Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.14.16.2 (tyrosine hydroxylase)
 14,760 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

From its characteristic clinical features, decrease of tyrosine hydroxylase (TH) in the terminal of the nigrostriatal (NS) dopamine (DA) neuron is considered the main lesion of HPD and the decrease of neopterin as well as biopterin in the cerebrospinal fluid suggested GTP cyclohydrolase I (GCH-I) as the responsible enzyme. By detecting the gene locus of GCH-I, Ichinose and his colleagues showed the abnormalities of GCH-I gene located on 14q 22.1 q22.2 as the cause of HPD. Since the first report of Ichinose et al, 11 mutations and frame shifts of the gene have been detected, in which the locus of abnormality differed among families but is identical in a family, but more than several families have been left with undetected abnormalities including those having linkage to 14q. However, the DNA of these families as well as those with detected gene abnormalities failed to synthesize GCH-I if inoculated with E. coli and the levels of GCH-I in mononuclear blood cells were below 20% of normal values in HPD patients while they were 37 and 38% in two asymptomatic carriers. Ratio of mutant mRNA of GCH-I gene was 28% in a patient and 8.3% in an asymptomatic case. These lines of evidence on GCH-I show HPD is a dominant inherited disorder with abnormalities of GCH-I gene. GCH-I is the limiting enzyme for synthesizing tetrahydrobiopterin (BH4), coenzyme transmitters for the synthesizing hydroxylases of aminergic neurotransmitters, but the affinity is the least for TH. This might cause a rather selective involvement of TH preserving serotonin synthesis un- or less affected. Fluoro-DOPA and [11C] racropride PET studies were normal in HPD. Studies of an autopsied case with dopa responsive dystonia, which was confirmed to have GCH-I gene abnormalities, neuropathologically revealed no abnormalities except for a decrease in melanin pigmentation in the substantia nigra and histochemically a decrease in TH enzyme activities and its protein only in the striatum. There was mild decrease of DA content, the interregional caudate/putamen and subregional rostrocaudal patterns which were similar to Parkinson disease, but subdivisionally different with predominant reduction in the ventral subdivision of the caudate nucleus. In the ventral part of the basal ganglia the striatal direct projection exists predominantly. Cases with recessive abnormalities of pteridin metabolism other than HPD, 6-pyruvoyl-tetra-hydropterin synthase (PSPS) deficiency and dihydropteridine reductase deficiency also show dystonia with diurnal fluctuation responding to levodopa, though not as marked as HPD. MPTP monkey studies revealed no involvement of striatal indirect pathway for peak dose dystonia. So it is suggested that in HPD, decrease of TH at the terminal of the NS-DA neuron due to partial reduction of GCH-I develops postural dystonia through the striatal direct projection in childhood with diurnal fluctuation depending on age and circadian variation of TH activities at the terminals.
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PMID:[Segawa disease (hereditary progressive dystonia with marked diurnal fluctuation-HPD) and abnormalities in pteridin metabolism]. 912 93

Segawa disease (hereditary progressive dystonia with marked diurnal fluctuation) is an autosomal dominant, childhood onset, postural dystonia and the first hereditary basal ganglia disorder whose causative enzyme and gene defect were clarified. The initial symptom is unilateral pes equinovarus with marked diurnal fluctuation. Progression becomes slower after mid-teens and stationary after thirties. Postural tremor may occur after 10 years of age, especially after thirties. Parkinsonian resting tremor action and torsion dystonia. and disturbed locomotion do not occur. L-Dopa shows marked and sustained effect without side effects. F-Dopa PET and [11C] raclopride PET of over 20-year-old cases are normal. Deficiency of GTP cyclohydrolase I (GCH-I) was suggested from low CSF biopterin and neopterin. Mutation of GCH-I gene and decreased GCH-I were clarified as etiology. Twenty-five mutations discordant among families have been found. Autopsy of a gene proven case revealed decreased striatal tyrosine hydroxylase (TH) and dopamine (DA) in ventral striatum where direct pathway is predominant. Decreased GCH-I causes decreased tetrahydrobiopterin (BH4), TH and DA in nigrostriatal (NS) terminal. The lowest affinity of BH4 to TH causes selective involvement of DA. Postural dystonia is caused by decreased TH and DA affecting D1-direct pathway. Thalamic ventrolateral and pedunculo-pontine nuclei are spared. Diurnal fluctuation of symptoms is due to diurnal fluctuation of TH and DA at NS-DA terminal. Decreased DA to below 20% of normal, shown by polysomnographical studies, and its physiological age related decremental changes in NS-DA terminal underlies characteristic clinical course. High D2 receptor before early thirties masks D1 related hypertonus and manifest progression before 20 years of age. Other pteridine abnormalities also cause dopa responsive postural dystonia with diurnal fluctuation. A case of juvenile parkinsonism without dystonia showed decreased TH in dorsolateral putamen where indirect pathway is predominant. These suggest that decreased TH due to decreased BH4 involves D1-direct pathway causing dystonia, and decreased TH itself involves D2-indirect pathway causing parkinsonism.
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PMID:[Segawa disease]. 957 70

