Ataxia with isolated vitamin E deficiency: heterogeneity of mutations and phenotypic variability in a large number of families.

Ataxia with vitamin E deficiency (AVED), or familial isolated vitamin E deficiency, is a rare autosomal recessive neurodegenerative disease characterized clinically by symptoms with often striking resemblance to those of Friedreich ataxia. We recently have demonstrated that AVED is caused by mutations in the gene for alpha-tocopherol transfer protein (alpha-TTP). We now have identified a total of 13 mutations in 27 families. Four mutations were found in >=2 independent families: 744delA, which is the major mutation in North Africa, and 513insTT, 486delT, and R134X, in families of European origin. Compilation of the clinical records of 43 patients with documented mutation in the alpha-TTP gene revealed differences from Friedreich ataxia: cardiomyopathy was found in only 19% of cases, whereas head titubation was found in 28% of cases and dystonia in an additional 13%. This study represents the largest group of patients and mutations reported for this often misdiagnosed disease and points to the need for an early differential diagnosis with Friedreich ataxia, in order to initiate therapeutic and prophylactic vitamin E supplementation before irreversible damage develops.     

A physical and transcript map based upon refinement of the critical interval for PPH1, a gene for familial primary pulmonary hypertension. The International PPH Consortium

Primary pulmonary hypertension (PPH), an often fatal disorder, is characterized by sustained elevation of pulmonary artery pressure of unknown cause. In its familial form (FPPH), the disorder segregates as an autosomal dominant and displays markedly reduced penetrance. A gene for FPPH was previously localized to a 25-cM interval on the long arm of chromosome 2 (2q31-q33). We now report a complete yeast artificial chromosome (YAC) and bacterial artificial chromosome (BAC)/P1 artificial chromosome contig (PAC), assembled by STS content mapping, across a newly identified minimum nonrecombinant interval containing the gene designated PPH1. The physical map has served to establish polymorphic marker order unequivocally, enabling the establishment of detailed haplotypes for the region. Together with the identification of novel recombination events in affected individuals from six newly ascertained kindreds, these data have allowed the significant reduction of the minimum PPH1 critical interval to a 4.8-cM region. The region, flanked by the polymorphic markers D2S115 (centromeric) and D2S1384 (telomeric), corresponds to a minimum physical distance of 5.8 Mb at 2q33. Numerous expressed sequence tags and known genes were placed on the YAC/BAC contig spanning the PPH1 gene critical region.     

Biochemical consequences of heritable mutations in the alpha-tocopherol transfer protein

Tocopherol transfer protein (TTP) regulates vitamin E status by facilitating the secretion of tocopherol from liver to circulating lipoproteins. Heritable mutations in the ttpA gene, encoding for TTP, result in ataxia with vitamin E deficiency (AVED) syndrome, typified by low vitamin E levels and a plethora of neurological disorders. The molecular mechanisms by which TTP facilitates tocopherol secretion are presently unknown. We recently showed that vitamin E is taken up by hepatocytes through an endocytic process and that, shortly following uptake, the vitamin is found primarily in lysosomes. We showed further that TTP is localized to late endocytic vesicles and that it facilitates the intracellular trafficking of tocopherol from lysosomes to the plasma membrane. To gain insight into the molecular mechanisms that underlie TTP actions, we studied the physiological impact of three naturally occurring heritable mutations in the ttpA gene (the R59W, R221W, and A120T substitutions). We found that these mutations impair the ability of TTP to facilitate the secretion of vitamin E from cells. Furthermore, the degree of impairment corresponded to the severity of the AVED pathology associated with each mutation. In cells that express mutated TTP proteins, vitamin E did not traffic to the plasma membrane and remained "trapped" in lysosomes. In addition, we observed that substitution mutations that cause the AVED syndrome impart a marked instability on the TTP protein. These observations suggest that the physiological role of TTP is anchored in its ability to direct vitamin E trafficking from the endocytic compartment to transport vesicles that deliver the vitamin to the site of secretion at the plasma membrane.     

