Another link between phospholipid transmembrane migration and ABC transporter gene family, inferred from a rare inherited disorder of phosphatidylserine externalization.

The mechanisms involved in the maintenance or loss of the asymmetric distribution of phospholipids in the cell plasma membrane remain mysterious. In the yeast Saccharomyces cerevisiae, the transmembrane migration of certain phospholipids is controlled by transcription regulators of various ATP-binding cassette (ABC) transporters. The P-glycoprotein membrane transporters encoded by the multidrug resistance (MDR) genes, members of the ABC protein family, act as lipid translocases in mammalian cells. We report here the lack of expression of MDR genes in lymphoblasts derived from the B cells of a patient with an inherited Scott syndrome, characterized by impaired transmembrane migration of procoagulant phosphatidylserine and hemorrhagic complications. From microsatellite analysis of 7q21.1 and functional assessment, the most likely explanation accounting for Scott phenotype is a mutation in an unlinked gene coding for a regulatory protein necessary for the expression of MDR genes. Because phosphatidylserine externalization is also one of the hallmarks of cells undergoing apoptosis, these observations are suggestive of a relationship between basic processes such as multidrug transport, apoptosis and procoagulant phospholipid exposure.

Mutational and protein analysis of patients and heterozygous women with X-linked adrenoleukodystrophy.

X-linked adrenoleukodystrophy (ALD), a neurodegenerative disorder associated with impaired beta-oxidation of very-long-chain fatty acids (VLCFA), is due to mutations in a gene encoding a peroxisomal ATP-binding cassette (ABC) transporter (ALD protein [ALDP]). We analyzed the open reading frame of the ALD gene in 44 French ALD kindred by using SSCP or denaturing gradient-gel electrophoresis and studied the effect of mutations on ALDP by immunocytofluorescence and western blotting of fibroblasts and/or white blood cells. Mutations were detected in 37 of 44 kindreds and were distributed over the whole protein-coding region, with the exception of the C terminus encoded in exon 10. Except for two mutations (delAG1801 and P560L) observed four times each, nearly every ALD family has a different mutation. Twenty-four of 37 mutations were missense mutations leading to amino acid changes located in or close to putative transmembrane segments (TMS 2, 3, 4, and 5), in the EAA-like motif and in the nucleotide fold of the ATP-binding domain of ALDP. Of 38 ALD patients tested, 27 (71%) lacked ALDP immunoreactivity in their fibroblasts and/or white blood cells. More than half of missense mutations studied (11 of 21) resulted in a complete lack of ALDP immunoreactivity, and six missense mutations resulted in decreased ALDP expression. The fibroblasts and/or white blood cells of 15 of 15 heterozygous carrier from ALD kindred with no ALDP showed a mixture of positive- and negative-ALDP immunoreactivity due to X-inactivation. Since 5%-15% of heterozygous women have normal VLCFA levels, the immunodetection of ALDP in white blood cells can be applicable in a majority of ALD kindred, to identify heterozygous women, particularly when the ALD gene mutation has not yet been identified.

A close relative of the adrenoleukodystrophy (ALD) gene codes for a peroxisomal protein with a specific expression pattern.

Adrenoleukodystrophy (ALD), a severe demyelinating disease, is caused by mutations in a gene coding for a peroxisomal membrane protein (ALDP), which belongs to the superfamily of ATP binding cassette (ABC) transporters and has the structure of a half transporter. ALDP showed 38% sequence identity with another peroxisomal membrane protein, PMP70, up to now its closest homologue. We describe here the cloning and characterization of a mouse ALD-related gene (ALDR), which codes for a protein with 66% identity with ALDP and shares the same half transporter structure. The ALDR protein was overexpressed in COS cells and was found to be associated with the peroxisomes. The ALD and ALDR genes show overlapping but clearly distinct expression patterns in mouse and may thus play similar but nonequivalent roles. The ALDR gene, which appears highly conserved in man, is a candidate for being a modifier gene that could account for some of the extreme phenotypic variability of ALD. The ALDR gene is also a candidate for being implicated in one of the complementation groups of Zellweger syndrome, a genetically heterogeneous disorder of peroxisome biogenesis, rare cases of which were found to be associated with mutations in the PMP70 (PXMP1) gene.

