Involvement of the carboxyl-terminal region of the yeast peroxisomal half ABC transporter Pxa2p in its interaction with Pxa1p and in transporter function.

[x-linked adrenoleukodystrophy]

The peroxisome is a single membrane-bound organelle in eukaryotic cells involved in lipid metabolism , including β-oxidation of fatty acids . The human genetic disorder X-linked adrenoleukodystrophy (X-ALD ) is caused by mutations in the ABCD 1 gene (encoding ALDP , a peroxisomal half ATP-binding cassette [ABC ] transporter ). This disease is characterized by defective peroxisomal β-oxidation and a large accumulation of very long -chain fatty acids in brain white matter , adrenal cortex , and testis . ALDP forms a homodimer proposed to be the functional transporter , whereas the peroxisomal transporter in yeast is a heterodimer comprising two half ABC transporters , Pxa 1 p and Pxa 2 p , both orthologs of human ALDP . While the carboxyl-terminal domain of ALDP is engaged in dimerization , it remains unknown whether the same region is involved in the interaction between Pxa 1 p and Pxa 2 p .U sing a yeast two -hybrid assay , we found that the carboxyl-terminal region (CT ) of Pxa 2 p , but not of Pxa 1 p , is required for their interaction . Further analysis indicated that the central part of the CT (designated CT 2 ) of Pxa 2 p was indispensable for its interaction with the carboxyl terminally truncated Pxa 1 _NBD . An interaction between the CT of Pxa 2 p and Pxa 1 _NBD was not detected , but could be identified in the presence of Pxa 2 _NBD-CT 1 . A single mutation of two conserved residues (aligned with X-ALD -associated mutations at the same positions in ALDP ) in the CT 2 of the Pxa 2 _NBD-CT protein impaired its interaction with Pxa 1 _NBD or Pxa 1 _NBD-CT , resulting in a mutant protein that exhibited a proteinase K digestion profile different from that of the wild-type protein . Functional analysis of these mutant proteins on oleate plates indicated that they were defective in transporter function .The CT of Pxa 2 p is involved in its interaction with Pxa 1 p and in transporter function . This concept may be applied to human ALDP studies , helping to establish the pathological mechanism for CT -related X-ALD disease .