ARF- and coatomer-mediated peroxisomal vesiculation

The authors characterized on a molecular level the clofibrate-inducible 26-kDa integral peroxisomal membrane protein (Pmp26p, Pex11-1p) of rat liver. By screening cDNA databases with the obtained Pex11-1p-cDNA, a second homologous cDNA was identified that codes for a polypeptide with slightly larger molecular mass than Pex11-1p. The authors call this polypeptide Pex11-2p. Studies on the topology of Pex11-1p revealed two transmembrane domains with the N- and C-terminus facing the cytoplasm. The C-terminal tail of Pex11-1p ends in a consensus dilysine motif of the type-KXKXX-COOH, which is known to be involved in the ADP-ribosylation factor (ARF)1-coat protein (COP) I coat (ARF)1-dependent membrane recruitment to Golgi membranes. Studies with isolated peroxisomes incubated in the presence of cytosol, adenosine triphosphate and GTPγS, indeed, provided evidence for specific binding of ARF and coatomer to peroxisomes. Expression of Pex11-1p in Chinese hamster ovary (CHO) wild-type cells led to a twofold increase in the number of peroxisomes, but expression in a temperature-sensitive CHO mutant, defective in coatomer, induced elongation and tubulation of peroxisomal structures, rather than numerical proliferation. The obtained results for the first time offer a mechanism explaining Pex11-1p-, as well as ARF- and coatomer-mediated peroxisomal vesiculation. Two models are presented that may explain how these observations fit in with peroxisome biogenesis.     

COPI budding within the Golgi stack

The Golgi serves as a hub for intracellular membrane traffic in the eukaryotic cell. Transport within the early secretory pathway, that is within the Golgi and from the Golgi to the endoplasmic reticulum, is mediated by COPI-coated vesicles. The COPI coat shares structural features with the clathrin coat, but differs in the mechanisms of cargo sorting and vesicle formation. The small GTPase Arf1 initiates coating on activation and recruits en bloc the stable heptameric protein complex coatomer that resembles the inner and the outer shells of clathrin-coated vesicles. Different binding sites exist in coatomer for membrane machinery and for the sorting of various classes of cargo proteins. During the budding of a COPI vesicle, lipids are sorted to give a liquid-disordered phase composition. For the release of a COPI-coated vesicle, coatomer and Arf cooperate to mediate membrane separation.     

Coatomer, the coat protein of COPI transport vesicles, discriminates endoplasmic reticulum residents from p24 proteins

In the formation of COPI vesicles, interactions take place between the coat protein coatomer and membrane proteins: either cargo proteins for retrieval to the endoplasmic reticulum (ER) or proteins that cycle between the ER and the Golgi. While the binding sites on coatomer for ER residents have been characterized, how cycling proteins bind to the COPI coat is still not clear. In order to understand at a molecular level the mechanism of uptake of such proteins, we have investigated the binding to coatomer of p24 proteins as examples of cycling proteins as well as that of ER-resident cargos. The p24 proteins required dimerization to interact with coatomer at two independent binding sites in gamma-COP. In contrast, ER-resident cargos bind to coatomer as monomers and to sites other than gamma-COP. The COPI coat therefore discriminates between p24 proteins and ER-resident proteins by differential binding involving distinct subunits.     

Atg36

Eukaryotic cells adapt their organelle composition and abundance according to environmental conditions. Analysis of the peroxisomal membrane protein Pex3 has revealed that this protein plays a crucial role in peroxisome maintenance as it is required for peroxisome formation, segregation and breakdown. Although its function in peroxisome formation and segregation was known to involve its recruitment to the peroxisomal membrane of factors specific for these processes, the role of Pex3 in peroxisome breakdown was unclear until our recent identification of Atg36 as a novel Saccharomyces cerevisiae Pex3-interacting protein. Atg36 is recruited to peroxisomes by Pex3 and is required specifically for pexophagy. Atg36 is distinct from Atg30, the pexophagy receptor identified in Pichia pastoris. Atg36 interacts with Atg11 in vivo, and to a lesser extent with Atg8. These latter proteins link autophagic cargo receptors to the core autophagy machinery. Like other autophagic cargo receptors, Atg36 is a suicide receptor and is broken down in the vacuole together with its cargo. Unlike other cargo receptors, the interaction between Atg36 and Atg8 does not seem to be direct. Our recent findings suggest that Atg36 is a novel pexophagy receptor that may target peroxisomes for degradation via a noncanonical mechanism.     

