Taras Y. Nazarko

Molecular mechanism and physiological role of pexophagy

Pexophagy is a selective autophagy process wherein damaged and/or superfluous peroxisomes undergo vacuolar degradation. In methylotropic yeasts, where pexophagy has been studied most extensively, this process occurs by either micro‐ or macropexophagy: processes analogous to micro‐ and macroautophagy. Recent studies have identified specific factors and illustrated mechanisms involved in pexophagy. Although mechanistically pexophagy relies heavily on the core autophagic machinery, the latest findings about the role of auxiliary pexophagy factors have highlighted specialized membrane structures required for micropexophagy, and shown how cargo selectivity is achieved and how cargo size dictates the requirement for these factors during pexophagy. These insights and additional observations in the literature provide a framework for an understanding of the physiological role(s) of pexophagy.

Trs85 is Required for Macroautophagy, Pexophagy and Cytoplasm to Vacuole Targeting in Yarrowia lipolytica and Saccharomyces cerevisiae

Yarrowia lipolytica was recently introduced as a new model organism to study peroxisome degradation in yeasts. Transfer of Y. lipolytica cells from oleate/ethylamine to glucose/ammonium chloride medium leads to selective macroautophagy of peroxisomes. To decipher the molecular mechanisms of macropexophagy we made use of Y. lipolytica tagged mutants affected in the inactivation of peroxisomal enzymes under pexophagy conditions, Ain16 and Ain19. Both strains appeared to be disrupted at two different sites of the same gene, YlTRS85, the ortholog of Saccharomyces cerevisiae TRS85 that encodes 85 kDa subunit of transport protein particle (TRAPP). Y. lipolytica trs85 mutants had multiple defects of protein transport to external medium, cell wall and vacuoles, indicating that YlTrs85 is indeed the ScTrs85 functional homologue, required early in the classical secretory pathway. Interestingly, peroxisomes were not able to reach vacuoles under pexophagy conditions in both Ain16 and Ain19 strains. Therefore, the essential role of the early secretory flow in selective macroautophagy of peroxisomes is suggested.

Peroxisome Size Provides Insights into the Function of Autophagy-related Proteins

Autophagy is a major pathway of intracellular degradation mediated by formation of autophagosomes. Recently, autophagy was implicated in the degradation of intracellular bacteria, whose size often exceeds the capacity of normal autophagosomes. However, the adaptations of the autophagic machinery for sequestration of large cargos were unknown. Here we developed a yeast model system to study the effect of cargo size on the requirement of autophagy-related (Atg) proteins. We controlled the size of peroxisomes before their turnover by pexophagy, the selective autophagy of peroxisomes, and found that peroxisome size determines the requirement of Atg11 and Atg26. Small peroxisomes can be degraded without these proteins. However, Atg26 becomes essential for degradation of medium peroxisomes. Additionally, the pexophagy-specific phagophore assembly site, organized by the dual interaction of Atg30 with functionally active Atg11 and Atg17, becomes essential for degradation of large peroxisomes. In contrast, Atg28 is partially required for all autophagy-related pathways independent of cargo size, suggesting it is a component of the core autophagic machinery. As a rule, the larger the cargo, the more cargo-specific Atg proteins become essential for its sequestration.

Receptor protein complexes are in control of autophagy

In autophagic processes a variety of cargos is delivered to the degradative compartment of cells. Recent progress in autophagy research has provided support for the notion that when autophagic processes are operating in selective mode, a receptor protein complex will process the cargo. Here we present a concept of receptor protein complexes as comprising a functional tetrad of components: a ligand, a receptor, a scaffold and an Atg8 family protein. Our current understanding of each of the four components and their interaction in the context of cargo selection are considered in turn.

Peroxisomal Atg37 binds Atg30 or palmitoyl-CoA to regulate phagophore formation during pexophagy

The acyl-CoA–binding protein Atg37 is a new component of the pexophagic receptor protein complex that regulates the recruitment of Atg11 by Atg30 in the peroxisomal membrane during pexophagy

Atg35, a micropexophagy-specific protein that regulates micropexophagic apparatus formation in Pichia pastoris

Autophagy-related (Atg) pathways deliver cytosol and organelles to the vacuole in double-membrane vesicles called autophagosomes, which are formed at the phagophore assembly site (PAS), where most of the core Atg proteins assemble. Atg28 is a component of the core autophagic machinery partially required for all Atg pathways in Pichia pastoris. This coiled-coil protein interacts with Atg17 and is essential for micropexophagy. However, the role of Atg28 in micropexophagy was unknown. We used the yeast two-hybrid system to search for Atg28 interaction partners from P. pastoris and identified a new Atg protein, named Atg35. The atg35∆ mutant was not affected in macropexophagy, cytoplasm-to-vacuole targeting or general autophagy. However, both Atg28 and Atg35 were required for micropexophagy and for the formation of the micropexophagic apparatus (MIPA). This requirement correlated with a stronger expression of both proteins on methanol and glucose. Atg28 mediated the interaction of Atg35 with Atg17. Trafficking of overexpressed Atg17 from the peripheral ER to the nuclear envelope was required to organize a peri-nuclear structure (PNS), the site of Atg35 colocalization during micropexophagy. In summary, Atg35 is a new Atg protein that relocates to the PNS and specifically regulates MIPA formation during micropexophagy.

