A novel autosomal dominant limb-girdle muscular dystrophy (LGMD 1F) maps to 7q32.1-32.2.

In 2001, the authors described the clinical features of a genetically distinct autosomal dominant limb-girdle muscular dystrophy (LGMD; LGMD 1F). Using a genome-wide screen with more than 400 microsatellite markers, the authors identified a novel LGMD disease locus at chromosome 7q32.1-32.2. Within this chromosomal region, filamin C, a gene encoding actin binding protein highly expressed in muscle, was an obvious candidate gene; however, the authors did not detect any defects in filamin C or its protein product.

Response to levodopa treatment in dopa-responsive dystonia.

BACKGROUND: Dopa-responsive dystonia (DRD) is similar to Parkinson disease in that both disorders have impaired dopamine synthesis and respond to levodopa treatment. Dopa-responsive dystonia differs in that dopamine storage is intact in contrast to Parkinson disease in which it is markedly reduced. OBJECTIVE: To examine the short- and long-duration responses to levodopa dosing in subjects with DRD. METHODS: The response to brief infusions of levodopa was examined in 4 subjects with DRD and the effects of withdrawal of levodopa for 3 to 7 days studied in the 3 subjects receiving long-term levodopa therapy. Motor function was measured with tapping speed, Unified Parkinson's Disease Rating Scale motor score, and global dystonia score. RESULTS: The short-duration response to levodopa dosing seems to develop more slowly and persists longer in subjects with DRD than in subjects with Parkinson disease. Withdrawal of levodopa leads to a gradual decline in tapping speed and reemergence of dystonia over several days, similar to the rate of decay of motor function in Parkinson disease. The short- and long-duration responses were not clearly differentiated in DRD. CONCLUSIONS: This pilot study suggests that retained dopamine storage in DRD may prolong the short-duration response and blur the distinction of the short- and long-duration responses. The decline in motor function in DRD on withdrawal of long-term levodopa therapy resembles that in Parkinson disease, suggesting that a long-duration response, if it exists in DRD, is unrelated to dopamine storage.

Mitochondrial neurogastrointestinal encephalomyopathy: an autosomal recessive disorder due to thymidine phosphorylase mutations.

Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) is an autosomal recessive disorder defined clinically by severe gastrointestinal dysmotility; cachexia; ptosis, ophthalmoparesis, or both; peripheral neuropathy; leukoencephalopathy; and mitochondrial abnormalities. The disease is caused by mutations in the thymidine phosphorylase (TP) gene. TP protein catalyzes phosphorolysis of thymidine to thymine and deoxyribose 1-phosphate. We identified 21 probands (35 patients) who fulfilled our clinical criteria for MNGIE. MNGIE has clinically homogeneous features but varies in age at onset and rate of progression. Gastrointestinal dysmotility is the most prominent manifestation, with recurrent diarrhea, borborygmi, and intestinal pseudo-obstruction. Patients usually die in early adulthood (mean, 37.6 years; range, 26-58 years). Cerebral leukodystrophy is characteristic. Mitochondrial DNA (mtDNA) has depletion, multiple deletions, or both. We have identified 16 TP mutations. Homozygous or compound heterozygous mutations were present in all patients tested. Leukocyte TP activity was reduced drastically in all patients tested, 0.009 +/- 0.021 micromol/hr/mg (mean +/- SD; n = 16), compared with controls, 0.67 +/- 0.21 micromol/hr/mg (n = 19). MNGIE is a recognizable clinical syndrome caused by mutations in thymidine phosphorylase. Severe reduction of TP activity in leukocytes is diagnostic. Altered mitochondrial nucleoside and nucleotide pools may impair mtDNA replication, repair, or both.

Gaucher disease: the origins of the Ashkenazi Jewish N370S and 84GG acid beta-glucosidase mutations.

Type 1 Gaucher disease (GD), a non-neuronopathic lysosomal storage disorder, results from the deficient activity of acid beta-glucosidase (GBA). Type 1 disease is panethnic but is more prevalent in individuals of Ashkenazi Jewish (AJ) descent. Of the causative GBA mutations, N370S is particularly frequent in the AJ population, (q approximately .03), whereas the 84GG insertion (q approximately .003) occurs exclusively in the Ashkenazim. To investigate the genetic history of these mutations in the AJ population, short tandem repeat (STR) markers were used to map a 9.3-cM region containing the GBA locus and to genotype 261 AJ N370S chromosomes, 60 European non-Jewish N370S chromosomes, and 62 AJ 84GG chromosomes. A highly conserved haplotype at four markers flanking GBA (PKLR, D1S1595, D1S2721, and D1S2777) was observed on both the AJ chromosomes and the non-Jewish N370S chromosomes, suggesting the occurrence of a founder common to both populations. Of note, the presence of different divergent haplotypes suggested the occurrence of de novo, recurrent N370S mutations. In contrast, a different conserved haplotype at these markers was identified on the 84GG chromosomes, which was unique to the AJ population. On the basis of the linkage disequilibrium (LD) delta values, the non-Jewish European N370S chromosomes had greater haplotype diversity and less LD at the markers flanking the conserved haplotype than did the AJ N370S chromosomes. This finding is consistent with the presence of the N370S mutation in the non-Jewish European population prior to the founding of the AJ population. Coalescence analyses for the N370S and 84GG mutations estimated similar coalescence times, of 48 and 55.5 generations ago, respectively. The results of these studies are consistent with a significant bottleneck occurring in the AJ population during the first millennium, when the population became established in Europe.