Funnel-well SDS-PAGE: a rapid technique for obtaining sufficient quantities of low-abundance proteins for internal sequence analysis.

We report a modified sodium dodecyl sulfate polyacrylamide gel electrophoresis method that permits up to a 60-fold concentration factor, without significant loss of protein. This method leads to very efficient concentration of low-abundance proteins from partially purified fractions or very dilute protein solution. Furthermore, it permits in situ enzymatic digestion and consequently increases the probability of obtaining a suitable internal sequence.

Purification by DNA affinity precipitation of the cellular factors HEB1-p67 and HEB1-p94 which bind specifically to the human T-cell leukemia virus type-I 21 bp enhancer.

Transcription driven by the proviral promoter of the Human T-cell Leukemia Virus type I (HTLV-I) is tightly regulated by the Tax1 transactivator. This viral protein potently induces the enhancer activity of a 21 bp motif repeated three times in the promoter. We have previously shown that this induction results from the binding of Tax1 to this enhancer sequence and that this association is mediated by the cellular factor HEB1. In this paper we report the purification of this factor by chromatography and DNA affinity precipitation. The latter method allowed a rapid and efficient purification which led to the identification of two polypeptides with molecular masses of 94- and 67-kDa, named HEB1-p94 and HEB1-p67, respectively. DMS methylation interference and UV crosslinking experiments indicated that both proteins formed different nucleo-protein complexes, but had the same DNA specificity. Study of the interaction of these two proteins with Tax1 showed that only HEB1-p67 can specifically interact with Tax1.

Binding of the HTLV-I Tax1 transactivator to the inducible 21 bp enhancer is mediated by the cellular factor HEB1.

Transcription driven by the HTLV-I promoter is strongly activated by the viral transactivator protein Tax1. This effect is mediated via a 21 bp sequence which is imperfectly repeated three times in the viral promoter. We showed previously that a single 21 bp copy exhibits a strong Tax1-inducible enhancer activity and is able to bind different cellular proteins, namely ATF, HEB1 and HEB2. We have further investigated the molecular mechanism involved in the Tax1 induction of the 21 bp motif's enhancer activity by analysing Tax1 interaction with this DNA sequence. For this purpose a HeLa cell line constitutively expressing a functional Tax1 protein was established and nuclear extracts of these cells were used to perform a DNA affinity precipitation assay. This experimental approach allowed us to show that Tax1 specifically binds to the 21 bp motif. The same sequence elements of the 21 bp motif are required both for Tax1 binding and for Tax1-induced enhancer activity. Chromatographic fractionation of the HeLa tax nuclear extract showed that the binding is indirect and is mediated by the cellular factor HEB 1.

Tax1 induction of the HTLV-I 21 bp enhancer requires cooperation between two cellular DNA-binding proteins.

Activation of the HTLV-I promoter by the viral Tax1 transactivator is mediated by a 21 bp sequence motif imperfectly repeated three times and composed of three exactly conserved domains (A, B and C from 5' to 3'). We show here that the Tax1 response requires the integrity of the B domain and of at least one of the flanking A or C domains. We have identified three cellular proteins which bind specifically to the 21 bp motif. One of these is the already well-characterized transcription factor ATF. The other two, namely HEB1 and HEB2, are specific for the 21 bp motif. HEB1 can bind to either domain A or C, but binding of ATF and HEB2 is determined by domain B. However, neither domain B alone, nor ATF/CREB binding sites respond significantly to Tax1. We therefore propose that Tax1 induction of the 21 bp enhancer element requires interaction with the two different cellular proteins identified in this study: HEB1 and HEB2, rather than binding of the ATF factor.