognitive impairment. Selective regional neuron loss and gliosis in striatum, cerebral cortex, thalamus, subthalamus and hippocampus are well recognized as neuropathological correlates for the clinical manifestations of HD. The underlying genetic mutation is the expansion of CAG trinucleotide repeats (coding for polyglutamines) to 36-121 copies in exon 1 of the HD gene. The HD mRNA and protein product (huntingtin) show widespread distribution, and thus much remains to be understood about the selective and progressive neurodegeneration in HD. To create an experimental animal model for HD, transgenic mice were generated showing widespread expression of full-length human HD cDNA with either 16, 48 or 89 CAG repeats. Only mice with 48 or 89 CAG repeats manifested progressive behavioural and motor dysfunction with neuron loss and gliosis in striatum, cerebral cortex, thalamus and hippocampus. These animals represent clinically relevant models for HD pathogenesis, and may provide insights into the underlying pathophysiological mechanisms of other triplet repeat disorders. Page, K. J., L. Potter, et al. (1998). "The expression of Huntingtin-associated protein (HAP1) mRNA in developing, adult and ageing rat CNS: implications for Huntington's disease neuropathology." Eur J Neurosci 10(5): 1835-45. Using radioactive in situ hybridization, we have mapped the expression of Huntingtin-associated protein (HAP1) mRNA in rat brain at developmental stages (E12-E19, PO-P21), in adult rats (3 months) and in 'aged' (19-21 months) rats. Using two pairs of 45mer oligonucleotide probes specific for HAP1A and a probe which recognizes regions of both the HAP1A and HAP1B mRNA sequences (panHAP1), we find that the expression of HAP1 mRNA is specific to the CNS and restricted predominantly to anatomically connected limbic structures, particularly the amygdala (medial and corticomedial nuclei), the hypothalamus (arcuate, preoptic, paraventricular and lateral hypothalamic area), bed nucleus of the stria terminalis (BNST) and the lateral septal nuclei. HAP1 mRNA was detected in embryos at E12 and displayed a prevalent distribution in the developing limbic structures by E15. In aged, 19-21-months-old, rats there is a downregulation of HAP1 mRNA expression across all CNS loci where HAP1 was previously abundant. The lowest levels of HAP1 mRNA expression corresponded with the areas of greatest pathological cell loss in Huntington's disease (HD); the caudate putamen, globus pallidus and neocortex. These observations support the suggestion that HAP1 plays an important role in the neuropathology of HD. Nasir, J., K. Duan, et al. (1998). "Gene structure and map location of the murine homolog of the Huntington-associated protein, Hap1." Mamm Genome 9(7): 565-70. Huntington's Disease (HD) is an inherited progressive neurodegenerative disorder associated with a mutation in a gene expressed in both affected and non-affected tissues. The selective neuropathology in HD is thought to be mediated in part through interactions with other proteins including the Huntington Associated Protein, HAP-1, which is predominantly expressed in the brain. We have mapped its murine homolog, Hap1, to mouse Chr 11 (band D), which shares extensive synteny with human Chr 17 including the region 17q21-q22, where the gene for 'frontotemporal dementia and parkinsonism linked to chromosome 17' has bee mapped. In addition, we have sequenced a 21,984 base pair (bp) genomic clone encompassing the entire Hap1 gene. It is organized as 11 exons and flanked by exons from potentially one or more novel genes. At least three Hap1 transcripts (Hap1-A; Hap1-B; Hap1-C) can be formed by alternative splicing at the 3' end of the gene leading to protein isoforms with novel C-termini. Nance, M. A. (1998). "Huntington disease: clinical, genetic, and social aspects." J Geriatr Psychiatry Neurol 11(2): 61-70. Huntington disease (HD) is a fascinating neurodegenerative disorder whose features straddle the boundaries of psychiatry, neurology, and genetics. The clinical symptoms of HD consist of a triad of motor, cognitive, and psychiatric/behavioral disturbances. In 1993, the HD Collaborative Research Group identified the gene and the mutation responsible for HD. HD was one of the first neurodegenerative disorders discovered to be caused by a novel mutational mechanism known as trinucleotide repeat expansion. Since then, HD has been the model for autosomal dominant neurogenetic disorders. The clinical, pathological, and genetic aspects of the disease are reviewed and some of the questions that remain to be answered by researchers of the 21st century are outlined. Mitchell, A. (1998). "A fly's eye view of Huntington's disease." Nature 395(6705): 841. Martindale, D., A. Hackam, et al. (1998). "Length of huntingtin and its polyglutamine tract influences localization and frequency of intracellular aggregates." Nat Genet 18(2): 150-4. It is unclear how polyglutamine expansion is associated with the pathogenesis of Huntington disease (HD). Here, we provide evidence that polyglutamine expansion leads to the formation of large intracellular aggregates in vitro and in vivo. In vitro these huntingtin-containing aggregates disrupt normal cellular architecture and increase in frequency with polyglutamine length. Huntingtin truncated at nucleotide 1955, close to the caspase-3 cleavage site, forms perinuclear aggregates more readily than full-length huntingtin and increases the susceptibility of cells to death following apoptotic stimuli. Further truncation of huntingtin to nucleotide 436 results in both intranuclear and perinuclear aggregates. For a given protein size, increasing polyglutamine length is associated with increased cellular toxicity. Asymptomatic transgenic mice expressing full-length huntingtin with 138 polyglutamines form exclusively perinuclear aggregates in neurons. These data support the hypothesis that proteolytic cleavage of mutant huntingtin leads to the development of aggregates which compromise cell viability, and that their localization is influenced by protein length. Lunkes, A. and J. L. Mandel (1998). "A cellular model that recapitulates major pathogenic steps of Huntington's disease." Hum Mol Genet 7(9): 1355-61. To gain insight into the pathogenic mechanisms of Huntington's disease (HD), we have developed a stable cellular model, using a neuroblastoma cell line in which the expression of full-length or truncated forms of wild-type and mutant huntingtin can be induced. While the wild-type forms have the expected cytoplasmic localization, the expression of mutant proteins leads to the formation of cytoplasmic and nuclear inclusions in a time- and polyglutamine length-dependent manner. The inclusions are ubiquitinated, appear more rapidly in cells expressing truncated forms of mutant huntingtin and are correlated with enhanced apoptosis. In lines expressing mutant full-length huntingtin, major characteristics present in Huntington's patients could be modelled. Selective processing of the mutant, but not the wild-type, full-length huntingtin was observed at late time points, with appearance of a breakdown product corresponding to a