Atg36: The Saccharomyces cerevisiae receptor for pexophagy

Eukaryotic cells adapt their organelle composition and abundance according to environmental conditions. Analysis of the peroxisomal membrane protein Pex3 has revealed that this protein plays a crucial role in peroxisome maintenance as it is required for peroxisome formation, segregation and breakdown. Although its function in peroxisome formation and segregation was known to involve its recruitment to the peroxisomal membrane of factors specific for these processes, the role of Pex3 in peroxisome breakdown was unclear until our recent identification of Atg36 as a novel Saccharomyces cerevisiae Pex3-interacting protein. Atg36 is recruited to peroxisomes by Pex3 and is required specifically for pexophagy. Atg36 is distinct from Atg30, the pexophagy receptor identified in Pichia pastoris. Atg36 interacts with Atg11 in vivo, and to a lesser extent with Atg8. These latter proteins link autophagic cargo receptors to the core autophagy machinery. Like other autophagic cargo receptors, Atg36 is a suicide receptor and is broken down in the vacuole together with its cargo. Unlike other cargo receptors, the interaction between Atg36 and Atg8 does not seem to be direct. Our recent findings suggest that Atg36 is a novel pexophagy receptor that may target peroxisomes for degradation via a noncanonical mechanism.     

Pex11p plays a primary role in medium-chain fatty acid oxidation, a process that affects peroxisome number and size in Saccharomyces cerevisiae

The Saccharomyces cerevisiae peroxisomal membrane protein Pex11p has previously been implicated in peroxisome proliferation based on morphological observations of PEX11 mutant cells. Pex11p-deficient cells fail to increase peroxisome number in response to growth on fatty acids and instead accumulate a few giant peroxisomes. We report that mutants deficient in genes required for medium-chain fatty acid (MCFA) beta-oxidation display the same phenotype as Pex11p-deficient cells. Upon closer inspection, we found that Pex11p is required for MCFA beta-oxidation. Disruption of the PEX11 gene results in impaired formation of MCFA-CoA esters as measured in intact cells, whereas their formation is normal in cell lysates. The sole S. cerevisiae MCFA-CoA synthetase (Faa2p) remains properly localized to the inner leaflet of the peroxisomal membrane in PEX11 mutant cells. Therefore, the in vivo latency of MCFA activation observed in Pex11p-deficient cells suggests that Pex11p provides Faa2p with substrate. When PEX11 mutant cells are shifted from glucose to oleate-containing medium, we observed an immediate deficiency in beta-oxidation of MCFAs whereas giant peroxisomes and a failure to increase peroxisome abundance only became apparent much later. Our observations suggest that the MCFA oxidation pathway regulates the level of a signaling molecule that modulates the number of peroxisomal structures in a cell.     

A dual function for Pex3p in peroxisome formation and inheritance

Saccharomyces cerevisiae Pex3p has been shown to act at the ER during de novo peroxisome formation. However, its steady state is at the peroxisomal membrane, where its role is debated. Here we show that Pex3p has a dual function: one in peroxisome formation and one in peroxisome segregation. We show that the peroxisome retention factor Inp1p interacts physically with Pex3p in vitro and in vivo, and split-GFP analysis shows that the site of interaction is the peroxisomal membrane. Furthermore, we have generated PEX3 alleles that support peroxisome formation but fail to support recruitment of Inp1p to peroxisomes, and as a consequence are affected in peroxisome segregation. We conclude that Pex3p functions as an anchor for Inp1p at the peroxisomal membrane, and that this function is independent of its role at the ER in peroxisome biogenesis.     