Localization of a gene for myoclonus-dystonia to chromosome 7q21-q31.

Essential myoclonus-dystonia is a neurological condition characterized by myoclonic and dystonic muscle contractions and the absence of other neurological signs or laboratory abnormalities; it is often responsive to alcohol. The disorder may be familial with apparent autosomal dominant inheritance. We report a large kindred with essential familial myoclonus-dystonia and map a locus for the disorder to a 28-cM region of chromosome 7q21-q31.

Striatal biopterin and tyrosine hydroxylase protein reduction in dopa-responsive dystonia.

OBJECTIVE: To determine the mechanism leading to striatal dopamine (DA) loss in dopa-responsive dystonia (DRD). BACKGROUND: Although mutations in the gene GCH1, coding for the tetrahydrobiopterin (BH4) biosynthetic enzyme guanosine triphosphate-cyclohydrolase I, have been identified in some patients with DRD, the actual status of brain BH4 (the cofactor for tyrosine hydroxylase [TH]) is unknown. METHODS: The authors sequenced GCH1 and measured levels of total biopterin (BP) and total neopterin (NP), TH, and dopa decarboxylase (DDC) proteins, and the DA and vesicular monoamine transporters (DAT, VMAT2) in autopsied brain of two patients with typical DRD. RESULTS: Patient 1 had two GCH1 mutations but Patient 2 had no mutation in the coding region of this gene. Striatal BP levels were markedly reduced (<20% of control subjects) in both patients and were also low in two conditions characterized by degeneration of nigrostriatal DA neurons (PD and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine treated primate), whereas brain NP concentrations were selectively decreased (<45%) in the DRD patients. In the putamen, both DRD patients had severely reduced (<3%) TH protein levels but had normal concentrations of DDC protein, DAT, and VMAT2. CONCLUSIONS: The data suggest that 1) brain BH4 is decreased substantially in dopa-responsive dystonia, 2) dopa-responsive dystonia can be distinguished from degenerative nigrostriatal dopamine deficiency disorders by the presence of reduced brain neopterin, and 3) the striatal dopamine reduction in dopa-responsive dystonia is caused by decreased TH activity due to low cofactor concentration and to actual loss of TH protein. This reduction of TH protein, which might be explained by reduced enzyme stability/expression consequent to congenital BH4 deficiency, can be expected to limit the efficacy of acute BH4 administration on dopamine biosynthesis in dopa-responsive dystonia.

Primary torsion dystonia: the search for genes is not over.

A GAG deletion in the DYT1 gene accounts for most early, limb onset primary torsion dystonia (PTD). The genetic bases for the more common adult onset and focal PTD are less well delineated. Genetic loci for an "intermediate dystonia" phenotype and for torticollis, named DYT6 and DYT7 respectively, have recently been mapped in single families. To evaluate the contribution of these genetic loci to other families with familial "non-DYT1" dystonia five large families with dystonia were studied using genetic markers spanning the DYT6 and DYT7 regions. There was no evidence of linkage to either locus in any family. These findings illustrate the genetic heterogeneity of the dystonias and indicate the existence of one or more as yet unmapped genes for dystonia. Large collaborative efforts will be required to identify these, and additional genes, causing PTD.

Mitochondrial neurogastrointestinal encephalomyopathy syndrome maps to chromosome 22q13.32-qter.

Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) syndrome is a rare, multisystem disorder characterized clinically by ptosis, progressive external ophthalmoplegia, gastrointestinal dysmotility, leukoencephalopathy, thin body habitus, and myopathy. Laboratory studies reveal defects of oxidative-phosphorylation and multiple mtDNA deletions frequently in skeletal muscle. We studied four ethnically distinct families affected with this apparently autosomal recessive disorder. Probands from each family were shown, by Southern blot, to have multiple mtDNA deletions in skeletal muscle. We mapped the MNGIE locus to 22q13.32-qter, distal to D22S1161, with a maximum two-point LOD score of 6.80 at locus D22S526. Cosegregation of MNGIE with a single chromosomal region in families with diverse ethnic backgrounds suggests that we have mapped an important locus for this disorder. We found no evidence to implicate three candidate genes in this region, by using direct sequence analysis for DNA helicase II and by assaying enzyme activities for arylsulfatase A and carnitine palmitoyltransferase.

Autosomal recessive juvenile parkinsonism maps to 6q25.2-q27 in four ethnic groups: detailed genetic mapping of the linked region.

