A treatable familial neuromyopathy with vitamin E deficiency, normal absorption, and evidence of increased consumption of vitamin E

Kohlschütter, Alfried; Hübner, Christoph; Jansen, W.; Lindner, S G

doi:10.1007/bf01804221

Cited by 45 publications

(10 citation statements)

References 8 publications

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“…Recent evidence convincingly shows that an impairment of the carnitine synthesis pathway at the step of lysosomal proteolysis of a mitochondrial trimethyllysine‐containing protein is the primary biochemical lesion in this disease [43]. Since NCL patients show both carnitine deficiency and abnormally low levels of 22:6 n ‐3, and higher levels of 20:4 n ‐6 [43–46], an impairment of the carnitine‐dependent pathway of 22:6 n ‐3 synthesis appears to be a major cause of its pathophysiology; this is consistent with data showing that supplementation with 22:6 n ‐3 ameliorates its pathology [47,48]. Other conditions associated with carnitine deficiency, such as treatment with certain pharmacologic agents, vegan diets, and excess dietary fat intake, also show decreased levels of 22:6 n ‐3 (but normal 22:5 n ‐3 levels) and higher levels of 20:4 n ‐6 and 22:5 n ‐6 (when measured) [7,13,49–54].…”

Section: Other Conditions Associated With Decreased Carnitine and 22:supporting

confidence: 76%

Secondary carnitine deficiency and impaired docosahexaenoic (22:6n‐3) acid synthesis: a common denominator in the pathophysiology of diseases of oxidative phosphorylation and β‐oxidation

Infante¹,

Huszagh²

2000

FEBS Letters

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Section: Other Conditions Associated With Decreased Carnitine and 22:supporting

confidence: 76%

Secondary carnitine deficiency and impaired docosahexaenoic (22:6n‐3) acid synthesis: a common denominator in the pathophysiology of diseases of oxidative phosphorylation and β‐oxidation

Infante¹,

Huszagh²

2000

FEBS Letters

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“…In separate experiments, LDL was isolated from a 27-year-old male patient with familial isolated vitamin E deficiency (FIVE) (32,33). The patient was homozygotic for a defect in the ␣-tocopherol transfer protein gene (33) and required regular vitamin E supplements (1800 mg daily).…”

Section: Methodsmentioning

confidence: 99%

α-Tocopherol as a Reductant for Cu(II) in Human Lipoproteins

Kontush

Meyer

Finckh

et al. 1996

Journal of Biological Chemistry

112

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Initiation of lipid peroxidation by Cu(II) requires reduction of Cu(II) to Cu(I) as a first step. It is unclear, however, whether this reaction occurs in the course of lipoprotein oxidation. It is also unknown which reductant, if any, can drive the reduction of Cu(II) in this case. We found that Cu(II) was rapidly reduced to Cu(I) by all major human lipoproteins (high, low, and very low density lipoproteins (HDL, LDL, and VLDL), and chylomicrons). Cu(II)-reducing activity was associated with a lipid moiety of the lipoproteins. The rates of Cu(II) reduction by different lipoproteins were similar when the lipoproteins were adjusted to similar alpha-tocopherol concentrations. Enriching lipoproteins with alpha-tocopherol considerably increased the rate of CU(II) reduction. CU(II) reduction by alpha-tocopherol-deficient LDL isolated from a patient with familial inherited vitamin E deficiency was found to occur much slower in comparison with LDL isolated from a donor with a normal plasma level of alpha-tocopherol. Initial rate of CU(II) reduction by alpha-tocopherol-deficient LDL was found to be zero. Enriching LDL with ubiquinol-10 to concentrations close to those of alpha-tocopherol did not influence the reaction rate. When LDL was treated with ebselen to eliminate preformed lipid hydroperoxides, the reaction rate was also not changed significantly. CU(II) reduction was accompanied by a consumption of lipoprotein alpha-tocopherol and accumulation of conjugated dienes in the samples. Increasing alpha-tocopherol content in lipoproteins slightly decreased the rate of conjugated diene accumulation in LDL and HDL and considerably increased it in VLDL. The results suggest that alpha-tocopherol plays a triggering role in the lipoprotein oxidation by CU(II), providing its initial step as follows: alpha TocH + CU(II) --> alpha Toc. + Cu(I) + H+. This reaction appears to diminish or totally eliminate the antioxidative activity of alpha-tocopherol in the course of lipoprotein oxidation.