predicted caspase-3 cleavage product. A more truncated N-terminal fragment of huntingtin is also produced, that appears involved in building up cytoplasmic inclusions at early time points, and later on also nuclear inclusions. This fits with the finding that inclusions in the brain of HD patients are detected only using antibodies directed against epitopes very close to the polyglutamine stretch. This unique model should thus be useful to study the processing mechanism of mutant huntingtin, its role in the formation of intracellular aggregates and the effect of the latter on cellular physiology. Lunkes, A., Y. Trottier, et al. (1998). "Pathological mechanisms in Huntington's disease and other polyglutamine expansion diseases." Essays Biochem 33: 149-63. HD is an autosomal dominant neurodegenerative disorder characterized by involuntary movements, cognitive impairment progressing to dementia, and mood disturbances. The brains of patients show extensive neuronal loss in the striatum, and the cerebral cortex is also affected. The genetic defect causing HD is an expansion of a CAG repeat encoding a polyglutamine stretch in the target protein, named huntingtin. The age of onset of HD is inversely correlated with the size of the expansion. Polyglutamine expansion represents a novel cause of neurodegeneration, which has been shown to be responsible for seven other inherited disorders. The polyglutamine expansion confers a gain of toxic property to the mutated target proteins. Molecular and cellular studies of the brains of patients and of mice models of polyglutamine expansion diseases have led to the identification of abnormal intracellular inclusions representing aggregation of the mutated protein. However, the mechanism whereby such polyglutamine expansion leads to selective neuronal dysfunction and death is still puzzling. Liu, Y. F. (1998). "Expression of polyglutamine-expanded Huntingtin activates the SEK1-JNK pathway and induces apoptosis in a hippocampal neuronal cell line." J Biol Chem 273(44): 28873-7. Huntington's disease is one of a growing number of hereditary neurodegenerative disorders caused by expansion of a polyglutamine stretch at the NH2 terminus of huntingtin. To explore whether polyglutamine-expanded huntingtin induces neuronal toxicity, I examined the expression of the full-length of huntingtin with 16, 48, or 89 polyglutamine repeats in a rat hippocampal neuronal cell (HN33). Expression of mutated huntingtin with 48 or 89 polyglutamine repeats stimulated c-Jun amino-terminal kinases (JNKs) activity and induced apoptotic cell death in HN33 cells while expression of normal huntingtin with 16 polyglutamine repeats had no toxic effect. The JNK activation precedes apoptotic cell death and co-expression of a dominant negative mutant form of stress-signaling kinase (SEK1) nearly completely blocked activation of JNKs and neuronal apoptosis mediated by mutated huntingtin. Taken together, my studies demonstrate that expression of polyglutamine-expanded huntingtin induces neuronal apoptosis via activation of the SEK1-JNK pathway. Li, S. H., C. A. Gutekunst, et al. (1998). "Interaction of huntingtin-associated protein with dynactin P150Glued." J Neurosci 18(4): 1261-9. Huntingtin is the protein product of the gene for Huntington's disease (HD) and carries a polyglutamine repeat that is expanded in HD (>36 units). Huntingtin-associated protein (HAP1) is a neuronal protein and binds to huntingtin in association with the polyglutamine repeat. Like huntingtin, HAP1 has been found to be a cytoplasmic protein associated with membranous organelles, suggesting the existence of a protein complex including HAP1, huntingtin, and other proteins. Using the yeast two-hybrid system, we found that HAP1 also binds to dynactin P150(Glued) (P150), an accessory protein for cytoplasmic dynein that participates in microtubule-dependent retrograde transport of membranous organelles. An in vitro binding assay showed that both huntingtin and P150 selectively bound to a glutathione transferase (GST)-HAP1 fusion protein. An immunoprecipitation assay demonstrated that P150 and huntingtin coprecipitated with HAP1 from rat brain cytosol. Western blot analysis revealed that HAP1 was enriched in rat brain microtubules and comigrated with P150 and huntingtin in sucrose gradients. Immunofluorescence showed that transfected HAP1 colocalized with P150 and huntingtin in human embryonic kidney (HEK) 293 cells. We propose that HAP1, P150, and huntingtin are present in a protein complex that may participate in dynein-dynactin-associated intracellular transport. Li, S. H. and X. J. Li (1998). "Aggregation of N-terminal huntingtin is dependent on the length of its glutamine repeats." Hum Mol Genet 7(5): 777-82. Huntington's disease (HD) is caused by expansion of a glutamine repeat in huntingtin. Mutant huntingtin contains 36-55 repeats in adult HD patients and >60 repeats in juvenile HD patients. An N-terminal fragment of mutant huntingtin forms aggregates in neuronal nuclei in the brains of transgenic mice and HD patients. Aggregation of expanded polyglutamine is thought to be a common pathological mechanism in HD and other glutamine repeat diseases. It is not clear how the length of the repeats is correlated with formation of protein aggregates. By expressing a series of huntingtin constructs encoding various glutamine repeats (23-150 units) in cultured cells we observed N-terminal fragments of huntingtin (amino acids 1-67 and 1-212), but not full-length huntingtins, with glutamine repeats >/=66 units formed protein aggregates. Huntingtin aggregation was not induced when the repeat was </=49 units and was markedly promoted by very long repeats >/=120 units. This study suggests that various N-terminal fragments of mutant huntingtin can form aggregates and that aggregation is prompted by lengthening the glutamine repeat. Li, S. H., S. H. Hosseini, et al. (1998). "A human HAP1 homologue. Cloning, expression, and interaction with huntingtin." J Biol Chem 273(30): 19220-7. Huntington's disease (HD) is caused by the expansion of a glutamine repeat in the protein huntingtin. The expanded glutamine repeat is thought to mediate a gain of function by causing huntingtin to abnormally interact with other proteins. We previously identified a rat huntingtin-associated protein (HAP1) that binds to huntingtin; HAP1 binds more tightly to huntingtin with an expanded glutamine repeat than to wild type huntingtin. Identification of the human homologue of HAP1 is necessary for investigation of the potential role of HAP1 in HD pathology. Here, we report the cloning of a human HAP1 homologue (hHAP) that shares 62% identity with rat HAP1 over its entire sequence and 82% amino acid identity in the putative huntingtin-binding region. The hHAP gene encodes a 4.1-kilobase transcript and a 75-kDa protein which are specifically expressed in human brain tissues. Its expression in Huntington's disease brains is reduced in parallel with a decreased expression of huntingtin. While two isoforms of rat HAP1 are expressed at similar levels in rat brain, only a single major form of hHAP is found in primate brains. In vitro