Refinement of the dominant optic atrophy locus (OPA1) to a 1.4-cM interval on chromosome 3q28-3q29, within a 3-Mb YAC contig

Dominant optic atrophy, type Kjer, is an autosomal dominant eye disease that is characterized by progressive optic atrophy with onset in early childhood, decrease of visual acuity, colour vision defects and centrocecal scotoma. By examination of 5 Danish families and the use of polymorphic markers, we have refined the localization of the OPA1 locus and assigned it to a 1.4-cM interval on chromosome 3q28-3q29, between markers D3S3669 and D3S3562. This localizes the gene on a 3-Mb YAC contig covering the disease locus. We have also located a possible candidate gene HRY to this contig. Received: 1 April 1996 / Revised: 8 August 1996     

Molecular determinants of heritable vitamin E deficiency

Tocopherol transfer protein (TTP) is a key regulator of vitamin E homeostasis. TTP is presumed to function by transporting the hydrophobic vitamin between cellular compartments, thus facilitating its secretion to the extracellular space. Indeed, recombinant TTP demonstrates marked ability to facilitate tocopherol transfer between lipid bilayers. We report the biochemical characterization of six missense mutations TTP(1) that are found in human AVED patients. We expressed the H101Q, A120T, R192H, R59W, E141K, and R221W TTP mutants in Escherichia coli, and purified the proteins to homogeneity. We then characterized TTP and its mutant counterparts with respect to their affinity for RRR-alpha-tocopherol and to their ability to catalyze tocopherol transfer between membranes. We observe the R59W, E141K, and R221W mutations, associated with the severe, early-onset version of AVED, are impaired in tocopherol binding and transfer activity. Surprisingly, despite the profound clinical effect of the R59W, E141K, and R221W mutations in vivo, their impact on TTP activity in vitro is quite benign (2-3-fold reduction in transfer kinetics). Furthermore, mutations associated with milder forms of the AVED disease, while causing pronounced perturbations in tocopherol homeostasis in vivo, are remarkably similar to the wild-type protein in the tocopherol transfer assays in vitro. Our data indicate that tocopherol transfer activity in vitro does not properly recapitulate the physiological functions of TTP. These findings suggest the possibility that the AVED syndrome may not arise from an inability of TTP to bind or to transfer alpha tocopherol, but rather from defects in other activities of the protein.     

A YAC contig encompassing the recessive Stargardt disease gene (STGD) on chromosome 1p.

Stargardt disease (STGD) and fundus flavimaculatus are infrequent autosomal recessive conditions characterized by a juvenile macular dystrophy and variable degrees of peripheral retinal changes. Linkage analysis performed in 47 STGD/fundus flavimaculatus families demonstrated significant linkage to 13 polymorphic DNA markers on chromosome 1p. The maximum combined two-point lod score was 32.7 (maximum recombination fraction [phi max] = .006) with the polymorphic marker D1S188. Our data demonstrate that STGD and fundus flavimaculatus are the same disorder clinically and genetically and provide further evidence for genetic homogeneity of this phenotype. Analysis of recombination events on disease chromosomes placed the STGD gene within a 4-cM interval between markers D1S435 and D1S236. A physical map was constructed of a YAC contig flanking STGD, from markers D1S500 to D1S495, and includes the critical interval delineated by historical recombinants. This contig spans approximately 31 cM, with one gap (3-5 cM) that is outside the 4-cM critical region. Localization of STGD to a single YAC contig will facilitate its positional cloning.     