Methods of plate pexophagy monitoring and positive selection for ATG gene cloning in yeasts.

Methods for colony assay of peroxisomal oxidases in yeasts provide a convenient and fast approach for monitoring peroxisome status. They have been used in several laboratories for the isolation of yeast mutants deficient in selective autophagic peroxisome degradation (pexophagy), catabolite repression of peroxisomal enzymes or mutants deficient in oxidases themselves. In this chapter, protocols for monitoring peroxisomal alcohol oxidase and amine oxidase directly in yeast colonies and examples of their application for mutant isolation are described. These methods were successfully utilized in several methylotrophic yeasts and the alkane-utilizing yeast Yarrowia lipolytica.

Peroxisomal Pex3 Activates Selective Autophagy of Peroxisomes via Interaction with the Pexophagy Receptor Atg30

Background: Pex3 is a docking factor for pexophagy receptors in yeast. Results: A specific domain on Pex3 is responsible for interaction and activation of the pexophagy receptor Atg30 during pexophagy. Conclusion: Pex3 regulates the initiation of pexophagy. Significance: The peroxisomal ligand of the pexophagy receptor contributes to pexophagy signaling. Pexophagy is a process that selectively degrades peroxisomes by autophagy. The Pichia pastoris pexophagy receptor Atg30 is recruited to peroxisomes under peroxisome proliferation conditions. During pexophagy, Atg30 undergoes phosphorylation, a prerequisite for its interactions with the autophagy scaffold protein Atg11 and the ubiquitin-like protein Atg8. Atg30 is subsequently shuttled to the vacuole along with the targeted peroxisome for degradation. Here, we defined the binding site for Atg30 on the peroxisomal membrane protein Pex3 and uncovered a role for Pex3 in the activation of Atg30 via phosphorylation and in the recruitment of Atg11 to the receptor protein complex. Pex3 is classically a docking protein for other proteins that affect peroxisome biogenesis, division, and segregation. We conclude that Pex3 has a role beyond simple docking of Atg30 and that its interaction with Atg30 regulates pexophagy in the yeast P. pastoris.

Atg37 regulates the assembly of the pexophagic receptor protein complex

Like other selective autophagy pathways, the selective autophagy of peroxisomes, pexophagy, is controlled by receptor protein complexes (RPCs). The pexophagic RPC in Pichia pastoris consists of several proteins: Pex3 and Pex14 ligands in the peroxisomal membrane, Atg30 receptor, Atg11, and Atg17 scaffolds, and the phagophore protein Atg8. Recently, we identified a new component of the pexophagic RPC, Atg37, which is involved in the assembly of this complex. Atg37 is an integral peroxisomal membrane protein (PMP) that binds Pex3 and Atg30, but not Pex14 or Atg8. In the absence of Atg37, the recognition of Pex3 and recruitment of Atg17 by Atg30 are normal. However, the recruitment of Atg11 is severely affected suggesting that the role of Atg37 is to facilitate the Atg30-Atg11 interaction. Palmitoyl-CoA competes with Atg30 for the acyl-CoA binding domain of Atg37 in vitro and might regulate the dynamics of the pexophagic RPC in vivo. The human counterpart of Atg37, ACBD5, also localizes to peroxisomes and is specifically required for pexophagy. Therefore, it is tempting to speculate that ACBD5/ATG37 regulates the assembly of the pexophagic RPC in mammalian cells.

Autophagy-Related Pathways and Specific Role of Sterol Glucoside in Yeasts

Recently, we showed that the requirement of sterol glucoside (SG) during pexophagy in yeasts is dependent on the species and the nature of peroxisome inducers. Atg26, the enzyme that converts sterol to SG, is essential for degradation of very large methanol-induced peroxisomes, but only partly required for degradation of smaller-sized oleate- and amine-induced peroxisomes in Pichia pastoris. Moreover, oleate- and amine-induced peroxisomes of another yeast, Yarrowia lipolytica, are degraded by an Atg26-independent mechanism. The same is true for degradation of oleate-induced peroxisomes in Saccharomyces cerevisiae. Here, we review our findings on the specificity of Atg26 function in pexophagy and extend our observations to the role of SG in the cytoplasm to vacuole targeting (Cvt) pathway and bulk autophagy. The results presented here and elsewhere indicate that Atg26 might increase the efficacy of all autophagy-related pathways in P. pastoris, but not in other yeasts. Recently, it was shown that P. pastoris Atg26 (PpAtg26) is required for elongation of the pre-autophagosomal structure (PAS) into the micropexophagic membrane apparatus (MIPA) during micropexophagy. Therefore, we speculate that SG might facilitate elongation of any double membrane from the PAS and this enhancer function of SG becomes essential when extremely large double membranes are formed. Addendum to: The Requirement of Sterol Glucoside for Pexophagy in Yeast Is Dependent on the Species and Nature of Peroxisome Inducers T.Y. Nazarko, A.S. Polupanov, R.R. Manjithaya, S. Subramani and A.A. Sibirny Mol Biol Cell 2007; 18:106-18