Gene transfer techniques have been explored as therapeutic modalities and neurobiologic tools to understand the role of various genes in animal models of Parkinson's disease. The gene for tyrosine hydroxylase, the rate-limiting step of dopamine synthesis, has been transferred into animal models by viral vectors or by implantable cells that have been modified by retrovirus vectors. The role of additional genes such as GTP cyclohydrolase 1 and aromatic L-amino acid decarboxylase in optimal delivery of dopamine in animal models is reviewed. Gene therapy also allows goals beyond replacement of dopamine. Neurotrophic factors such as brain-derived neurotrophic factor and glial cell line-derived neurotrophic factor can be introduced to promote sprouting of neurites and protect the dopaminergic neurons from degeneration. Genes involved in apoptosis, free radical scavenger pathway, or other cell death mechanism could also be used to prevent the degeneration of the neurons. Current technology of gene therapy is limited in its long-term expression and ability to regulate the gene expression. However, recent developments provide better understanding of these limitations and suggest potential solutions to these technical hurdles.
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PMID:Potential of gene therapy for Parkinson's disease: neurobiologic issues and new developments in gene transfer methodologies. 961 21

The clinical distinction between dopa-responsive dystonia (DRD) and juvenile Parkinson's disease JPD) can pose a diagnostic challenge. Both conditions are dopa responsive. However, long-term L-dopa benefit is very different between the two. The difference in the prognosis is due to presence or absence of nigral cell loss. In JPD, there is degenerative nigral cell loss, whereas there are enzymatic defects in dopamine synthesis without cell loss in DRD. Mutations have been found in the GTP cyclohydrolase I (GCH-I) and tyrosine hydroxylase genes in DRD. As the discovered mutations are multiple and more are expected to be found, it is difficult to confirm or exclude DRD by mutation studies. Measurement of cerebrospinal fluid (CSF) neopterin will detect DRD from mutations in the GCH-I gene but not from mutations in tyrosine hydroxylase. The dopamine transporter (DAT) is a protein in the dopaminergic nerve terminals. (1R)-2beta-Carbomethoxy-3beta-(4-[123I]iodophenyl)tropane ([123I]beta-CIT) is a ligand for the DAT, and it was shown to be a useful nuclear imaging marker for neurons that degenerate in Parkinson's disease (PD). As DRD was shown to have a normal DAT without nigral cell loss in a postmortem study, we predicted that the DAT measured in vivo by nuclear imaging will be normal in DRD and will differentiate DRD from JPD. Therefore, we performed [123I]beta-CIT single-photon emission computed tomography ([123I]beta-CIT SPECT) in clinically diagnosed DRD, PD, and JPD, and examined whether DAT imaging can differentiate DRD from PD and JPD. We then examined whether DAT imaging can provide a screening tool for molecular genetic studies, by studying mutations in the candidate gene GCH-I and measuring CSF neopterin. Five females (4 from two families, and 1 sporadic) were diagnosed as DRD based on early-onset foot dystonia and progressive parkinsonism beginning at ages 7 to 12. All patients were functioning normally on L-dopa 100 to 250 mg/day for up to 8 years. SPECT imaging was obtained after intravenous injection of [123I]beta-CIT; 15 healthy volunteers served as normal control, and 6 PD and 1 JPD as disease controls. [123I]beta-CIT striatal binding was normal in DRD, whereas it was markedly decreased in PD and JPD. Gene analysis showed a novel nonsense mutation in the GCH-I gene in one family. No mutation was found in the other family or in the sporadic case. CSF neopterin was markedly decreased in the 4 tested patients. [123I]beta-CIT SPECT is a sensitive method for probing the integrity of nigrostriatal dopaminergic nerve terminals. A normal striatal DAT in a parkinsonian patient is evidence for a nondegenerative cause of parkinsonism and differentiates DRD from JPD. Finding a new mutation in one family and failure to demonstrate mutations in the putative gene in other cases supports the usefulness of DAT imaging in diagnosing DRD.
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PMID:Dopamine transporter density measured by [123I]beta-CIT single-photon emission computed tomography is normal in dopa-responsive dystonia. 962 49

