Peroxisomes: offshoots of the ER.

Peroxisomes are part of the ubiquitous set of eukaryotic organelles. They are small, single membrane bounded vesicles, specialized in the degradation of very-long-chain fatty acids and in synthesis of myelin lipids. Once considered inconspicuous, recent new insights in the formation and function of peroxisomes have revealed a much more subtle interplay between organelles that warrant a re-evaluation of the historical assignment of peroxisomes as being either autonomous or ER-derived. Peroxisomes acquire their lipids and membrane proteins from the ER, whereas they import their matrix proteins directly from the cytosol. Remarkably, many of its metabolic enzymes and factors controlling peroxisome abundance (fission and inheritance) too are shared with other organelles, stressing interdependence among cellular compartments.

Peroxisome formation and maintenance are dependent on the endoplasmic reticulum.

Looks can be deceiving. Although peroxisomes appear to be simple organelles, their formation and maintenance pose unique challenges for the cell. The birth of new peroxisomes starts at the endoplasmic reticulum (ER), which delivers lipids and membrane proteins. To form a new peroxisomal compartment, ER-derived preperoxisomal vesicles carrying different membrane proteins fuse, allowing the assembly of the peroxisomal translocon. To complete formation, peroxisomes import their soluble proteins directly from the cytosol using the newly assembled translocon. Together with the ER-derived biogenic route, peroxisomal fission and segregation subsequently maintain the cellular peroxisome population. In this review we highlight the latest insights on the life cycle of peroxisomes and show how the new cell biology concept of peroxisome formation affects our thinking about peroxisome-related diseases and their evolutionary past. The future challenge lies in the identification of all the proteins involved in this elaborate biogenic process and the dissection of their mechanism of action.

Biochemically distinct vesicles from the endoplasmic reticulum fuse to form peroxisomes.

As a rule, organelles in eukaryotic cells can derive only from pre-existing organelles. Peroxisomes are unique because they acquire their lipids and membrane proteins from the endoplasmic reticulum (ER), whereas they import their matrix proteins directly from the cytosol. We have discovered that peroxisomes are formed via heterotypic fusion of at least two biochemically distinct preperoxisomal vesicle pools that arise from the ER. These vesicles each carry half a peroxisomal translocon complex. Their fusion initiates assembly of the full peroxisomal translocon and subsequent uptake of enzymes from the cytosol. Our findings demonstrate a remarkable mechanism to maintain biochemical identity of organelles by transporting crucial components via different routes to their final destination.

Peroxisomal membrane proteins insert into the endoplasmic reticulum.

We show that a comprehensive set of 16 peroxisomal membrane proteins (PMPs) encompassing all types of membrane topologies first target to the endoplasmic reticulum (ER) in Saccharomyces cerevisiae. These PMPs insert into the ER membrane via the protein import complexes Sec61p and Get3p (for tail-anchored proteins). This trafficking pathway is representative for multiplying wild-type cells in which the peroxisome population needs to be maintained, as well as for mutant cells lacking peroxisomes in which new peroxisomes form after complementation with the wild-type version of the mutant gene. PMPs leave the ER in a Pex3p-Pex19p-dependent manner to end up in metabolically active peroxisomes. These results further extend the new concept that peroxisomes derive their basic framework (membrane and membrane proteins) from the ER and imply a new functional role for Pex3p and Pex19p.

Peroxisomes: minted by the ER.

Peroxisomes are one of numerous organelles in a eukaryotic cell; they are small, single-membrane-bound vesicles involved in cellular metabolism, particularly fatty acid degradation. Transport of metabolites and co-factors in and across the membrane is taken care of by specific transporters. Peroxisome formation and maintenance has been debated for a long time: opinions swinging from autonomous to ER-derived organelles. Only recently it has been established firmly that the site of origin of peroxisomes is the ER. It implies that a new branch of the endomembrane system is open to further characterization.

The return of the peroxisome.

Of the classical compartments of eukaryotic cells, peroxisomes were the last to be discovered. They are small, single-membrane-bound vesicles involved in cellular metabolism, most notably the beta-oxidation of fatty acids. Characterization of their properties and behavior has progressed rather slowly. However, during the past few years, peroxisomes have entered the limelight as a result of several breakthroughs. These include the observations that they are not autonomously multiplying organelles but are derived from the endoplasmic reticulum, and that partitioning of peroxisomes to progeny cells is an active and well-controlled process. In addition, we are discovering more and more proteins that are not only dedicated to peroxisomes but also serve other organelles.