Vitamin E: an overview of major research directions

During the last 90 years since the discovery of vitamin E, research has focused on different properties of this molecule, the focus often depending on the specific techniques and scientific knowledge present at each time. Originally discovered as a dietary factor essential for reproduction in rats, vitamin E has revealed in the meantime many more important molecular properties, such as the scavenging of reactive oxygen and nitrogen species with consequent prevention of oxidative damage associated with many diseases, or the modulation of signal transduction and gene expression in antioxidant and non-antioxidant manners. Research over the last 30 years has also resolved the biosynthesis and occurrence of vitamin E in plants, the proteins involved in the cellular uptake, tissue distribution and metabolism, and defined a congenital recessive neurological disease, ataxia with vitamin E deficiency (AVED), characterized by impaired enrichment of -tocopherol in plasma as a result of mutations in the liver -tocopherol transfer gene. This review is giving a brief introduction about vitamin E by following the major research directions since its discovery with a historical perspective.     

X chromosome-inactivation patterns confirm the late timing of monoamniotic-MZ twinning.

Autosomal dominant brachydactyly type B (BDB) is characterized by nail aplasia with rudimentary or absent distal and middle phalanges. We describe two unrelated families with BDB. One family is English; the other family is Canadian but of English ancestry. We assigned the BDB locus in the Canadian family to an 18-cM interval on 9q, using linkage analysis (LOD score 3.5 at recombination fraction [theta] 0, for marker D9S938). Markers across this interval also cosegregated with the BDB phenotype in the English family (LOD score 2.1 at straight theta=0, for marker D9S277). Within this defined interval is a smaller (7.5-cM) region that contains 10 contiguous markers whose disease-associated haplotype is shared by the two families. This latter result suggests a common founder among families of English descent that are affected with BDB.     

Refinement of a Translocation Breakpoint Associated with Blepharophimosis–Ptosis–Epicanthus Inversus Syndrome to a 280-kb Interval at Chromosome 3q23

Blepharophimosis syndrome (BPES) is an autosomal dominant disorder of craniofacial development, the features of which include blepharophimosis, ptosis, and epicanthus inversus. Although it has been suggested that BPES is genetically heterogeneous, a major locus for this condition resides at chromosome 3q23. We have previously mapped a translocation breakpoint associated with BPES to the D3S1316–D3S1615 interval. The markers in this region have subsequently been shown to lie in a different order, with the BPES locus mapping to the 1-cM D3S1576 and D3S1316 interval. In the current investigation, a physical map, consisting of 60 yeast artificial chromosome (YAC) clones and 1 bacterial artificial chromosome, that spans this region has been constructed. Ten expressed sequence tags and the cellular retinol-binding protein I locus have been mapped to the contig. YAC end isolation has led to the creation of novel STSs that have been used to reduce the size of the BPES critical region to a 280-kb interval, which has been cloned in two nonchimeric YACs.     

The molecular basis of vitamin E retention: structure of human alpha-tocopherol transfer protein

Alpha-tocopherol transfer protein (alpha-TTP) is a liver protein responsible for the selective retention of alpha-tocopherol from dietary vitamin E, which is a mixture of alpha, beta, gamma, and delta-tocopherols and the corresponding tocotrienols. The alpha-TTP-mediated transfer of alpha-tocopherol into nascent VLDL is the major determinant of plasma alpha-tocopherol levels in humans. Mutations in the alpha-TTP gene have been detected in patients suffering from low plasma alpha-tocopherol and ataxia with isolated vitamin E deficiency (AVED). The crystal structure of alpha-TTP reveals two conformations. In its closed tocopherol-charged form, a mobile helical surface segment seals the hydrophobic binding pocket. In the presence of detergents, an open conformation is observed, which probably represents the membrane-bound form. The selectivity of alpha-TTP for RRR-alpha-tocopherol is explained from the van der Waals contacts occurring in the lipid-binding pocket. Mapping the known mutations leading to AVED onto the crystal structure shows that no mutations occur directly in the binding pocket.     