binding, immunoprecipitation, and coexpression studies confirm the interaction of hHAP with huntingtin. The in vitro binding of hHAP to huntingtin is enhanced by lengthening the glutamine repeat. Despite similar binding properties of rat HAP1 and hHAP, differences in the sequences and expression of hHAP may contribute to a specific role for its interaction with huntingtin in humans. Li, S. H., C. A. Gutekunst, et al. (1998). "Association of HAP1 isoforms with a unique cytoplasmic structure." J Neurochem 71(5): 2178-85. HAP1 is a neural protein and interacts with the Huntington's disease protein huntingtin. There are at least two HAP1 isoforms, HAP1-A and HAP1-B, which have different C-terminal amino acid sequences. Here we report that both HAP1 isoforms associate with a unique cytoplasmic structure in neurons of rat brain. The HAP1-immunoreactive structure appears as an inclusion that is an oval mass of electron-dense material, 0.5-3 microm in diameter, containing many curvilinear or ring-shaped segments, and often containing electron-lucent cores. This structure is very similar to those previously termed the stigmoid body, nematosome, or botrysome. Transfection of cell lines with cDNA encoding HAP1-A, but not HAP1-B, resulted in similar HAP1-immunoreactive inclusions in the cytoplasm, suggesting that HAP1-A is essential to the formation of this structure. Yeast two-hybrid and transfection studies show that both HAP1-A and HAP1-B can self-associate, implying that native HAP1 in the cytoplasmic inclusion may be a heteromultimer of HAP1-A and HAP1-B. Coexpression of HAP1-A and HAP1-B in human embryonic kidney 293 cells demonstrates that the ratio of the expressed HAP1-A to HAP1-B regulates the formation of HAP1-associated inclusions. We propose that HAP1 isoforms are involved in the formation of HAP1-immunoreactive inclusions in the neuronal cytoplasm. Lathrop, R. H., M. Casale, et al. (1998). "Modeling protein homopolymeric repeats: possible polyglutamine structural motifs for Huntington's disease." Proc Int Conf Intell Syst Mol Biol 6: 105-14. We describe a prototype system (Poly-X) for assisting an expert user in modeling protein repeats. Poly-X reduces the large number of degrees of freedom required to specify a protein motif in complete atomic detail. The result is a small number of parameters that are easily understood by, and under the direct control of, a domain expert. The system was applied to the polyglutamine (poly-Q) repeat in the first exon of huntingtin, the gene implicated in Huntington's disease. We present four poly-Q structural motifs: two poly-Q beta-sheet motifs (parallel and antiparallel) that constitute plausible alternatives to a similar previously published poly-Q beta-sheet motif, and two novel poly-Q helix motifs (alpha-helix and pi-helix). To our knowledge, helical forms of polyglutamine have not been proposed before. The motifs suggest that there may be several plausible aggregation structures for the intranuclear inclusion bodies which have been found in diseased neurons, and may help in the effort to understand the structural basis for Huntington's disease. Karlovich, C. A., R. M. John, et al. (1998). "Characterization of the Huntington's disease (HD) gene homologue in the zebrafish Danio rerio." Gene 217(1-2): 117-25. The Huntington's disease (HD) gene contains a trinucleotide repeat that is expanded and unstable in patients with the disease (HDCRG, 1993). As the first step toward investigating a potential role for this gene in early vertebrate development, we isolated the homolog of the Huntington's disease (ZHD) cDNA in zebrafish. This cDNA encodes a predicted protein product of 3121 amino acids with 70% identity to human huntingtin. The first exon is predicted to encode four glutamines, followed by only one proline, demonstrating that the polymorphic polyproline stretch found in mammalian HD sequences is absent in the fish. We sequenced approximately 900bp upstream from the predicted start codon and found that it lacks a TATA box, CCAAT box, or Sp1 binding sites. Western blot analysis revealed that the protein is expressed at a high level in late embryonic development and at moderate levels in the adult head. Kahlem, P., H. Green, et al. (1998). "Transglutaminase action imitates Huntington's disease: selective polymerization of Huntingtin containing expanded polyglutamine." Mol Cell 1(4): 595-601. Different proteins bearing polyglutamine of excessive length are lethal to neurons and cause human disease of the central nervous system. In parts of the brain affected by Huntington's disease, the amount of the huntingtin with expanded polyglutamine is reduced and there appear huntingtin-containing polymers of larger molecular weight. We show here that huntingtin is a substrate of transglutaminase in vitro and that the rate constant of the reaction increases with length of the polyglutamine over a range of an order of magnitude. As a result, huntingtin with expanded polyglutamine is preferentially incorporated into polymers. Both disappearance of the huntingtin with expanded polyglutamine and its replacement by polymeric forms are prevented by inhibitors of transglutaminase. The effect of transglutaminase therefore duplicates the changes in the affected parts of the brain. Jackson, G. R., I. Salecker, et al. (1998). "Polyglutamine-expanded human huntingtin transgenes induce degeneration of Drosophila photoreceptor neurons." Neuron 21(3): 633-42. Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder. Disease alleles contain a trinucleotide repeat expansion of variable length, which encodes polyglutamine tracts near the amino terminus of the HD protein, huntingtin. Polyglutamine-expanded huntingtin, but not normal huntingtin, forms nuclear inclusions. We describe a Drosophila model for HD. Amino-terminal fragments of human huntingtin containing tracts of 2, 75, and 120 glutamine residues were expressed in photoreceptor neurons in the compound eye. As in human neurons, polyglutamine-expanded huntingtin induced neuronal degeneration. The age of onset and severity of neuronal degeneration correlated with repeat length, and nuclear localization of huntingtin presaged neuronal degeneration. In contrast to other cell death paradigms in Drosophila, coexpression of the viral antiapoptotic protein, P35, did not rescue the cell death phenotype induced by polyglutamine-expanded huntingtin. Huang, C. C., P. W. Faber, et al. (1998). "Amyloid formation by mutant huntingtin: threshold, progressivity and recruitment of normal polyglutamine proteins." Somat Cell Mol Genet 24(4): 217-33. Huntington's disease (HD) is caused by an expanded CAG trinucleotide repeat encoding a tract of consecutive glutamines near the amino terminus of huntingtin, a large protein of unknown function. It has been proposed that the expanded polyglutamine stretch confers a new property on huntingtin and thereby causes cell and region-specific neurodegeneration. Genotype-phenotype correlations predict that this novel property appears above a threshold length (approximately 38 glutamines), becomes progressively more evident with increasing polyglutamine length, is completely