Parkinson disease (PD) is a common neurodegenerative condition associated with degeneration of dopaminergic neurons in the zona compacta of the substantia nigra. There is increasing evidence that genetic factors play a role in the etiology of PD, although genetic heterogeneity is likely. An autosomal dominant syndrome with many similarities to sporadic PD has been mapped to 4q21-22 in a large Italian pedigree and has been found to be due to mutation of the alpha-synuclein gene. However, this gene appears to account for only a minority of PD, and a susceptibility locus for autosomal dominant parkinsonism has recently been mapped, on 2p13. Autosomal recessive juvenile parkinsonism (JP), which shows marked clinical similarity to PD, maps to 6q25.2-q27. We found linkage to this region in a group of 15 families from four distinct ethnic backgrounds. A full genomic screen excluded other candidate regions. We have constructed a detailed genetic map of the linked region and have mapped the position of the manganese superoxide dismutase gene (SOD2). Recombination events restricted the JP locus to a 6.9-cM region and excluded SOD2. The apparent homozygosity for null alleles at D6S955 in one family suggested a deletion and finer localization of the JP locus.

Reduced lymphoblast neopterin detects GTP cyclohydrolase dysfunction in dopa-responsive dystonia.

OBJECTIVE: To demonstrate that measurement of endogenous neopterin levels in unstimulated lymphoblasts identifies inherited GTP cyclohydrolase 1 (GCH1) dysfunction and can be a diagnostic test for dopa-responsive dystonia (DRD). BACKGROUND: DRD results from decreased dopamine biosynthesis due to dysfunctional GCH1. GCH1 is the rate-limiting enzyme in the biosynthesis of tetrahydrobiopterin (BH4), an essential cofactor for catecholamine synthesis. Mutations in the GCH1 coding region are identified in 60 to 70% of DRD cases; in others, the cause of GCH1 dysfunction is unknown. METHODS: Using HPLC, we measured endogenous neopterin, the main byproduct of the GCH1 reaction, in lymphoblasts under basal conditions and following GCH1 stimulation conditions. RESULTS: In a four-generation family, all identified carriers of dysfunctional GCH1 had basal neopterin levels that were below those of controls. The spouse of one carrier had a mutation in exon 6 of GCH1. Although this man's GCH1 function appeared unaffected by this, his daughter, who was a compound heterozygote with her mother's dysfunctional GCH1 and this mutation, had a phenotype that was more severe than that of typical DRD. Cytokine or phytohemagglutinin (PHA) did not induce GCH1 activity in any carrier of dysfunctional GCH1; controls who did not respond to PHA had increased neopterin levels following cytokine induction. CONCLUSIONS: Endogenous neopterin measurement in unstimulated lymphoblasts is an accurate tool to identify dysfunctional GCH1 and a potential specific diagnostic marker for dysfunctional GCH1 in DRD and other neurologic disorders. Not all mutations in GCH1 affect GCH1 enzyme activity. PHA induction alone, previously used by others, may result in incorrect identification of GCH1 dysfunction in DRD.

Striatal D2 receptors in symptomatic and asymptomatic carriers of dopa-responsive dystonia measured with [11C]-raclopride and positron-emission tomography.

We tested the hypothesis that asymptomatic carriers of dopa-responsive dystonia (DRD) have increased dopamine D2 receptors in the striatum that protect them from the clinical manifestations of dopaminergic deficiency. We examined striatal D2-receptor binding in (1) symptomatic subjects (treated and untreated) and (2) asymptomatic gene carriers. Using [11C]-raclopride PET, we found elevated striatal D2-receptor binding in both groups. In one of our drug-naive symptomatic subjects, 7 months of treatment with levodopa/carbidopa did not affect the receptor binding as measured on a second scan. We conclude that increased D2-receptor binding in DRD may be a homeostatic response to the dopaminergic deficit in subjects carrying the DRD gene, but is not the sole factor determining the clinical state of these individuals.

Idiopathic torsion dystonia linked to chromosome 8 in two Mennonite families.

The DYT1 locus on chromosome 9q34 is responsible for most childhood limb-onset idiopathic torsion dystonia (ITD). Linkage to DYT1 has been excluded in families with adult-onset, and predominantly cranial-cervical, ITD. We mapped a locus (DYT6) associated with prominent cranial-cervical ITD in two large Mennonite families to chromosome 8. An identical haplotype spanning 40-cM segregates with ITD in these families, suggesting a shared mutation from the recent past.

Mapping of familial primary pulmonary hypertension locus (PPH1) to chromosome 2q31-q32.

BACKGROUND: The pathogenesis of primary pulmonary hypertension (PPH) is unknown, although in some instances families with multiple affected members suggest a genetic etiology. METHODS AND RESULTS: We used microsatellite markers and linkage analysis in a large family with PPH to determine the chromosomal location of their disease gene. We tested a second, ethnically distinct, family for cosegregation of disease with markers from the linked region. We mapped the disease locus PPH1; GDB/HUGO designation (GDB:1381541; July 1996), approved when this work was accepted for publication in abstract form (Circulation. 1996;94[suppl I]:1-49.), in these families to a 27-cM region on chromosome 2q31-q32, with a maximum lod score of 3.87 associated with markers D2S350 and D2S364. CONCLUSIONS: Cosegregation of this region with disease in different ethnic groups suggests that we mapped an important locus in familial PPH. Careful study of additional families and sporadic cases will be required to confirm this localization of PPH1 and characterize its overall role.