ABCC6 prevents ectopic mineralization seen in pseudoxanthoma elasticum by inducing cellular nucleotide release.

Pseudoxanthoma elasticum (PXE) is an autosomal recessive disease characterized by progressive ectopic mineralization of the skin, eyes, and arteries, for which no effective treatment exists. PXE is caused by inactivating mutations in the gene encoding ATP-binding cassette sub-family C member 6 (ABCC6), an ATP-dependent efflux transporter present mainly in the liver. Abcc6(-/-) mice have been instrumental in demonstrating that PXE is a metabolic disease caused by the absence of an unknown factor in the circulation, the presence of which depends on ABCC6 in the liver. Why absence of this factor results in PXE has remained a mystery. Here we report that medium from HEK293 cells overexpressing either human or rat ABCC6 potently inhibits mineralization in vitro, whereas medium from HEK293 control cells does not. Untargeted metabolomics revealed that cells expressing ABCC6 excrete large amounts of nucleoside triphosphates, even though ABCC6 itself does not transport nucleoside triphosphates. Extracellularly, ectonucleotidases hydrolyze the excreted nucleoside triphosphates to nucleoside monophosphates and inorganic pyrophosphate (PPi), a strong inhibitor of mineralization that plays a pivotal role in several mineralization disorders similar to PXE. The in vivo relevance of our data are demonstrated in Abcc6(-/-) mice, which had plasma PPi levels <40% of those found in WT mice. This study provides insight into how ABCC6 affects PXE. Our data indicate that the factor that normally prevents PXE is PPi, which is provided to the circulation in the form of nucleoside triphosphates via an as-yet unidentified but ABCC6-dependent mechanism.

Mice without phosphatidylcholine transfer protein have no defects in the secretion of phosphatidylcholine into bile or into lung airspaces.

Phosphatidylcholine transfer protein (Pc-tp) is a highly specific carrier of phosphatidylcholine (PC) without known function. Proposed functions include the supply of PC required for secretion into bile or lung air space (surfactant) and the facilitation of enzymatic reactions involving PC synthesis or breakdown. To test these functions, we generated knock-out mice unable to make Pc-tp. Remarkably, these mice are normal and have no defect in any of the postulated Pc-tp functions analyzed. The lipid content and composition of the bile, as well as lung surfactant secretion and composition, of Pc-tp (-/-) mice, is normal. The lack of a Pc-tp contribution to biliary lipid secretion is in agreement with our finding that Pc-tp is down-regulated in adult mouse liver: whereas Pc-tp is abundant in the liver of mouse pups, Pc-tp levels decrease > 10-fold around 2 wk after birth, when bile formation starts. In adult mice, Pc-tp levels are high only in epididymis, testis, kidney, and bone marrow-derived mast cells. Absence of Pc-tp in bone marrow-derived mast cells does not affect their lipid composition or PC synthesis and degradation. We discuss how PC might reach the canalicular membrane of the hepatocyte for secretion into the bile, if not by Pc-tp.

cDNA cloning and tissue-specific expression of the phosphatidylcholine transfer protein gene.

We have isolated a cDNA containing the complete coding sequence of bovine liver phosphatidylcholine transfer protein (PC-TP). The deduced amino acid sequence consists of 213 amino acid residues and is, except for a lysine instead of an arginine at position 167, identical to the sequence determined by Edman degradation [Akeroyd, Moonen, Westerman, Puyk and Wirtz (1981) Eur. J. Biochem. 114, 385-391]. A cDNA encoding amino acid residues 41-214 of mouse lung PC-TP was also isolated. The predicted amino acid sequence was 90% similar (81% identical) to the corresponding sequence of bovine liver PC-TP, demonstrating that PC-TP is conserved among mammalian species. By Southern blot analysis, evidence was obtained for the presence of a single bovine PC-TP-encoding gene. The expression of the PC-TP gene was determined during mouse embryonic development and in adult mouse tissues using an RNase protection assay. PC-TP RNA was present in embryos at all stages of development as early as the embryonic stem cell, suggesting a role for PC-TP in cell growth and differentiation. Towards the end of embryonic development, just before term, high levels of PC-TP RNA were found in the liver. This level was even higher 7 days post-term. In addition to adult liver, high levels of PC-TP RNA were also found in kidney and testis. The prominent presence of PC-TP in developing and adult liver is compatible with its proposed role in bile formation.