dominant over normal huntingtin and is not appreciably worsened by a double genetic dose in HD homozygotes. Recently, an amino terminal fragment of mutant huntingtin has been found to form self-initiated fibrillar aggregates in vitro. We have tested the capacity for aggregation to assess whether this property matches the criteria expected for a fundamental role in HD pathogenesis. We find that that in vitro aggregation displays a threshold and progressivity for polyglutamine length remarkably similar to the HD disease process. Moreover, the mutant huntingtin amino terminus is capable of recruiting into aggregates normal glutamine tract proteins, such as the amino terminal segments of both normal huntingtin and of TATA-binding protein (TBP). Our examination of in vivo aggregates from HD post-mortem brains indicates that they contain an amino terminal segment of huntingtin of between 179 and 595 residues. They also contain non-huntingtin protein, as evidenced by immunostaining for TBP. Interestingly, like the in vitro aggregates, aggregates from HD brain display Congo red staining with green birefringence characteristic of amyloid. Our data support the view that the expanded polyglutamine segment confers on huntingtin a new property that plays a determining role in HD pathogenesis and could be a target for treatment. Moreover, the new property might have its toxic consequences by interaction with one or more normal polyglutamine-containing proteins essential for the survival of target neurons. Holzmann, C., W. Maueler, et al. (1998). "Isolation and characterization of the rat huntingtin promoter." Biochem J 336 ( Pt 1): 227-34. Huntington's disease (HD) is a neurodegenerative disorder caused by a (CAG)>37 repeat expansion in a novel gene of unknown function. Although the huntingtin gene is expressed in neuronal and non-neuronal tissues, the disease affects nerve cells of selected regional areas of the central nervous system. To gain insight into the regulation of the HD gene we analysed 1348 bp of the rat huntingtin promoter region. This region lacks a TATA and a CAAT box, is rich in GC content and has several consensus sequences for binding sites for SP1, PEA3, Sif and H2A. The stretch between nucleotides -56 and -206 relative to the first ATG is highly conserved between human and rodents and it harbours several potential binding sites for transcription factors. We analysed deletion mutants fused with the chloramphenicol acetyltransferase reporter gene in transfected, HD-expressing neuronal (NS20Y, NG108-15) and non-neuronal Chinese hamster ovary cell lines. Hence these cells should contain the required trans-acting factors necessary for HD gene expression. Partial deletion of the evolutionarily conserved part of the promoter significantly decreases the activity in both neuronal and non-neuronal cells, indicating that the core promoter activity is located between nucleotides -332 and -15. DNase I footprinting and electrophoretic mobility-shift assays were used to define the nucleotide positions and binding affinity of DNA-protein interactions. Himmelbauer, H., N. Wedemeyer, et al. (1998). "IRS-PCR-based genetic mapping of the huntingtin interacting protein gene (HIP1) on mouse chromosome 5." Mamm Genome 9(1): 26-31. Huntington's disease (HD) is a devastating central nervous system disorder. Even though the gene responsible has been positionally cloned recently, its etiology has remained largely unclear. To investigate potential disease mechanisms, we conducted a search for binding partners of the HD-protein huntingtin. With the yeast two-hybrid system, one such interacting factor, the huntingtin interacting protein-1 (HIP-1), was identified (Wanker et al. 1997; Kalchman et al. 1997) and the human gene mapped to 7q11.2. In this paper we demonstrate the localization of the HIP1 mouse homologue (Hip1) into a previously identified region of human-mouse synteny on distal mouse Chromosome (Chr) 5, both employing an IRS-PCR-based mapping strategy and traditional fluorescent in situ hybridization (FISH) mapping. Hayden, M. R. (1998). "In vitro and in vivo models for Huntington disease: lessons for the polyglutamine expansion disorders." Pathol Biol (Paris) 46(9): 695-6. Hackam, A. S., R. Singaraja, et al. (1998). "The influence of huntingtin protein size on nuclear localization and cellular toxicity." J Cell Biol 141(5): 1097-105. Huntington disease is an autosomal dominant neurodegenerative disorder caused by the pathological expansion of a polyglutamine tract. In this study we directly assess the influence of protein size on the formation and subcellular localization of huntingtin aggregates. We have created numerous deletion constructs expressing successively smaller fragments of huntingtin and show that these smaller proteins containing 128 glutamines form both intranuclear and perinuclear aggregates. In contrast, larger NH2-terminal fragments of huntingtin proteins with 128 glutamines form exclusively perinuclear aggregates. These aggregates can form in the absence of endogenous huntingtin. Furthermore, expression of mutant huntingtin results in increased susceptibility to apoptotic stress that is greater with decreasing protein length and increasing polyglutamine size. As both intranuclear and perinuclear aggregates are clearly associated with increased cellular toxicity, this supports an important role for toxic polyglutamine-containing fragments forming aggregates and playing a key role in the pathogenesis of Huntington disease. Gutekunst, C. A., S. H. Li, et al. (1998). "The cellular and subcellular localization of huntingtin-associated protein 1 (HAP1): comparison with huntingtin in rat and human." J Neurosci 18(19): 7674-86. The cellular and subcellular distribution of HAP1 was examined in rat brain by light and electron microscopic immunocytochemistry and subcellular fractionation. HAP1 localization was also determined in human postmortem tissue from control and Huntington's disease (HD) cases by light microscopic immunocytochemistry. At the cellular level, the heterogeneity of HAP1 expression was similar to that of huntingtin; however, HAP1 immunoreactivity was more widespread. The subcellular distribution of HAP1 was examined using immunogold electron microscopy. Like huntingtin, HAP1 is a cytoplasmic protein that associates with microtubules and many types of membranous organelles, including mitochondria, endoplasmic reticulum, tubulovesicles, endosomal and lysosomal organelles, and synaptic vesicles. A quantitative comparison of the organelle associations of HAP1 and huntingtin showed them to be almost identical. Within HAP1-immunoreactive neurons in rat and human brain, populations of large and small immunoreactive puncta were visible by light microscopy. The large puncta, which were especially evident in the ventral forebrain, were intensely HAP1 immunoreactive. Electron microscopic analysis revealed them to be a type of nucleolus-like body, which has been named a stigmoid body, that may play a role in protein synthesis. The small puncta, less intensely labeled, were primarily mitochondria. These results indicate that the localization of