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The deubiquitinase USP32 regulates non-proteolytic ubiquitination in the endosomal-lysosomal system
(2021)
The regulation of essential cellular processes requires tightly controlled and directed transport of proteins and membranes. The highly dynamic endosomal and lysosomal system forms the key network for exchange and trafficking of molecules with its early endosomes, recycling endosomes, late endosomes, lysosomes, and additionally autophagosomes.
In this system, the small GTPase Rab7 has an essential role at the late endosomal stage regulating vesicle transport, tethering, and fusion, and retromer mediated receptor recycling back to the trans-Golgi network (TGN). Thus, Rab7 is also important for autophagosomes and lysosomes.
Lysosomes do not only represent the end point of the degradation pathway with several feeder pathways. But these organelles are also a dynamic signaling hub for a variety of metabolic processes. The ever-important regulator of cellular biosynthetic pathways mTORC1 dynamically associates with lysosomes where it is activated. mTORC1 activation is a complex multi-step process where a series of signaling events converge in dependence of amino acid levels thereby enabling interactions between the lysosomal v-ATPase, Ragulator complex (consisting of LAMTOR1-5), and Rag GTPases.
Ubiquitin signals are involved in almost all cellular processes. With this, their regulatory mechanism is also described for the endosomal-lysosomal system as well as mTORC1 signaling. Deubiquitinases (DUBs) release conjugated ubiquitin from proteins and thereby maintain the dynamic state of the cellular ubiquitinome.
The ubiquitin-specific protease 32 (USP32) is a poorly characterized DUB with only emerging cellular function. However, its predicted domain structure includes two unique domains within the entire DUB family. It has been linked to the development of breast cancer and small cell lung cancer. Furthermore, overexpressed GFP-USP32 was localized at the TGN, and a global mass spectrometry-based DUB interactome study suggested an interaction with the retromer complex. Based on these data, USP32 was a very interesting candidate to study its cellular function in this PhD project.
To investigate the function without disease background, a polyclonal USP32 knockout (USP32KO) RPE1 cell line was generated using the CRISPR/Cas9 technology. First experiments revealed different protein expression levels in various cell lines, and a subcellular localization of USP32 at membranes of the Golgi and lysosomal compartments. In a subsequent SILAC-based ubiquitinome analysis potential substrates of USP32 were identified. Interestingly, various proteins of the endosomal-lysosomal system were detected with enriched non-proteolytic ubiquitination upon USP32 depletion.
The further characterization of Rab7 as USP32 substrate confirmed the USP32-sensitive ubiquitination of Rab7 at lysine (K) residues 191 and 194. The ubiquitination in USP32KO cells did not change the subcellular localization of Rab7, but enhanced the interaction with the effector protein RILP. This implied that Rab7 was either more active or RILP had higher affinity to ubiquitinated Rab7. The subsequent results verified this theory. The retromer mediated recycling of CI-M6PR back to the TGN was faster or more efficient in USP32-depleted cells.
Accompanying this, levels of hydrolases were enriched in lysosomes isolated from USP32KO cells. Notably, USP32 had no direct effect on expression level or assembly of the retromer complex itself.
The observed lysosomal phenotypes connected another identified substrate to the function of USP32 in the endosomal-lysosomal system: LAMTOR1. LAMTOR1 is a component of the Ragulator complex and thus involved in the activation of mTORC1 at the lysosomal surface. Similar as for Rab7, the first experiments to characterize LAMTOR1 as USP32 substrate confirmed the USP32-sensitive ubiquitination at K20 independent of amino acid availability. However, ubiquitination of LAMTOR1 decreased its lysosomal localization in untreated and amino acid starved USP32KO cells. The following label-free interactome study detected a reduced interaction of LAMTOR1 and subunits of the lysosomal v-ATPase upon loss of USP32. This resulted in a shifted subcellular localization of mTOR (subunit of mTORC1) away from lysosomes. Furthermore, direct substrates of mTORC1 were less or slower re-phosphorylated after long amino acid starvation and re-activation of mTORC1 in USP32KO cells indicating a reduced mTORC1 activity.