Involvement of the endoplasmic reticulum in peroxisome formation

The traditional view holds that peroxisomes are autonomous organelles multiplying by growth and division. More recently, new observations have challenged this concept. Herein, we present evidence supporting the involvement of the endoplasmic reticulum (ER) in peroxisome formation by electron microscopy, immunocytochemistry and three-dimensional image reconstruction of peroxisomes and associated compartments in mouse dendritic cells. We found the peroxisomal membrane protein Pex13p and the ATP-binding cassette transporter protein PMP70 present in specialized subdomains of the ER that were continuous with a peroxisomal reticulum from which mature peroxisomes arose. The matrix proteins catalase and thiolase were only detectable in the reticula and peroxisomes. Our results suggest the existence of a maturation pathway from the ER to peroxisomes and implicate the ER as a major source from which the peroxisomal membrane is derived.     

Molecular structure and flexibility of the yeast coatomer as revealed by electron microscopy

Coat protein complex I (COPI)-coated vesicles, one of three major types of vesicular carriers in the cell, mediate the early secretory pathway and retrograde transport from the Golgi to the endoplasmic reticulum. COPI vesicles are generated through activation of the regulatory GTPase Arf1 at the donor membrane and the subsequent recruitment of coatomer, a coat protein complex consisting of seven stably associated components. Coatomer functions in binding and sequestering cargo molecules and assembles into a polymeric protein shell that encompasses the surface of COPI vesicles. Little is known about the structural properties of this heptameric complex. We have isolated native yeast coatomer and examined its structure and subunit organization by single-particle electron microscopy. Our analyses provide the first three-dimensional picture of the complete coatomer and reveal substantial conformational flexibility likely to be critical for its scaffolding function.     

Differential roles of ArfGAP1, ArfGAP2, and ArfGAP3 in COPI trafficking

The formation of coat protein complex I (COPI)–coated vesicles is regulated by the small guanosine triphosphatase (GTPase) adenosine diphosphate ribosylation factor 1 (Arf1), which in its GTP-bound form recruits coatomer to the Golgi membrane. Arf GTPase-activating protein (GAP) catalyzed GTP hydrolysis in Arf1 triggers uncoating and is required for uptake of cargo molecules into vesicles. Three mammalian ArfGAPs are involved in COPI vesicle trafficking; however, their individual functions remain obscure. ArfGAP1 binds to membranes depending on their curvature. In this study, we show that ArfGAP2 and ArfGAP3 do not bind directly to membranes but are recruited via interactions with coatomer. In the presence of coatomer, ArfGAP2 and ArfGAP3 activities are comparable with or even higher than ArfGAP1 activity. Although previously speculated, our results now demonstrate a function for coatomer in ArfGAP-catalyzed GTP hydrolysis by Arf1. We suggest that ArfGAP2 and ArfGAP3 are coat protein–dependent ArfGAPs, whereas ArfGAP1 has a more general function.     

Peroxisome Biogenesis: Involvement of ARF and Coatomer

Peroxisomal membrane protein (Pmp)26p (RnPex11p), a major constituent of induced rat liver peroxisomal membrane, was found to contain a COOH-terminal, cytoplasmically exposed consensus dilysine motif with the potential to bind coatomer. Biochemical as well as immunocytochemical evidence is presented showing that peroxisomes incubated with preparations of bovine brain or rat liver cytosol recruit ADP-ribosylation factor (ARF) and coatomer in a strictly guanosine 5′-O-(3-thiotriphosphate)–dependent manner. Consistent with this observation, ldlF cells expressing a temperature-sensitive mutant version of the ε-subunit of coatomer exhibit elongated tubular peroxisomes possibly due to impaired vesiculation at the nonpermissive temperature. Since overexpression of Pex11p in Chinese hamster ovary wild-type cells causes proliferation of peroxisomes, these data suggest that Pex11p plays an important role in peroxisome biogenesis by supporting ARF- and coatomer-dependent vesiculation of the organelles.     