HAP1 and huntingtin is more similar than previously appreciated and provide further evidence that HAP1 and huntingtin have localizations consistent with roles in intracellular transport. Our data also suggest, however, that HAP1 is not present in the abnormal intranuclear and neuritic aggregates containing the N-terminal fragment of mutant huntingtin that are found in HD brains. Gusella, J. F. and M. E. MacDonald (1998). "Huntingtin: a single bait hooks many species." Curr Opin Neurobiol 8(3): 425-30. Cloning of the Huntington's disease gene uncovered huntingtin, which is remarkable for its lack of similarity with known proteins despite its large size, approximately 350 kDa. Subsequent experiments established that huntingtin has an as yet unknown function, crucial for embryonic development and neurogenesis. Recent protein trapping to identify huntingtin interactors now reveals that many different prey fall victim to huntingtin bait. Gourfinkel-An, I., G. Cancel, et al. (1998). "Neuronal distribution of intranuclear inclusions in Huntington's disease with adult onset." Neuroreport 9(8): 1823-6. Neuronal intranuclear inclusions were recently found in the brain of patients with inherited neurodegenerative disorders characterized by the expansion of a polyglutamine stretch in the mutated protein. These inclusions are ubiquitinated and, for some of these diseases, the presence of the mutated protein could be also identified. Using immunohistochemistry, we show here that ubiquitinated intranuclear inclusions are also observed postmortem in the brain of patients suffering from Huntington's disease characterized by small polyglutamine expansions and adult onset. We were, however, unable to detect the mutated form of huntingtin in these inclusions. These intranuclear inclusions were detected only in the affected cerebral regions, suggesting that their presence is probably linked to the neurodegenerative process. Georgalis, Y., E. B. Starikov, et al. (1998). "Huntingtin aggregation monitored by dynamic light scattering." Proc Natl Acad Sci U S A 95(11): 6118-21. An initial stage of fibrillogenesis in solutions of glutathione S-transferase-huntingtin (GST-HD) fusion proteins has been studied by using dynamic light scattering. Two GST-HD systems with poly-L-glutamine (polyGln) extensions of different lengths (20 and 51 residues) have been examined. For both systems, kinetics of z-average translation diffusion coefficients (Dapp) and their angular dependence have been obtained. Our data reveal that aggregation does occur in both GST-HD51 and GST-HD20 solutions, but that it is much more pronounced in the former. Thus, our approach provides a powerful tool for the quantitative assay of GST-HD fibrillogenesis in vitro. Gentile, V., C. Sepe, et al. (1998). "Tissue transglutaminase-catalyzed formation of high-molecular-weight aggregates in vitro is favored with long polyglutamine domains: a possible mechanism contributing to CAG-triplet diseases." Arch Biochem Biophys 352(2): 314-21. To investigate possible biochemical mechanisms underlying the "toxic gain of function" associated with polyglutamine expansions, the ability of guinea pig liver tissue transglutaminase to catalyze covalent attachments of various polyamines to polyglutamine peptides was examined. Of the polyamines tested, spermine is the most active substrate, followed by spermidine and putrescine. Formation of covalent cross links between polyglutamine peptides and polyamines yields high-M(r) aggregates--a process that is favored with longer polyglutamines. In the presence of tissue transglutaminase, purified glyceraldehyde-3-phosphate dehydrogenase (a key glycolytic enzyme that binds tightly to the polyglutamine domains of both huntingtin and dentatorubral-pallidoluysian atrophy proteins) is covalently attached to polyglutamine peptides in vitro, resulting in the formation of high-M(r) aggregates. In addition, endogenous glyceraldehyde-3-phosphate dehydrogenase of a Balb-c 3T3 fibroblast cell line overexpressing human tissue transglutaminase forms cross-links with a Q60 polypeptide added to the cell homogenate. Possibly, expansion of polyglutamine domains (thus far known to occur in the gene products associated with at least seven neurodegenerative diseases) leads to increased/aberrant tissue transglutaminase-catalyzed cross-linking reactions with both polyamines and susceptible proteins, such as glyceraldehyde-3-phosphate dehydrogenase. Formation of cross-linked heteropolymers may lead to deposition of high-M(r) protein aggregates, thereby contributing to cell death. Feigin, A. (1998). "Advances in Huntington's disease: implications for experimental therapeutics." Curr Opin Neurol 11(4): 357-62. The gene mutation causing Huntington's disease was identified in 1993 as an expanded trinucleotide repeat within the coding region for a 348-kd protein called huntingtin. The mechanism by which this cytosine-adenosine-guanosine repeat produces the progressive signs and symptoms of Huntington's disease remains uncertain, but recent advances have begun to provide insights into this process. Promising developments include transgenic mouse models of Huntington's disease with neuronal intranuclear inclusions, the identification of differential neuronal features which might account for the selective vulnerability of neurons seen in Huntington's disease and further evidence for the role of excitotoxicity and impaired mitochondrial energy production. These observations have suggested new therapeutic strategies, and have lent further support for experimental therapeutics aimed at improving mitochondrial function and reducing excitotoxic injury. Faber, P. W., G. T. Barnes, et al. (1998). "Huntingtin interacts with a family of WW domain proteins." Hum Mol Genet 7(9): 1463-74. The hallmark neuropathology of Huntington's disease (HD) is due to elongation of a polyglutamine segment in huntingtin, a novel approximately 350 kDa protein of unknown function. We used a yeast two-hybrid interactor screen to identify proteins whose association with huntingtin might be altered in the pathogenic process. Surprisingly, no interactors were found with internal and C-terminal segments of huntingtin. In contrast, huntingtin's N-terminus detected 13 distinct proteins, seven novel and six reported previously. Among these, we identified a major interactor class, comprising three distinct WW domain proteins, HYPA, HYPB and HYPC, that bind normal and mutant huntingtin in extracts of HD lymphoblastoid cells. This interaction is mediated by huntingtin's proline-rich region and is enhanced by lengthening the adjacent glutamine tract. Although HYPB and HYPC are novel, HYPA is human FBP-11, a protein implicated in spliceosome function. The emergence of this class of proteins as huntingtin partners argues that a WW domain-mediated process, such as non-receptor signaling, protein degradation or pre-mRNA splicing, may participate in HD pathogenesis. Dragatsis, I., A. Efstratiadis, et al. (1998). "Mouse mutant embryos lacking huntingtin are rescued from lethality by wild-type extraembryonic tissues." Development 125(8): 1529-39. Mouse embryos nullizygous for