Peroxisome fission is associated with reorganization of specific membrane proteins.

Membrane remodeling is an important aspect in organelle biogenesis. We show that different peroxisome membrane proteins that play a role in organelle biogenesis and proliferation (Pex8, Pex10, Pex14, Pex25 and Pex11) are subject to spatiotemporal behavior during organelle development. Using fluorescence microscopy analysis of Hansenula polymorpha dnm1 cells that are blocked in the normal fission process, we show that green fluorescent protein (GFP) fusions of Pex8, Pex10, Pex14 and Pex25 show enhanced fluorescence at the organelle extensions that are formed in budding cells. In contrast, Pex11 fluorescence is enriched at the base of this extension on the mother organelle. A fusion protein of GFP with the transporter Pmp47, used as a control, did not show enhanced fluorescence at any specific region of the organelle. The concentration of specific peroxins at the peroxisome surface was lost upon deletion of PEX11 or the N-terminal domain of Pex11 that is involved in membrane remodeling. Comparable distribution patterns as in dnm1 cells were observed in wild-type cells where Pex8, Pex10, Pex14 and Pex25, but not Pex11, were especially present at newly formed organelles that migrated to the bud. We speculate that peroxin reorganization events result in enhanced levels of peroxins involved in peroxisome biogenesis in nascent organelles.

A conserved function for Inp2 in peroxisome inheritance.

In budding yeast Saccharomyces cerevisiae, the peroxisomal protein Inp2 is required for inheritance of peroxisomes to the bud, by connecting the organelles to the motor protein Myo2 and the actin cytoskeleton. Recent data suggested that the function of Inp2 may not be conserved in other yeast species. Using in silico analyses we have identified a weakly conserved Inp2-related protein in 18 species of budding yeast and analyzed the role of the identified protein in the methylotrophic yeast Hansenula polymorpha in peroxisome inheritance. Our data show that H. polymorpha Inp2 locates to peroxisomes, interacts with Myo2, and is essential for peroxisome inheritance.

Preperoxisomal vesicles can form in the absence of Pex3.

We demonstrate that the peroxin Pex3 is not required for the formation of peroxisomal membrane structures in yeast pex3 mutant cells. Notably, pex3 mutant cells already contain reticular and vesicular structures that harbor key proteins of the peroxisomal receptor docking complex-Pex13 and Pex14-as well as the matrix proteins Pex8 and alcohol oxidase. Other peroxisomal membrane proteins in these cells are unstable and transiently localized to the cytosol (Pex10, Pmp47) or endoplasmic reticulum (Pex11). These reticular and vesicular structures are more abundant in cells of a pex3 atg1 double deletion strain, as the absence of Pex3 may render them susceptible to autophagic degradation, which is blocked in this double mutant. Contrary to earlier suggestions, peroxisomes are not formed de novo from the endoplasmic reticulum when the PEX3 gene is reintroduced in pex3 cells. Instead, we find that reintroduced Pex3 sorts to the preperoxisomal structures in pex3 cells, after which these structures mature into normal peroxisomes.