Refinement of the locus for autosomal dominant cerebellar ataxia type II to chromosome 3p21.1–14.1

We have previously mapped the gene for autosomal dominant cerebellar ataxia type II (ADCAII) to chromosome 3p12-p21.1 in a region of 33 cM by using four families of different geographic origin. In this study, we analysed the families with nine additional simple tandem repeat markers located in the ADCAII candidate region. An extensive clinical evaluation was also performed in the Belgian family CA-1 on two probably affected and seven at-risk individuals by means of ophthalmological examination and magnetic resonance imaging. Based on informative recombinants, we were able to reduce the ADCAII candidate region to the 12-cM region between D3S1300 and D3S1285. Furthermore, haplotype analysis among the families suggested that the most likely location of the ADCAII gene is within the 6.2-cM interval between D3S3698 and D3S1285. Because of the documented anticipation in ADCAII families, we also analysed family CA-1 with six polymorphic triplet repeat markers located on chromosome 3. None of these markers showed expanded alleles. Received: 16 August 1996 / Revised: 7 October 1996     

Mapping of quantitative trait locus related to submergence tolerance in rice with aid of chromosome walking.

The major QTL for submergence tolerance was locate in the 5.9 cM interval between flanking RFLP markers. To narrow down this region, a physical map was constructed using YAC and BAC clones. A 400-kb YAC was identified in this region and later its end fragments were used to screen a rice BAC library. Through chromosome walking, 24 positive BAC clones formed two contigs around linked-RFLP markers, R1164 and RZ698. Using one YAC end, six BAC ends and three RFLP markers, a fine-scale map was constructed of the 6.8-cM interval of S10709-RZ698 on rice chromosome 9. The submergence tolerance and related trait were located in a small, well-defined region around BAC-end marker 180D1R and RFLP marker R1164. The physical-to-map distance ratio in this region is as small as 172.5 kb/cM, showing that this region is a hot spot for recombination in the rice genome.     

Selective intestinal malabsorption of vitamin B12 displays recessive mendelian inheritance: assignment of a locus to chromosome 10 by linkage.

Juvenile megaloblastic anemia caused by selective intestinal malabsorption of vitamin B12 has been considered a distinct condition displaying autosomal recessive inheritance. It appears to have a worldwide distribution, and comparatively high incidences were reported 30 years ago in Finland and Norway. More recently, the Mendelian inheritance of the condition has been questioned because almost no new cases have occurred in these populations. Here we report linkage studies assigning a recessive-gene locus for the disease to chromosome 10 in previously diagnosed multiplex families from Finland and Norway, proving the Mendelian mode of inheritance. The locus is tentatively assigned to the 6-cM interval between markers D10S548 and D10S466, with a multipoint maximum lod score (Zmax) of 5.36 near marker D10S1477. By haplotype analysis, the healthy sibs in these families did not appear to constitute any examples of nonpenetrance. We hypothesize that the paucity of new cases in these populations is due either to a dietary effect on the gene penetrance that has changed with time, or to a drop in the birth rate in subpopulations showing enrichment of the mutation, or to both of these causes.     

Congenital fibrosis of the extraocular muscles (autosomal dominant congenital external ophthalmoplegia): genetic homogeneity, linkage refinement, and physical mapping on chromosome 12.

Congenital fibrosis of the extraocular muscles (CFEOM) is an autosomal dominant syndrome of congenital external ophthalmoplegia and bilateral ptosis. We previously reported linkage of this disorder in two unrelated families to an 8-cM region near the centromere of human chromosome 12. We now present refinement of linkage in the original two families, linkage analysis of five additional families, and a physical map of the critical region for the CFEOM gene. In each of the seven families the disease gene is linked to the pericentromeric region of chromosome 12. D12S345, D12S59, D12S331, and D12S1048 do not recombine with the disease gene and have combined lod scores of 35.7, 35.6, 16.0, and 31.4, respectively. AFM136xf6 and AFMb320wd9 flank the CFEOM locus, defining a critical region of 3 cM spanning the centromere of chromosome 12. These data support the concept that this may be a genetically homogeneous disorder. We also describe the generation of a YAC contig encompassing the critical region of the CFEOM locus. This interval has been assigned cytogenetically to 12p11.2-q12 and spans the centromere of chromosome 12. These results provide the basis for further molecular analyses of the structure and organization of the CFEOM locus and will help in the identification of candidate genes.     