A subtle interplay between three Pex11 proteins shapes de novo formation and fission of peroxisomes

The organization of eukaryotic cells into membrane-bound compartments must be faithfully sustained for survival of the cell. A subtle equilibrium exists between the degradation and the proliferation of organelles. Commonly, proliferation is initiated by a membrane remodeling process. Here, we dissect the function of proteins driving organelle proliferation in the particular case of peroxisomes. These organelles are formed either through a growth and division process from existing peroxisomes or de novo from the endoplasmic reticulum (ER). Among the proteins involved in the biogenesis of peroxisomes, peroxins, members of the Pex11 protein family participate in peroxisomal membrane alterations. In the yeast Saccharomyces cerevisiae, the Pex11 family consists of three proteins, Pex11p, Pex25p and Pex27p. Here we demonstrate that yeast mutants lacking peroxisomes require the presence of Pex25p to regenerate this organelle de novo. We also provide evidence showing that Pex27p inhibits peroxisomal function and illustrate that Pex25p initiates elongation of the peroxisomal membrane. Our data establish that although structurally conserved each of the three Pex11 protein family members plays a distinct role. While ScPex11p promotes the proliferation of peroxisomes already present in the cell, ScPex25p initiates remodeling at the peroxisomal membrane and ScPex27p acts to counter this activity. In addition, we reveal that ScPex25p acts in concert with Pex3p in the initiation of de novo peroxisome biogenesis from the ER.     

Peroxisome Formation Requires the Endoplasmic Reticulum Channel Protein Sec61

In peroxisome formation, models of near‐autonomous peroxisome biogenesis with membrane protein integration directly from the cytosol into the peroxisomal membrane are in direct conflict with models whereby peroxisomes bud from the endoplasmic reticulum and receive their membrane proteins through a branch of the secretory pathway. We therefore reinvestigated the role of the Sec 61 complex, the protein‐conducting channel of the endoplasmic reticulum (ER) in peroxisome formation. We found that depletion or partial inactivation of Sec 61 in yeast disables peroxisome formation. The ER entry of the early peroxisomal membrane protein Pex 3 engineered with a glycosylation tag is reduced in sec61 mutant cells. Moreover, we were able to reconstitute Pex 3 import into ER membranes in vitro, and we identified a variant of a signal anchor sequence for ER translocation at the Pex 3 N‐terminus. Our findings are consistent with a Sec 61 requirement for peroxisome formation and a fundamental role of the ER in peroxisome biogenesis.     

Endoplasmic reticulum-directed Pex3p routes to peroxisomes and restores peroxisome formation in a Saccharomyces cerevisiae pex3Delta strain

Recent studies on the sorting of peroxisomal membrane proteins challenge the long-standing model in which peroxisomes are considered to be autonomous organelles that multiply by growth and division. Here, we present data lending support to the idea that the endoplasmic reticulum (ER) is involved in sorting of the peroxisomal membrane protein Pex3p, a protein required early in peroxisome biogenesis. First, we show that the introduction of an artificial glycosylation site into the N terminus of Pex3p leads to partial N-linked core glycosylation, indicative of insertion into the ER membrane. Second, when FLAG-tagged Pex3p is equipped with an ER targeting signal, it can restore peroxisome formation in pex3Delta cells. Importantly, FLAG antibodies that specifically recognize the processed Pex3p show that the signal peptide of the fusion protein is efficiently cleaved off and that the processed protein localizes to peroxisomes. In contrast, a Pex3p construct in which cleavage of the signal peptide is blocked by a mutation localizes to the ER and the cytosol and cannot complement pex3Delta cells. Together, these results strongly suggest that ER-targeted Pex3p indeed routes via the ER to peroxisomes, and we hypothesize that this pathway is also used by endogenous Pex3p.     

Association of tapasin and COPI provides a mechanism for the retrograde transport of major histocompatibility complex (MHC) class I molecules from the Golgi complex to the endoplasmic reticulum

Tapasin is a subunit of the transporter associated with antigen processing (TAP). It associates with the major histocompatibility complex (MHC) class I. We show that tapasin interacts with beta- and gamma-subunits of COPI coatomer. COPI retrieves membrane proteins from the Golgi network back to the endoplasmic reticulum (ER). The COPI subunit-associated tapasin also interacts with MHC class I molecules suggesting that tapasin acts as the cargo receptor for packing MHC class I molecules as cargo proteins into COPI-coated vesicles. In tapasin mutant cells, neither TAP nor MHC class I are detected in association with the COPI coatomer. Interestingly, tapasin-associated MHC class I molecules are antigenic peptide-receptive and detected in both the ER and the Golgi. Our data suggest that tapasin is required for the COPI vesicle-mediated retrograde transport of immature MHC class I molecules from the Golgi network to the ER.     

