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The CAG triplet repeat region of the Huntington's disease gene was amplified in 923 single sperm from three affected and two normal individuals. Average-size alleles (15-18 repeats) showed only three contraction mutations among 475 sperm (0.6%). A 30 repeat normal allele showed an 11% mutation frequency. The mutation frequency of a 36 repeat intermediate allele was 53% with 8% of all gametes having expansions which brought the allele size into the HD disease range (> or = 38 repeats). Disease alleles (38-51 repeats) showed a very high mutation frequency (92-99%). As repeat number increased there was a marked elevation in the frequency of expansions, in the mean number of repeats added per expansion and the size of the largest observed expansion. Contraction frequencies also appeared to increase with allele size but decreased as repeat number exceeded 36. Our sperm typing data are of a discrete nature rather than consisting of smears of PCR product from pooled sperm. This allowed the observed mutation frequency spectra to be compared to the distribution calculated using discrete stochastic models based on current molecular ideas of the expansion process. An excellent fit was found when the model specified that a random number of repeats are added during the progression of the polymerase through the repeated region.
Hum Mol Genet 1995 Sep
PMID:Single sperm analysis of the trinucleotide repeats in the Huntington's disease gene: quantification of the mutation frequency spectrum. 854 34

We have directly compared intergenerational stability of intermediate alleles (IAs) derived from new mutation families (IANM) for Huntington disease (HD) with IAs in the general population (IAGP) which occur in approximately 1 in 50 persons. Analysis of meiotic events in blood and sperm reveals that IANM are significantly more unstable than IAGP despite similar size. However, for both IANM and IAGP CAG changes were small and risks for inheriting an expansion into the HD affected range were low. Sequence analysis reveals that the CAG tract is generally interrupted by a penultimate CAA in IAGP, IANM and alleles in the affected range. In one new mutation family, however, two A-->G mutations result in a pure CAG tract which is associated with very marked instability. These mutations alter the predicted DNA hairpin structure with a predicted increase in the likelihood of large expansion, supporting the model that hairpin loop formation plays an important role in trinucleotide instability.
Hum Mol Genet 1995 Oct
PMID:Increased instability of intermediate alleles in families with sporadic Huntington disease compared to similar sized intermediate alleles in the general population. 859 15

Mapping genes for nonsyndromic hereditary hearing impairment may lead to identification of genes that are essential for the development and preservation of hearing. We studied a family with autosomal dominant, progressive, low frequency sensorineural hearing loss. Linkage analysis employing microsatellite polymorphic markers revealed a fully linked marker (D4S126) at 4p16.3, a gene-rich region containing IT15, the gene for Huntington's disease (HD). For D4S126, the logarithm-of-odds (lod) score was 3.64 at theta = 0, and the overall maximum lod score was 5.05 at theta = 0.05 for D4S412. Analysis of recombinant individuals maps the disease gene to a 1.7 million base pair (Mb) region between D4S412 and D4S432. Genes for two types of mutant mice with abnormal cochleovestibular function, tilted (tlt) and Bronx waltzer (bv), have been mapped to the syntenic region of human 4p16.3 on mouse chromosome 5. Further studies with the goals of cloning a gene for autosomal nonsyndromic hearing impairment and identifying the murine homologue may explain the role of this gene in the development and function of the cochlea.
Hum Mol Genet 1995 Oct
PMID:A gene for autosomal dominant nonsyndromic hereditary hearing impairment maps to 4p16.3. 859 23

A novel human G protein-coupled receptor kinase was recently identified by positional cloning in the search for the Huntington's disease locus (Ambrose, C., James, M., Barnes, G., Lin, C., Bates, G., Altherr, M., Duyao, M., Groot, N., Church, D., Wasmuth, J. J., Lehrach, H., Housman, D., Buckler, A., Gusella, J. F., and MacDonald, M. E. (1993) Hum. Mol. Genet. 1, 697-703). Comparison of the deduced amino acid sequence of GRK4 with those of the closely related GRK5 and GRK6 suggested the apparent loss of 32 codons in the amino-terminal domain and 46 codons in the carboxyl-terminal domain of GRK4. These two regions undergo alternative splicing in the GRK4 mRNA, resulting from the presence or absence of exons filling one or both of these apparent gaps. Each inserted sequence maintains the open reading frame, and the deduced amino acid sequences are similar to corresponding regions of GRK5 and GRK6. Thus, the GRK4 mRNA and the GRK4 protein can exist as four distinct variant forms. The human GRK4 gene is composed of 16 exons extending over 75 kilobase pairs of DNA. The two alternatively spliced exons correspond to exons II and XV. The genomic organization of the GRK4 gene is completely distinct from that of the human GRK2 gene, highlighting the evolutionary distance since the divergence of these two genes. Human GRK4 mRNA is expressed highly only in testis, and both alternative exons are abundant in testis mRNA. The four GRK4 proteins have been expressed, and all incorporate [3H]palmitate. GRK4 is capable of augmenting the desensitization of the rat luteinizing hormone/chorionic gonadotropin receptor upon coexpression in HEK293 cells and of phosphorylating the agonist-occupied, purified beta2-adrenergic receptor, indicating that GRK4 is a functional protein kinase.
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PMID:Characterization of the G protein-coupled receptor kinase GRK4. Identification of four splice variants. 862 39

