Targeting of human catalase to peroxisomes is dependent upon a novel COOH-terminal peroxisomal targeting sequence.

[neonatal adrenoleukodystrophy]

We have identified a novel peroxisomal targeting sequence (PTS ) at the extreme COOH terminus of human catalase . The last four amino acids of this protein (-KANL ) are necessary and sufficient to effect targeting to peroxisomes in both human fibroblasts and Saccharomyces cerevisiae , when appended to the COOH terminus of the reporter protein , chloramphenicol acetyl transferase . However , this PTS differs from the extensive family of COOH-terminal PTS tripeptides collectively termed PTS 1 in two major aspects . First , the presence of the uncharged amino acid , asparagine , at the penultimate residue of the human catalase PTS is highly unusual , in that a basic residue at this position has been previously found to be a common and critical feature of PTS 1 signals . Nonetheless , this asparagine residue appears to constitute an important component of the catalase PTS , in that replacement with aspartate abolished peroxisomal targeting (as did deletion of the COOH-terminal four residues ). Second , the human catalase PTS comprises more than the COOH-terminal three amino acids , in that COOH-terminal-ANL can not functionally replace the PTS 1 signal-SKL in targeting a chloramphenicol acetyl transferase fusion protein to peroxisomes . The critical nature of the fourth residue from the COOH terminus of the catalase PTS (lysine ) is emphasized by the fact that substitution of this residue with a variety of other amino acids abolished or reduced peroxisomal targeting . Targeting was not reduced when this lysine was replaced with arginine , suggesting that a basic amino acid at this position is required for maximal functional activity of this PTS . In spite of these unusual features , human catalase is sorted by the PTS 1 pathway , both in yeast and human cells . Disruption of the PAS 10 gene encoding the S . cerevisiae PTS 1 receptor resulted in a cytosolic location of chloramphenicol acetyl transferase appended with the human catalase PTS , as did expression of this protein in cells from a neonatal adrenoleukodystrophy patient specifically defective in PTS 1 import . Furthermore , through the use of the two -hybrid system , it was demonstrated that both the PAS 10 gene product (Pas 10 p ) and the human PTS 1 receptor can interact with the COOH-terminal region of human catalase , but that this interaction is abolished by substitutions at the penultimate residue (asparagine-to - aspartate ) and at the fourth residue from the COOH terminus (lysine-to -glycine ) which abolish PTS functionality . We have found no evidence of additional targeting information elsewhere in the human catalase protein . An internal tripeptide (-SHL-, which conforms to the mammalian PTS 1 consensus ) located nine to eleven residues from the COOH terminus has been excluded as a functional PTS . Additionally , in contrast to the situation for S . cerevisiae catalase A , which contains an internal PTS in addition to a COOH-terminal PTS 1 , human catalase lacks such a redundant PTS , as evidenced by the exclusive cytosolic location of human catalase mutated in the COOH-terminal PTS . Consistent with this species difference , fusions between catalase A and human catalase which include the catalase A internal PTS are targeted , at least in part , to peroxisomes regardless of whether the COOH-terminal human catalase PTS is intact .