Inhibitors of COPI and COPII do not block PEX3-mediated peroxisome synthesis

In humans, defects in peroxisome biogenesis are the cause of lethal diseases typified by Zellweger syndrome. Here, we show that inactivating mutations in human PEX3 cause Zellweger syndrome, abrogate peroxisome membrane synthesis, and result in reduced abundance of peroxisomal membrane proteins (PMPs) and/or mislocalization of PMPs to the mitochondria. Previous studies have suggested that PEX3 may traffic through the ER en route to the peroxisome, that the COPI inhibitor, brefeldin A, leads to accumulation of PEX3 in the ER, and that PEX3 overexpression alters the morphology of the ER. However, we were unable to detect PEX3 in the ER at early times after expression. Furthermore, we find that inhibition of COPI function by brefeldin A has no effect on trafficking of PEX3 to peroxisomes and does not inhibit PEX3-mediated peroxisome biogenesis. We also find that inhibition of COPII-dependent membrane traffic by a dominant negative SAR1 mutant fails to block PEX3 transport to peroxisomes and PEX3-mediated peroxisome synthesis. Based on these results, we propose that PEX3 targeting to peroxisomes and PEX3-mediated peroxisome membrane synthesis may occur independently of COPI- and COPII-dependent membrane traffic.     

Coupling of coat assembly and vesicle budding to packaging of putative cargo receptors

COPI-coated vesicle budding from lipid bilayers whose composition resembles mammalian Golgi membranes requires coatomer, ARF, GTP, and cytoplasmic tails of putative cargo receptors (p24 family proteins) or membrane cargo proteins (containing the KKXX retrieval signal) emanating from the bilayer surface. Liposome-derived COPI-coated vesicles are similar to their native counterparts with respect to diameter, buoyant density, morphology, and the requirement for an elevated temperature for budding. These results suggest that a bivalent interaction of coatomer with membrane-bound ARF[GTP] and with the cytoplasmic tails of cargo or putative cargo receptors is the molecular basis of COPI coat assembly and provide a simple mechanism to couple uptake of cargo to transport vesicle formation.     

Peroxisome biogenesis and peroxisome biogenesis disorders

Peroxisome assembly in mammals requires more than 15 genes. Two isoforms of the peroxisome targeting signal type 1 (PTS1) receptor, Pex5pS and Pex5pL, are identified in mammals. Pex5pS and Pex5pL bind PTS1 proteins. Pex5pL, but not Pex5pS, directly interacts with the PTS2 receptor, Pex7p, carrying its cargo PTS2 protein in the cytosol. Pex5p carrying the cargos, PTS1 and PTS2, docks with the initial site Pex14p in a putative import machinery, subsequently translocating to other components such as Pex13p, Pex2p, Pex10p and Pex12p, whereby the matrix proteins are imported. The peroxins, Pex3p, Pex16p and Pex19p, function in the assembly of peroxisomal membrane vesicles that precedes the import of matrix proteins. Hence, peroxisomes may form de novo and do not have to arise from pre-existing, morphologically recognizable peroxisomes. Impaired peroxisome assembly causes peroxisome biogenesis disorders such as Zellweger syndrome.     

An ER‐peroxisome tether exerts peroxisome population control in yeast

Eukaryotic cells compartmentalize biochemical reactions into membrane‐enclosed organelles that must be faithfully propagated from one cell generation to the next. Transport and retention processes balance the partitioning of organelles between mother and daughter cells. Here we report the identification of an ER‐peroxisome tether that links peroxisomes to the ER and ensures peroxisome population control in the yeast Saccharomyces cerevisiae. The tether consists of the peroxisome biogenic protein, Pex3p, and the peroxisome inheritance factor, Inp1p. Inp1p bridges the two compartments by acting as a molecular hinge between ER‐bound Pex3p and peroxisomal Pex3p. Asymmetric peroxisome division leads to the formation of Inp1p‐containing anchored peroxisomes and Inp1p‐deficient mobile peroxisomes that segregate to the bud. While peroxisomes in mother cells are not released from tethering, de novo formation of tethers in the bud assists in the directionality of peroxisome transfer. Peroxisomes are thus stably maintained over generations of cells through their continued interaction with tethers.