a targeted disruption of the Huntington's disease gene homologue (Hdh), which encodes a protein (huntingtin) of unknown biochemical function, become developmentally retarded and disorganized, and die early in development. Using chimeric analysis, we demonstrate that extensively chimeric embryos derived by injection of Hdh null ES cells into wild-type host blastocysts are rescued from lethality. In contrast, when wild-type ES cells are injected into Hdh null blastocysts, the chimeric embryos are morphologically indistinguishable from Hdh null mutants derived from natural matings, and die shortly after gastrulation. Therefore, the primary defect in the absence of huntingtin lies in extraembryonic tissues, whereas the epiblast and its derivatives are affected secondarily. It is likely that the mutation results in impairment of the nutritive functions of the visceral endoderm, which otherwise appears to differentiate normally, as evidenced by the expression of several specific marker genes. Consistent with preliminary histochemical analysis indicating that at least the transport of ferric ions is defective in Hdh mutants and in conjunction with the known localization of huntingtin in the membranes of vesicles associated with microtubules, we hypothesize that this protein is involved in the intracellular trafficking of nutrients in early embryos. Davies, S. W., K. Beardsall, et al. (1998). "Are neuronal intranuclear inclusions the common neuropathology of triplet-repeat disorders with polyglutamine-repeat expansions?" Lancet 351(9096): 131-3. Neuronal intranuclear inclusions have been found in the brain of a transgenic mouse model of Huntington's disease and in necropsy brain tissue of patients with Huntington's disease. We suggest that neuronal intranuclear inclusions are the common neuropathology for all inherited diseases caused by expansion of polyglutamine repeats. We also suggest that patients with a pathological diagnosis of neuronal intranuclear hyaline inclusion disease may also have polyglutamine repeat expansions. Culvenor, J. G., A. Henry, et al. (1998). "Subcellular localization of the Alzheimer's disease amyloid precursor protein and derived polypeptides expressed in a recombinant yeast system." Amyloid 5(2): 79-89. Different isoforms and derived polypeptides of the Alzheimer's disease amyloid protein precursor (A beta PP) have been expressed in the yeast Pichia pastoris. The expression characteristics of the different A beta PP polypeptides were studied by post-embedding immunogold electron microscopy with various A beta PP antibodies. The site of intracellular expression could be readily identified with specific antibodies. Full length A beta PP was expressed in association with the nuclear membrane and the endoplasmic reticulum. Secretory derivatives of A beta PP were localized in membrane-bound secretory vesicles. A construct encoding two copies of beta A4[1-42] linked head-to-tail (beta A4duplex) accumulated as irregular dense cytoplasmic and intranuclear inclusions which reacted with all beta A4 antibodies tested. A beta A4-C-terminal construct accumulated into membranous structures in the cytoplasm and nucleus and reacted with most antibodies to beta A4 and the cytoplasmic domain of A beta PP. The two shorter constructs containing the beta A4 sequence formed similar intranuclear aggregates to those reported for intranuclear inclusions of polyglutamine peptides from huntingtin (in Huntington's disease) and ataxin protein fragments (in spinocerebellar ataxia). This is of interest because intracellular aggregation of the polyglutamine and beta A4 peptides may affect cells by similar toxic mechanisms. These studies demonstrate clear differences in the expression properties of different A beta PP polypeptides. Cooper, J. K., G. Schilling, et al. (1998). "Truncated N-terminal fragments of huntingtin with expanded glutamine repeats form nuclear and cytoplasmic aggregates in cell culture." Hum Mol Genet 7(5): 783-90. Huntington's disease (HD) is a progressive neurodegenerative disorder caused by an expanding CAG repeat coding for polyglutamine in the huntingtin protein. Recent data have suggested the possibility that an N-terminal fragment of huntingtin may aggregate in neurons of patients with HD, both in the cytoplasm, forming dystrophic neurites, and in the nucleus, forming intranuclear neuronal inclusion bodies. An animal model of HD using the short N-terminal fragment of huntingtin has also been found to have intranuclear inclusions and this same fragment can aggregate in vitro . We have now developed a cell culture model demonstrating that N-terminal fragments of huntingtin with expanded glutamine repeats aggregate both in the cytoplasm and in the nucleus. Neuroblastoma cells transiently transfected with full-length huntingtin constructs with either a normal or expanded repeat had diffuse cytoplasmic localization of the protein. In contrast, cells transfected with truncated N-terminal fragments showed aggregation only if the glutamine repeat was expanded. The aggregates were often ubiquitinated. The shorter truncated product appeared to form more aggregates in the nucleus. Cells transfected with the expanded repeat construct but not the normal repeat construct showed enhanced toxicity to the apoptosis-inducing agent staurosporine. These data indicate that N-terminal truncated fragments of huntingtin with expanded glutamine repeats can aggregate in cells in culture and that this aggregation can be toxic to cells. This model will be useful for future experiments to test mechanisms of aggregation and toxicity and potentially for testing experimental therapeutic interventions. Coles, R., R. Caswell, et al. (1998). "Functional analysis of the Huntington's disease (HD) gene promoter." Hum Mol Genet 7(5): 791-800. The basis for the highly specific neuronal vulnerability seen in Huntington's disease (HD) has not been determined. Recent studies have demonstrated that variation in HD protein expression occurs in the striatum, with affected regions showing increased HD immunoreactivity. Experiments in HD and SCA1 transgenic mice suggest a correlation between phenotypic severity and expression of the mutant transgene. To gain insights into control of HD gene expression, and to investigate the possibility of cell-cell differences in transcription, we have analysed the 5' upstream region of the HD gene in a neuronal (SK-N-SH) and a non-neuronal (JEG3) cell line. Reporter gene assays demonstrated the presence of a key positive-acting region apparently arising from two Sp1 sites in a tandem repeat acting synergistically. This site is polymorphic, and a single Sp1 site is associated with reduced levels of transcription. These experiments also reveal differences in control of expression between neuronal and non-neuronal cell lines. Chiariotti, L., G. Benvenuto, et al. (1998). "Identification and characterization of a novel RING-finger gene (RNF4) mapping at 4p16.3." Genomics 47(2): 258-65. We have isolated a new human RING-finger gene (RNF4) that encodes a 190-amino-acid protein. RNF4, in addition to the carboxyl-terminally located RING-finger motif, contains