Dopamine-deficient mice (DA-/- ), lacking tyrosine hydroxylase (TH) in dopaminergic neurons, become hypoactive and aphagic and die by 4 weeks of age. They are rescued by daily treatment with L-3,4-dihydroxyphenylalanine (L-DOPA); each dose restores dopamine (DA) and feeding for less than 24 hr. Recombinant adeno-associated viruses expressing human TH or GTP cyclohydrolase 1 (GTPCH1) were injected into the striatum of DA-/- mice. Bilateral coinjection of both viruses restored feeding behavior for several months. However, locomotor activity and coordination were partially improved. A virus expressing only TH was less effective, and one expressing GTPCH1 alone was ineffective. TH immunoreactivity and DA were detected in the ventral striatum and adjacent posterior regions of rescued mice, suggesting that these regions mediate a critical DA-dependent aspect of feeding behavior.
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PMID:Viral gene delivery selectively restores feeding and prevents lethality of dopamine-deficient mice. 1002 99

Guanosine triphosphate (GTP) cyclohydrolase I (GCH) is the first and rate-limiting enzyme for biosynthesis of tetrahydrobiopterin, the cofactor of tyrosine hydroxylase (TH). Our previous study reported the presence of GCH in several neuronal groups in animal brains using a newly raised anti-GCH antibody. The present study aims at elucidating whether GCH and TH coexist in the same neurons of the human brain with the aid of immunohistochemical dual labeling. GCH-immunoreactivity was observed in the cell bodies and fibers of monoaminergic neurons of the human brain. Neurons which contain both enzymes are seen in the human substantia nigra, ventral tegmental area, locus coeruleus, dorsal raphe, and zona incerta. In these regions, almost all the cells also show immunoreactivity for aromatic L-amino acid decarboxylase (AADC), the second step enzyme for catecholamine synthesis, indicating that these neurons are catecholaminergic. However, some neurons in the dorsal and dorsomedial hypothalamic nuclei are stained only for GCH or TH. They appear to constitute an independent cell group in the human brain. The present observation suggests that L-dopa is not produced in the cells immunoreactive for TH but not for GCH, and that TH in these cells which lack GCH may have an unidentified role other than dopa synthesis.
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PMID:Specific localization of the guanosine triphosphate (GTP) cyclohydrolase I-immunoreactivity in the human brain. 1090 21

To date, at least 12 types of primary dystonia can be distinguished on a genetic basis. A 3-bp deletion in the DYT1 gene causes early onset, generalized torsion dystonia (TD), and mutations in the GTP cyclohydrolase I and the tyrosine hydroxylase genes result in dopa-responsive dystonia (DYT5). A missense change in the D2 dopamine receptor in one large family (DYT11) has recently been implicated in myoclonus-dystonia. Furthermore, seven other loci for dystonia genes have been mapped to chromosomal regions, including a locus for a mixed dystonia phenotype (DYT6), one form of focal dystonia (DYT7), three types of paroxysmal dystonia (DYT8-10), X-linked dystonia-parkinsonism (DYT3), and rapid-onset dystonia-parkinsonism (DYT12). No positive linkage results have yet been obtained for autosomal recessive TD (DYT2) and several other families of different types of dominantly inherited TD (DYT4). In addition, hereditary secondary dystonia may occur as part of familial diseases of the basal ganglia, metabolic and storage disorders, and various X-linked and other familial neurodegenerative syndromes affecting the basal ganglia. It may be anticipated that the traditional clinical and etiological classifications of dystonia will increasingly be replaced by a genetic one and that the identification of more dystonia genes may lead to a better understanding of these largely nondegenerative disorders.
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PMID:[Genetics of dystonia]. 1091 37

