Biosynthesis of peroxisomal enzymes in the methylotrophic yeast Hansenula polymorpha

Synthesis of a major integral membrane polypeptide of rat liver peroxisomes on free polysomes

The manner of synthesis and assembly of the peroxisomal membrane proteins is unknown. Understanding these processes is essential to an understanding of the formation of the organelle. We have investigated the biogenesis of the previously identified major 21.7-kDa integral peroxisomal membrane polypeptide [Fujiki, Y., Fowler, S., Shio, H., Hubbard, A. L. & Lazarow, P. B. (1982) J. Cell Biol. 93, 103-110]. This protein was purified to apparent homogeneity and used to elicit a rabbit antiserum. In immunoblotting analysis, antibody bound only to the 22-kDa membrane polypeptide present exclusively in peroxisomal membranes. Total rat liver RNA was translated in a nuclease-treated rabbit reticulocyte cell-free protein-synthesizing system. The in vitro translation product, isolated by means of the antibody and Staphylococcus aureus cells, comigrated with the mature 22-kDa polypeptide in NaDodSO4/PAGE. Analysis of the translation products of RNAs from free and membrane-bound polysomes indicated that the mRNA for the 22-kDa membrane polypeptide is found predominantly in free polysomes. The results imply post-translational insertion of the membrane polypeptide into the peroxisomal membrane without proteolytic processing and suggest that peroxisomes, like mitochondria and chloroplasts, form by fission from preexisting organelles.

High-level expression and molecular cloning of genes encoding Candida tropicalis peroxisomal proteins

The development of peroxisomes in the cells of Candida tropicalis grown on oleic acid was accompanied by a markedly high expression of peroxisomal proteins. On the basis of this finding, the nuclear DNA library of this yeast was screened by differential hybridization, and 102 clones of oleic acid-inducible sequences were isolated. Seven coding regions were found to form clusters in three stretches of the genomic DNA. Five of the regions were identified as genes for peroxisomal polypeptides (PXPs). The coding sequence for PXP-2 hybrid selected an additional mRNA for PXP-4, the subunit of long-chain acyl coenzyme A oxidase, which was the most abundant PXP. PXP-2 and PXP-4 were close in apparent molecular weight and generated similar peptides when digested with a protease. The gene for PXP-4 was adjacent to that for PXP-2 on the genome and also hybridized to the mRNA coding for PXP-5. These and other similar results suggest that the genes for the peroxisomal proteins of this organism arose by duplication of a few ancestral genes.

Import of in-vitro-synthesized glyoxysomal malate dehydrogenase into isolated watermelon glyoxysomes

Glyoxysomal malate dehydrogenase (gMDH; EC 1.1.1.37) is synthesized by a reticulocyte system in the presence of watermelon mRNA (Citrullus vulgaris Schrad., var. Kleckey's Sweet No 6) as a cytosolic, higher-molecular-weight precursor (41 kdalton). We now show that this precursor is posttranslationally sequestered by a crude glyoxysomal fraction or by glyoxysomes purified on a Percoll(R) gradient to a proteolytically protected form (60 min proteinase-K treatment at 4° C) with the size of the gMDH subunit (33 kdalton). In the presence of buffer instead of organelles a complete degradation of the precursor is obtained. The in-vitro organelle import, however, depends upon the presence of proteases such as proteinase K or trypsin. After short proteolytic treatments (e.g. 10 min proteinase K at 4° C), the correct processing of the MDH precursor is obtained even in the absence of organelles. This product, however, is not sequestered in vitro to a protease-resistant form by glyoxysomes. The possibility is discussed that under in-vivo conditions pre-gMDH is processed on the outside of the glyoxysomal membrane and transferred immediately after processing into the organelle presumably as a gMDH monomer followed by refolding and dimerization.