two putative nuclear localization signals and stretches of acidic amino acids that are similar to the activation domains of some transcription factors. RNF4 was expressed at low levels in all human tissues examined, with the notable exception of very high expression in the testis. The mouse homolog of RNF4 was abundantly expressed in embryonic tissues from the earliest days postgestation and exhibited a ubiquitous pattern of expression as assessed by in situ hybridization. We have mapped RNF4 to 4p16.3, a chromosome region associated with several genetic and neoplastic diseases. RNF4 spans 47 kb, is composed of eight exons, and maps immediately proximal to the anonymous locus D4S183, between the huntingtin (HD) and the fibroblast growth factor receptor 3 (FGFR3) genes. Cha, J. H., C. M. Kosinski, et al. (1998). "Altered brain neurotransmitter receptors in transgenic mice expressing a portion of an abnormal human huntington disease gene." Proc Natl Acad Sci U S A 95(11): 6480-5. Loss of neurotransmitter receptors, especially glutamate and dopamine receptors, is one of the pathologic hallmarks of brains of patients with Huntington disease (HD). Transgenic mice that express exon 1 of an abnormal human HD gene (line R6/2) develop neurologic symptoms at 9-11 weeks of age through an unknown mechanism. Analysis of glutamate receptors (GluRs) in symptomatic 12-week-old R6/2 mice revealed decreases compared with age-matched littermate controls in the type 1 metabotropic GluR (mGluR1), mGluR2, mGluR3, but not the mGluR5 subtype of G protein-linked mGluR, as determined by [3H]glutamate receptor binding, protein immunoblotting, and in situ hybridization. Ionotropic alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid and kainate receptors were also decreased, while N-methyl-D-aspartic acid receptors were not different compared with controls. Other neurotransmitter receptors known to be affected in HD were also decreased in R6/2 mice, including dopamine and muscarinic cholinergic, but not gamma-aminobutyric acid receptors. D1-like and D2-like dopamine receptor binding was drastically reduced to one-third of control in the brains of 8- and 12-week-old R6/2 mice. In situ hybridization indicated that mGluR and D1 dopamine receptor mRNA were altered as early as 4 weeks of age, long prior to the onset of clinical symptoms. Thus, altered expression of neurotransmitter receptors precedes clinical symptoms in R6/2 mice and may contribute to subsequent pathology. Boutell, J. M., J. D. Wood, et al. (1998). "Huntingtin interacts with cystathionine beta-synthase." Hum Mol Genet 7(3): 371-8. We have screened a rat brain library to identify proteins which interact with the 5'-end of huntingtin (amino acids 1-171), including the polyglutamine tract, in the yeast two-hybrid system. We detected an interaction with cystathionine beta-synthase (CBS) [L-serine hydrolyase (adding homocysteine), EC 4.2.1.22], which was confirmed in vitro using His-tagged CBS expressed in Escherichia coli , which was able to specifically bind both rat and human full-length huntingtin. Neither normal nor expanded polyglutamine repeat alone interacted with CBS in the yeast two-hybrid system and nor did constructs containing SBMA or DRPLA with normal or expanded polyglutamine tracts. CBS therefore appears to bind specifically to huntingtin. CBS deficiency is associated with homocystinuria, which is known to affect various physiological systems, including the central nervous system. Homocysteine, one of the substrates of CBS, is known to accumulate in homocystinuria and is metabolized to homocysteate and homocysteine sulphinate, both known to be powerful excitotoxic amino acids. It has been suggested that Huntington's disease involves the action of excitotoxic amino acids and this interaction with CBS may suggest a mechanism for such excitotoxic damage. Bertaux, F., A. H. Sharp, et al. (1998). "HAP1-huntingtin interactions do not contribute to the molecular pathology in Huntington's disease transgenic mice." FEBS Lett 426(2): 229-32. HAP1 (huntingtin associated protein) has previously been found to interact with huntingtin (htt) in a glutamine length dependent manner and has been proposed to play a role in the cell specific neurodegeneration observed in Huntington's disease (HD). We have isolated mouse HAP1 (hap1) and have shown that expression is not enriched in areas specifically affected in HD. We have used the yeast two hybrid system to demonstrate that htt amino acids 171-230 are necessary for the hap1-htt binding and that hapl does not interact with the transgene exon 1 protein in a transgenic model of HD. Becher, M. W., J. A. Kotzuk, et al. (1998). "Intranuclear neuronal inclusions in Huntington's disease and dentatorubral and pallidoluysian atrophy: correlation between the density of inclusions and IT15 CAG triplet repeat length." Neurobiol Dis 4(6): 387-97. Huntington's disease (HD) is caused by CAG triplet repeat expansion in IT15 which leads to polyglutamine stretches in the HD protein product, huntingtin. The pathological hallmark of HD is the degeneration of subsets of neurons, primarily those in the striatum and neocortex. Specific morphological markers of affected cells have not been identified in patients with HD, although a unique itranuclear inclusion was recently reported in neurons of transgenic animals expressing a construct encoding the N-terminal part (including the glutamine repeat) of huntingtin (Davies et al., 1997). In order to understand the importance of this finding, we sought for comparable nuclear abnormalities in autopsy material from patients with HD. In all 20 HD cases examined, anti-ubiquitin and N-terminal huntingtin antibodies identified itranuclear inclusions in neurons and the frequency of these lesions correlated with the length of the CAG repeat in IT15. In addition, examination of material from the related HD-like triplet repeat disorder, dentatorubral and pallidoluysian atrophy, also revealed intranuclear neuronal inclusions. These findings suggest that intranuclear inclusions containing protein aggregates may be common feature of the pathogenesis of glutamine repeat neurodegenerative disorders. Beal, M. F. (1998). "Mitochondrial dysfunction in neurodegenerative diseases." Biochim Biophys Acta 1366(1-2): 211-23. A potential pivotal role for mitochondrial dysfunction in neurodegenerative diseases is gaining increasing acceptance. Mitochondrial dysfunction leads to a number of deleterious consequences including impaired calcium buffering, generation of free radicals, activation of the mitochondrial permeability transition and secondary excitotoxicity. Neurodegenerative diseases of widely disparate genetic etiologies may share mitochondrial dysfunction as a final common pathway. Recent studies using cybrid cell lines suggest that sporadic Alzheimer's disease is associated with a deficiency of cytochrome oxidase. Friedreich's ataxia is caused by an expanded GAA repeat resulting in dysfunction of frataxin, a nuclear encoded mitochondrial protein involved in mitochondrial iron transport. This results in increased mitochondrial iron and oxidative damage. Familial