Huntington disease (HD) is an autosomal-dominant disorder of mid-life onset characterized by chorea, dementia, and oculomotor disturbances. Anticipation is commonly seen in HD families, particularly when the disease is inherited through the father. The disorder is associated with an expanded (CAG)n repeat in the IT15 gene that is unstable and tends to increase in size during meiotic transmissions, particularly of paternal origin. We have detected an unusual form of HD on the island of Crete which has distinctly different characteristics. Data from eight families encompassing 48 HD patients, showed a median age at onset 15-20 years later than that for HD occurring worldwide. There is no juvenile cases and no anticipation. DNA analysis in 12 HD patients showed expansion of the (CAG)n repeat the size of which was identical among members of each family or varied by only one unit. The elongated DNA segment was passed stably or contracted during both paternal and maternal transmissions thus indicating that unique molecular mechanisms may be operational in this form of HD.
Hum Mol Genet 1995 Dec
PMID:Stability of the Huntington disease (CAG)n repeat in a late onset form occuring on the Island of Crete. 863 93

A robust feature of mammalian aging associated with diminished motor control is the loss of dopamine D2 receptors from the neostriatum. Decline in this neurotransmitter receptor is also observed in neurodegenerative disorders, such as Huntington's disease and late-stage Parkinson's disease. We have constructed a replication-deficient adenoviral vector to transfer rat dopamine D2 receptor cDNA to brain as a possible therapeutic strategy. Using tissue culture cells infected with this vector, we detected dopamine D2 receptor mRNA by Northern analysis and functional receptor protein in membrane preparations as specific binding of the dopamine D2 receptor ligand, [3H]spiperone. In vivo demonstration involved autoradiographic analysis of [3H]spiperone binding in rat striatum following injection of the adenoviral vector. Dopamine D2 receptor expression was amplified markedly above normal concentrations in the injection site, whereas no increased expression was observed in sites receiving control treatments. These results demonstrate the potential of gene therapy using adenoviral vectors to transfer neurotransmitter receptor proteins to the brain to reverse deficiencies in specific neurodegenerative disorders.
Brain Res Mol Brain Res 1995 Dec 28
PMID:Adenovirus-mediated gene transfer of dopamine D2 receptor cDNA into rat striatum. 875 Aug 35

Positional cloning has shown that the Huntington disease (HD) mutation is an expanded trinucleotide repeat in the IT15 gene. Although this mutation clearly produces the HD phenotype, the function of the Huntington disease protein remains undefined. One recent immunocytochemical study suggested that the IT15 protein preferentially localizes to the nucleus of affected neuronal cells. If this result is accurate, it could link the biochemical function of this protein to nuclear activities such as gene regulation. To examine the nuclear transport of the Huntington disease protein, we searched for basic peptide motifs that could produce nuclear localization. One peptide (RRKGKEK) was identified that is highly homologous to a consensus nuclear localization signal. When fused to the cytoplasmic reporter protein, beta-galactosidase, nuclear localization was observed in stably transformed human cell lines. In a complementary study, an anti-peptide polyclonal antibody, raised against a sequence adjacent to the putative nuclear localization sequence, detected the IT15 protein in the nucleus of human cells. These results extend and confirm the previous localization studies and identify an IT15 peptide motif that can function for nuclear localization.
Brain Res Mol Brain Res 1995 Oct
PMID:The identification of a functional nuclear localization signal in the Huntington disease protein. 877 58