Preferential Localization of the Limb-Girdle Muscular Dystrophy Type 2A Gene in the Proximal Part of a 1-cM 15q15.1-q15.3 Interval

A gene for a recessive form of limb-girdle muscular dystrophy (LGMD2A) has been localized to chromosome 15. A physical map of the 7-cM candidate 15q15.1-q21.1 region has been constructed by means of a 10–12-Mb continuum of overlapping YAC clones. New microsatellite markers developed from these YACs were genotyped on large, consanguineous LGMD2A pedigrees from different origins. The identification of recombination events in these families allowed the restriction of the LGMD2A region to an estimated 1-cM interval, equivalent to ~3–4 Mb. Linkage disequilibrium data on genetic isolates from the island of Réunion and from the Amish community suggest a preferential location of the LGMD2A gene in the proximal part of this region. Analysis of the interrelated pedigrees from Réunion revealed the existence of at least six different carrier haplotypes. This allelic heterogeneity is incompatible with the presumed existence of a founder effect and suggests that multiple LGMD2A mutations may segregate in this population.     

Genetic and physical mapping of the Chediak-Higashi syndrome on chromosome 1q42-43.

The Chediak-Higashi syndrome (CHS) is a severe autosomal recessive condition, features of which are partial oculocutaneous albinism, increased susceptibility to infections, deficient natural killer cell activity, and the presence of large intracytoplasmic granulations in various cell types. Similar genetic disorders have been described in other species, including the beige mouse. On the basis of the hypothesis that the murine chromosome 13 region containing the beige locus was homologous to human chromosome 1, we have mapped the CHS locus to a 5-cM interval in chromosome segment 1q42.1-q42.2. The highest LOD score was obtained with the marker D1S235 (Zmax = 5.38; theta = 0). Haplo-type analysis enabled us to establish D1S2680 and D1S163, respectively, as the telomeric and the centromeric flanking markers. Multipoint linkage analysis confirms the localization of the CHS locus in this interval. Three YAC clones were found to cover the entire region in a conting established by YAC end-sequence characterization and sequence-tagged site mapping. The YAC contig contains all genetic markers that are nonrecombinant for the disease in the nine CHS families studied. This mapping confirms the previous hypothesis that the same gene defect causes CHS in human and beige pheno-type in mice and provides a genetic framework for the identification of candidate genes.     

Allelic and locus heterogeneity in autosomal recessive gelatinous drop-like corneal dystrophy

Gelatinous drop-like corneal dystrophy (GDLD) is a rare autosomal recessive disease characterized by the deposition of amyloid beneath the corneal epithelium and by severely impaired visual acuity leading to blindness. Although gelatinous corneal dystrophy has previously been mapped to chromosome 1p and seems to be associated with mutations in the M1S1 gene, molecular genetic studies have been limited to Japanese patients. To investigate the cause of GDLD in patients with diverse ethnic backgrounds, we performed linkage analyses in eight unrelated GDLD families from India, USA, Europe, and Tunisia. In seven of these families, the disease locus mapped to a 16-cM interval on the short arm of chromosome 1 between markers D1S519 and D1S2835, a region including the M1S1 gene. In addition, a 1.2-kb fragment containing the entire coding region of M1S1 gene was sequenced in affected individuals. Seven novel mutations (M1R, 8-bp ins., Q118 E, V194 E, C119 S, 870delC, and 1117delA) were identified in six families and two unrelated individuals. No sequence abnormalities were detected in a single family in which the GDLD locus was also excluded from the M1S1 region by linkage analysis. These findings demonstrate allelic and locus heterogeneity for GDLD.