Chromosomal localization of three genes coamplified in the multidrug-resistant CHRC5 Chinese hamster ovary cell line.

At least five gene classes are amplified in the multidrug-resistant CHO cell line CHRC5. Protein products have been identified for two classes; class 2 codes for the large membrane P-glycoprotein, whereas class 4 encodes the small cytoplasmic calcium-binding protein sorcin (V19). By DNA analysis we have shown previously that these five genes are linked in two groups: class 1 + 2 + 3; and class 4 + 5. By use of in situ hybridization with complementary DNAs derived from the resistant cell line we demonstrate here that genes from both linkage groups are amplified and situated together in each of two different chromosomal regions of the resistant Chinese hamster cell line. The positions of the amplicons correspond to cytogenetically identified homogeneously staining regions in an altered 7q+ chromosome and in a rearranged Z-7 [t(3;4)] chromosome. The native genes were mapped both in the CHRC5 line and in a normal diploid Chinese hamster cell strain, CHNF 86. We confirm the position of the class 2 gene on 1q26 and we show that class 4 and 5 genes are located in the same region of 1q. We conclude that the gene classes 2, 4, and 5 are closely juxtaposed in the normal Chinese hamster genome and comprise one amplicon in resistant cells. Our results are compatible with the hypothesis that multidrug resistance is due to overexpression of P-glycoprotein genes and that the other genes amplified in the CHRC5 line are coamplified because they happen to lie close to the P-glycoprotein genes.

A 22-kd protein (sorcin/V19) encoded by an amplified gene in multidrug-resistant cells, is homologous to the calcium-binding light chain of calpain.

We have previously shown that at least five linked genes are co-amplified and overexpressed in the multi-drug resistant (MDR) Chinese hamster ovary cell line CHRC5. We show here that one of these genes (class 4) codes for a small phosphorylated, cytosolic protein, sorcin/V19, known to be overproduced by many MDR cell lines. The class 4 gene codes for a nested set of mRNAs, varying in size between 1000 and 2500 nucleotides. Sequence analysis of complementary DNAs shows that these mRNAs encode a protein of 198 amino acids. The identity of this protein with sorcin was established by comparison with the amino acid sequence of two peptides from mouse sorcin. Hamster sorcin is a 22-kd protein with four 'E-F hand' structures typical of calcium-binding sites and it has substantial homology with the light chain of calpain. Two of the calcium-binding sites contain putative recognition sites for cAMP-dependent protein kinase. These may account for the known phosphorylation of sorcin. The unknown function of sorcin might therefore be controlled by both calcium and cAMP levels. The contribution of sorcin to multidrug resistance, if any, remains to be tested.

A conserved and unique (AT)-rich segment in yeast mitochondrial DNA.

The mtDNA of the cytoplasmic petite mutant of yeast RD1A consists mainly of a perfect head-to-tail repetition of a known sequence of 66 consecutive AT and 2 GC base pairs. We have hybridized complementary RNA made on RD1A mtDNA with the mtDNAs of four different wild-type Saccharomyces strains that differ markedly in restriction fragmentation pattern. The tm's of the four heteroduplexes are identical to the tm of the homoduplex of RD1A mtDNA with complementary RNA of one repeat length. With all four wild-type mtDNAs this complementary RNA hybridizes mainly to a single restriction fragment of about 300 base pairs. This shows the conservation and individuality of at least one (AT)-rich segment in yeast mtDNA. The 300 base pair fragment has been mapped in the vicinity of the oxi-2 locus. The possible role of the (AT)-rich segment in the processing of the primary transcript of this region is discussed.