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“…Families 3 and 4 (referred by M. Ben Hamida) and 9 and 17 (referred by A. Benomar) belong to large series of Tunisian and Moroccan families, respectively, and are not part of this study. Clinical descriptions were reported elsewhere for families 13 (Burck et al 1981;Kohlschü tter et al 1988), 18 (Laplante et al 1984), 14 (Sokol et al 1988), 16 (Trabert et al 1989), 1 and 2 (Ben Hamida et al 1993b), 8 (Amiel et al 1995, and 28 (Martinello et al, in press), and mutation was reported for 10 families (Ouahchi et al 1995). In addition to the 27 families analyzed here, molecular and clinical data from 6 families were compiled from the literature (Gotoda et al 1995;Hentati et al 1996;Yokota et al 1996Yokota et al , 1997.…”

Section: Subjectsmentioning

confidence: 99%

“…Our experience has shown that, in AVED patients, there is no limitation to or difficulty with the absorption of vitamin E by the intestinal tract (Kayden and Traber 1993). The administration of vitamin E supplements in divided doses daily has resulted in cessation of progression of the neurological symptoms and signs and in amelioration of established neurological abnormalities, in a number of patients (Kohlschü tter et al 1988;Yokota et al 1997). Our experience is that, for adults, the administration of 800 mg RRR a-tocopherol twice daily, with meals that contain fat, results in plasma a-tocopherol Table 5 Correlation between Genotype and Discrimination among Stereoisomers of a-Tocopherol a "Hentati" indicates a family from the study by Hentati et al (1996); "Gotoda" indicates a family from the study by Gotoda et al (1995); Numbering is according to Traber et al (1993).…”

Section: Figurementioning

confidence: 99%

“…In normal individuals, the latter function accounts for the efficient recycling of plasma vitamin E ( pools/d) that otherwise is 1.4 ‫ע‬ 0.6 rapidly eliminated (Traber et al 1994). FIVE has been described in rare cases, studied during the period 1981-89 (Burck et al 1981;Laplante et al 1984;Harding et al 1985;Krendel et al 1987;Stumpf et al 1987;Yokota et al 1987;Kohlschü tter et al 1988;Sokol et al 1988;Trabert et al 1989). The description, reported in 1993, of eight affected individuals from two large Tunisian pedigrees (Ben Hamida et al 1993b) initiated the identification of many other patients from North Africa, where this condition appears to be much more frequent.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Ataxia with Isolated Vitamin E Deficiency: Heterogeneity of Mutations and Phenotypic Variability in a Large Number of Families

Cavalier

Ouahchi

Kayden

et al. 1998

The American Journal of Human Genetics

287

184

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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.

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A treatable familial neuromyopathy with vitamin E deficiency, normal absorption, and evidence of increased consumption of vitamin E

Cited by 45 publications

References 8 publications

Secondary carnitine deficiency and impaired docosahexaenoic (22:6n‐3) acid synthesis: a common denominator in the pathophysiology of diseases of oxidative phosphorylation and β‐oxidation

Secondary carnitine deficiency and impaired docosahexaenoic (22:6n‐3) acid synthesis: a common denominator in the pathophysiology of diseases of oxidative phosphorylation and β‐oxidation

α-Tocopherol as a Reductant for Cu(II) in Human Lipoproteins

Ataxia with Isolated Vitamin E Deficiency: Heterogeneity of Mutations and Phenotypic Variability in a Large Number of Families

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