A neurogenetic disorder is defined as a clinical disease caused by a defect in one or more genes which affect the differentiation and function of the neuroectoderm and its derivatives. Genetic findings in various neurogenetic disorders are discussed. Huntington disease, spinobulbar muscular atrophy, and the autosomal dominant cerebellar ataxias are examples of autosomal dominant disorders caused by the expansion of trinucleotides (CAG) within disease genes. The CAG expansions appear to result in a gain of gene function. Prenatal, presymptomatic, and differential diagnostic tests are based on the detection of the repeat expansions. Point mutations within disease genes result in many additional neurogenetic disorders. An autosomal dominant form of amyotrophic lateral sclerosis and various types of craniosynostotic syndromes are described. The mutations in the disease genes also appear to result in a gain of gene function. Molecular diagnosis in these disorders is based on the direct examination of the mutated gene by methods such as single-strand conformation polymorphism analysis, denaturing gradient gel electrophoresis, and direct DNA sequencing. In many neurogenetic disorders the disease gene has not yet been identified. Here molecular diagnosis relies on indirect approaches based on methods such as the analysis of linkage and of allelic association. Hereditary forms of dystonia are presented as examples. Common sporadic neurological disorders such as Alzheimer and Parkinson diseases frequently have multifactorial causes. Investigations into the molecular basis and the development of diagnostic tests in these two important diseases are discussed. At present no curative therapies exist in neurogenetic disorders. Gene therapeutic approaches, however, provide promise for a cure in at least some of these diseases. Basic principles of gene therapy are explained and attempts at gene therapy in Alzheimer and Parkinson diseases are described. Finally, some of the many obstacles are summarized that must be overcome before gene therapy becomes feasible in most monogenic neurological diseases.
J Mol Med (Berl) 1996 Feb
PMID:Neurogenetic diseases: molecular diagnosis and therapeutic approaches. 882 Apr 2

The mutation underlying Huntington disease (HD) is CAG expansion in the first exon of the HD gene. In order to investigate the role of CAG expansion in the pathogenesis of HD, we have produced transgenic mice containing the full length human HD cDNA with 44 CAG repeats. By 1 year, these mice have no behavioral abnormalities and morphometric analysis at 6 (one animal) and 9 (two animals) months age revealed no changes. Despite high levels of mRNA expression, there was no evidence of the HD gene product in any of these transgenic mice. In vitro transfection studies indicated that the inclusion of 120 bp of the 5' UTR in the cDNA construct and the presence of a frameshift mutation at nucleotide 2349 prevented expression of the HD cDNA. These findings suggest that the pathogenesis of HD is not mediated through DNA-protein interaction and that presence of the RNA transcript with an expanded CAG repeat is insufficient to cause the disease. Rather, translation of the CAG is crucial for the pathogenesis of HD. In contrast to that seen in humans, the CAG repeat in these mice was remarkably stable in 97 meioses. This suggests that genomic sequences may play a critical role in influencing repeat instability.
Hum Mol Genet 1996 Feb
PMID:Absence of disease phenotype and intergenerational stability of the CAG repeat in transgenic mice expressing the human Huntington disease transcript. 882 73

Huntington's disease is a progressive neurodegenerative disorder, which is caused by expansion of a polymorphic (CAG)n repeat in the coding region of the Huntington's disease gene. The function of huntingtin has not been elucidated so far. Accordingly, detailed subcellular localization studies remain useful. In an immunohistochemical study, we have reported huntingtin to be present in the cytoplasm of cells in the majority of the tissues studied. In addition, we detected a signal in the nucleus of cells in some tissues, including neuronal cells. We have further extended these studies in various mammalian cell lines, using a panel of (affinity-purified) polyclonal huntingtin antibodies in immunofluorescence, confocal laser scanning microscopy and biochemical subcellular fractionation studies. In mouse embryonic fibroblasts, human skin fibroblasts and in mouse neuroblastoma cells huntingtin was present in the cytoplasm. All five antibodies, directed against different parts of huntingtin, also showed a signal in the nucleus. This signal could be competed by the original antigen. The localization of huntingtin in both cytoplasm and nucleus, was confirmed by biochemical subcellular fractionation studies. However, in most other studies, a nuclear location for huntingtin has not been found. Our results suggest, however, that besides its function(s) in the cytoplasm, a nuclear function of huntingtin at some stages of differentiation or in some phases of the cell cycle may not be excluded.
Hum Mol Genet 1996 Aug
PMID:Subcellular localization of the Huntington's disease gene product in cell lines by immunofluorescence and biochemical subcellular fractionation. 884 26

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