Hereditary progressive dystonia with marked diurnal fluctuation or the strictly defined dopa-responsive dystonia (HPD/DRD) is an autosomally dominantly inherited dystonia caused by abnormalities of the gene of the GTP cyclohydrolase I (GCH 1) located on the 14q22. 1-q22.2. The heterozygotic gene abnormality induces partial decrement of tetrahydrobiopterin (BH4) and affects synthesis of tyrosine hydroxylase (TH) rather selectively. The reduction of TH exists at the terminals of the nigrostriatal (NS) dopamine (DA) neuron, predominantly in the ventral area of the striatum and disfacilitates the D1 receptor-striatal direct pathway. This consequently disinhibit the inhibitory efferent pathways and develops postural dystonia via the particular descending pathways to the reticulospinal tract and postural tremor via the ascending pathways to the ventralis lateralis (VL) nucleus of the thalamus. This also inhibits the efferents to the superior colliculus, and affects voluntary saccade but spares that to the pedunculo-pontine nucleus (PPN) preserving locomotive movement clinically. The DA-D2 receptors, the striatal indirect pathways or the efferent connecting to these pathways are not involved in the pathophysiology of HPD/DRD. So parkinsonian plastic rigidity, parkinsonian resting tremor, cogwheel rigidity or levodopa induced dyskinesia are not observed. In some patients, particularly in compound hetereozygotes, there are symptoms suggesting the involvement of serotonergic neurons or those thought to be caused by exaggeration of DA-D2 receptors. Neuropathologically there is no degenerative changes. Clinical laboratory examinations suggest that levels of TH and DA activities are around 20% of the normal values throughout the course of illness. Therefore, the age-dependent clinical course, marked progression in the first one and one half decades, its subsiding in the third decade and almost stationary course from the fourth decade are just the reflection of age-related decremental variation of the TH activities at the terminal of the normal NS-DA neuron. The diurnal fluctuation is also the reflection of circadian oscillation of the TH activities at the terminal. Functional maturation of the striatal indirect pathways in the first one and one half decades and developmental decremental variation of the DA-D2 receptor in the first three decades also reflect in the age-dependent variation of symptoms by modulating the background tone of muscle. The later functional development of the ascending efferents of the basal ganglia to the thalamus, may cause the postural tremor which appears in the second decade and becomes predominant in the fourth decade. Early decrease of TH due to deficiency of BH4 in HPD/DRD also affects the DA-D4 receptor of the tuberoinfundibular DA neuron and cause stagnation of increase of body length in childhood. With normal preservation of the fundamental function of the NS-DA neuron, levodopa, by replacing the DA content at the terminal, alleviates the motor symptoms completely and the effects sustain without any side effects. Levodopa also improves the short body length, if it is administrated before puberty. Up to now 60 mutations have been detected in the GCH 1 gene. The locus of mutation differs among families except for two pare of families with different ethnic background which showed identical mutations. Experimentally, one abnormal heterozygotic gene decreased the production of the enzyme to less than 50%, e.g. some below 20% and others around 30-40%, which clinically as symptomatic patients and asymptomatic carriers, respectively. Other experiments show dominant negative effects which differ among families or the loci of mutation. These might be the background for developing the intra-familial variation, that is, in some there is anticipation, and in the other the symptoms and clinical course are identical or vary in a family without any relation to the generation. (ABSTRACT TRUNCATED)
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PMID:Hereditary progressive dystonia with marked diurnal fluctuation. 1098 64

Mutations of the guanosine triphosphate (GTP)-cyclohydrolase I (GCH-I) gene, which catalyzes the first step in the tetrahydrobiopterin (the natural cofactor for tyrosine hydroxylase) biosynthesis, are demonstrated to cause HPD, i.e. strictly defined dopa-responsive dystonia. We analyzed the GCH-I gene of patients who fulfilled clinical criteria for typical hereditary progressive dystonia (HPD) to finalize the diagnosis. Two novel point mutations in two independent families and one novel de novo point mutation in one sporadic patient were identified. In a Japanese family, a T-to-C transition was found at exon 2, which resulted in a substitution of Cys 141 to Arg. In another Japanese family, a C-to-T mutation in exon 4 caused a nonsense codon Gln180Stop. In a clinically sporadic Japanese patient, T-to-G transition in exon 1 brought Met 102 Arg missense mutation, which was not observed in its biological parents. These three mutations were not observed in previously reported 57 pedigrees/patients and no polymorphisms in the coding region of the GCH-I gene were identified. None of the mutations of GCH-I gene in HPD reported to date or in this study have been detected more than once in any ethnicity suggesting a relatively high spontaneous mutation rate in this gene.
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PMID:Gene mutation in hereditary progressive dystonia with marked diurnal fluctuation (HPD), strictly defined dopa-responsive dystonia. 1098 68

The dystonias are a common clinically and genetically heterogeneous group of movement disorders. More than ten loci for inherited forms of dystonia have been mapped, but only three mutated genes have been identified so far. These are DYT1, encoding torsin A and mutant in the early-onset generalized form, GCH1 (formerly known as DYT5), encoding GTP-cyclohydrolase I and mutant in dominant dopa-responsive dystonia, and TH, encoding tyrosine hydroxylase and mutant in the recessive form of the disease. Myoclonus-dystonia syndrome (MDS; DYT11) is an autosomal dominant disorder characterized by bilateral, alcohol-sensitive myoclonic jerks involving mainly the arms and axial muscles. Dystonia, usually torticollis and/or writer's cramp, occurs in most but not all affected patients and may occasionally be the only symptom of the disease. In addition, patients often show prominent psychiatric abnormalities, including panic attacks and obsessive-compulsive behavior. In most MDS families, the disease is linked to a locus on chromosome 7q21 (refs. 11-13). Using a positional cloning approach, we have identified five different heterozygous loss-of-function mutations in the gene for epsilon-sarcoglycan (SGCE), which we mapped to a refined critical region of about 3.2 Mb. SGCE is expressed in all brain regions examined. Pedigree analysis shows a marked difference in penetrance depending on the parental origin of the disease allele. This is indicative of a maternal imprinting mechanism, which has been demonstrated in the mouse epsilon-sarcoglycan gene.
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PMID:Mutations in the gene encoding epsilon-sarcoglycan cause myoclonus-dystonia syndrome. 1152 94


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