amyotrophic lateral sclerosis is associated with point mutations in superoxide dismutase, which may lead to increased generation of free radicals and thereby contribute to mitochondrial dysfunction. Huntington's disease (HD) is caused by an expanded CAG repeat in an unknown protein termed huntingtin. The means by which this leads to energy impairment is unclear, however studies in both HD patients and a transgenic mouse model show evidence of bioenergetic defects. Mitochondrial dysfunction leads to oxidative damage which is well documented in several neurodegenerative diseases. Therapeutic approaches include methods to buffer intracellular ATP and to scavenge free radicals. Bates, G. P., L. Mangiarini, et al. (1998). "Polyglutamine expansion and Huntington's disease." Biochem Soc Trans 26(3): 471-5. Bates, G. P., L. Mangiarini, et al. (1998). "Transgenic mice in the study of polyglutamine repeat expansion diseases." Brain Pathol 8(4): 699-714. An increasing number of neurodegenerative diseases, including Huntington's disease (HD), have been found to be caused by a CAG/polyglutamine expansion. We have generated a mouse model of HD by the introduction of exon 1 of the human HD gene carrying highly expanded CAG repeats into the mouse germ line. These mice develop a progressive neurological phenotype. Neuronal intranuclear inclusions (NII) that are immunoreactive for huntingtin and ubiquitin have been found in the brains of symptomatic mice. In vitro analysis indicates that the inclusions are formed through self aggregation via the polyglutamine repeat into amyloid-like fibrils composed of a cross beta-sheet structure that has been termed a polar zipper. Analysis of patient material and other transgenic lines has now shown NII to be a common feature of all of these diseases. In the transgenic models, inclusions are present prior to the onset of symptoms suggesting a causal relationship. In contrast, neurodegeneration occurs after the onset of the phenotype indicating that the symptoms are caused by a neuronal dysfunction rather than a primary cell death. Tukamoto, T., N. Nukina, et al. (1997). "Huntington's disease gene product, huntingtin, associates with microtubules in vitro." Brain Res Mol Brain Res 51(1-2): 8-14. The gene responsible for Huntington's disease produces a large protein with a molecular weight of approximately 350 k, designated huntingtin. Here, we report that the protein can associate in vitro with the microtubules. Through the process of assembly and disassembly of microtubules, both wild-type and mutant huntingtin associate with microtubules to almost the same degree. Huntingtin does not bind to the tubulin-affinity column directly. Huntingtin appears to interact with polymerized tubulin. These results suggest that huntingtin may have a role in intracellular organelle transport or axonal transport by its association with microtubules. Ross, C. A. (1997). "Intranuclear neuronal inclusions: a common pathogenic mechanism for glutamine-repeat neurodegenerative diseases?" Neuron 19(6): 1147-50. Nukina, N. (1997). "[Huntington disease]." Rinsho Shinkeigaku 37(12): 1139-40. The gene responsible for Huntington's disease produces a protein with a molecular weight of about 350k, designated huntingtin. We identified both wild-type and mutant huntingtin in the brain and lymphoblastoid cells. Although the function of huntingtin is still unknown, several associated proteins such as HAP1, Ubiquitin-conjugating enzyme, HIP1 and glyceraldehyde-3-phosphate-dehy dorogenase (GAPDH) were reported. We found the huntingtin can associate in vitro with microtubules. Through the process of assembly and disassembly of microtubules, both wild-type and mutant huntingtin associate with microtubules to almost the same degree. The results suggest that huntingtin may have a role in intracellular organelle transport or axonal transport by its association with microtubules. The functional disturbance by expanded polyglutamine stretch may modify the feature of the disease. Nasioulas, S., L. Sheffield, et al. (1997). "Modified Method for the Detection of the CAG Repeat Expansion in Huntington's Disease and Application to a Predictive Testing Protocol." Mol Diagn 2(1): 53-59. Background: The identification of the CAG trinucleotide repeat expansion as the cause of Huntington's disease (HD) has dramatically altered the ease and uptake of testing. The direct test for the mutation allows testing of many more consultands, particularly those individuals whose family structure is not suitable for linkage analysis. Therefore, protocols that can rapidly handle a number of samples and give accurate reliable results are essential. Methods and Results: The HD1/HD2 set of primers, which amplify the variable CAG and polymorphic CCG repeats, and the HD1/HD3 set of primers, which amplify only the variable CAG repeat, were used. Comparison of internally labeled with end-labeled polymerase chain reaction product was made. "Lysates" made from blood were investigated as suitable material for the HD polymerase chain reaction. Conclusions: The conditions used for detection of the CAG repeat in the huntingtin gene by end labeling of one of the primers that amplifies only the CAG repeat were improved, and an efficient protocol that reduces sample preparation and storage by using lysates from blood rather than extracted purified genomic DNA was developed. Engelender, S., A. H. Sharp, et al. (1997). "Huntingtin-associated protein 1 (HAP1) interacts with the p150Glued subunit of dynactin." Hum Mol Genet 6(13): 2205-12. Huntington's disease (HD) is an inherited neurodegenerative disease caused by expansion of a polyglutamine repeat in the HD protein huntingtin. Huntingtin's localization within the cell includes an association with cytoskeletal elements and vesicles. We previously identified a protein (HAP1) which binds to huntingtin in a glutamine repeat length-dependent manner. We now report that HAP1 interacts with cytoskeletal proteins, namely the p150 Glued subunit of dynactin and the pericentriolar protein PCM-1. Structural predictions indicate that both HAP1 and the interacting proteins have a high probability of forming coiled coils. We examined the interaction of HAP1 with p150 Glued . Binding of HAP1 to p150 Glued (amino acids 879-1150) was confirmed in vitro by binding of p150 Glued to a HAP1-GST fusion protein immobilized on glutathione-Sepharose beads. Also, HAP1 co-immunoprecipitated with p150 Glued from brain extracts, indicating that the interaction occurs in vivo . Like HAP1, p150 Glued is highly expressed in neurons in brain and both proteins are enriched in a nerve terminal vesicle-rich fraction. Double label immunofluorescence experiments in NGF-treated PC12 cells using confocal microscopy revealed that HAP1 and p150 Glued partially co-localize. These results suggest that HAP1 might function as an adaptor protein using coiled coils to mediate interactions among cytoskeletal, vesicular and motor proteins. Thus, HAP1 and huntingtin may play a role in vesicle trafficking within the cell and disruption of this function could contribute to the neuronal dysfunction and death seen in HD. |