Both USP32-dependent regulations of Rab7 and LAMTOR1/Ragulator converged in enhanced autophagic processes analyzed by increased LC3 levels upon amino acid starvation and USP32 depletion.
In summary, the presented thesis described the diverse role of USP32 in the endosomal and lysosomal system, and contributes to the understanding of novel ubiquitin signals in this context.
Autophagy, together with the ubiquitin-proteasome system, is the main quality control pathway responsible for maintaining cell homeostasis. There are several types of autophagy distinguished by cargo selectivity and means of induction. This thesis focuses on macroautophagy, hereafter autophagy, where a double-layered membrane is formed originating from the endoplasmatic reticulum (ER) engulfing cargo selectively or unselectively. Subsequently, a vesicle forms around the cargo, an autophagosome, and eventually fuses with the lysosome leading to degradation of the vesicle content and release of the cargo “building blocks”. Basal autophagy continuously occurs, unselectively engulfing a portion of the cytoplasm. However, autophagy can also be induced by stress such as starvation, protein aggregation, damaged organelles, intracellular pathogens etc. In this case, the cargo is selectively targeted, and the fate of the autophagosome is the same as in basal autophagy. In recent years, interest in identifying mechanisms of autophagy regulation has risen due to its importance in neurodegenerative diseases and cancer. Given the complexity of the process, its execution is tightly regulated from initiation, autophagosome formation, expansion, closure, and finally fusion with the lysosome. Each of the steps involves different protein complexes, whose timely activity is orchestrated by post-translational modifications. One of them is ubiquitination. Ubiquitin is a small, 76-amino acid protein conjugated in a 3-step reaction to other proteins, in a reversible manner, meaning undone by deubiquitinases. Originally described as a degradation signal targeting proteins to the proteasome, today it is known it has various additional non-proteolytic functions, such as regulating a protein’s activity, localization, or interaction partners. The role of ubiquitin in autophagy has already been shown. However, given the reversibility and fine-tuning of the ubiquitin signal, many expected regulators remain unidentified. This work aimed to identify novel deubiquitinating enzymes that regulate autophagy. We identified ubiquitin-specific protease 11 (USP11) as a novel, negative regulator of autophagy. Loss of USP11 leads to an increase in autophagic flux, whereas overexpression of USP11 attenuates it. Moreover, this observation was reproducible in model organism Caenorhabditis elegans, emphasizing the importance of USP11 in autophagy regulation. To identify the mechanism of USP11-dependent autophagy regulation, we performed a USP11 interactome screen after 4 hour Torin1 treatment and identified a plethora of autophagy-related proteins. Following the most prominent hits, we have investigated versatile ways in which USP11 regulates autophagy. USP11 interacts with the PI3KC3 complex, the role of which is phosphorylating lipids of the ER, thereby initiating the formation of the autophagosomal membrane. Phosphorylated lipids serve as a recruitment signal for downstream effector proteins necessary for the membrane expansion. The core components of the complex are VPS34, the lipid kinase, ATG14, the protein responsible for targeting the complex to the ER, VPS15, a pseudokinase with a scaffolding role, Beclin1, a regulatory subunit, and NRBF2, the dimer-inducing subunit. We have found USP11 interacts with the complex and, based on its activity, USP11 influences post-translational status of all the aforementioned subunits, except for ATG14. Moreover, we have found that loss of USP11 leads to an increase in NRBF2 levels, whereas it does not change the levels of the other proteins. Given that the dimerization of the complex leads to an increase in complex activity, we investigated if the complex is more tightly formed in the absence of USP11, and if it is more active. We have found both to be the case. Although the exact mechanism of USP11-dependent PI3KC3 complex regulation remains to be identified, we found that loss of USP11 stimulates the complex formation and activity, likely contributing to the general effect of USP11 on autophagy flux. Additionally, we found that USP11 modulates levels of mTOR, the most upstream kinase in autophagy initiation steps and general multifaceted metabolism regulator. Loss of USP11 led to downregulation of mTOR levels, suggesting USP11 may rescue mTOR from proteasome-mediated degradation. Furthermore, we found mTOR to be differentially modified depending on the activity of USP11. However, it remains to be shown if USP11-dependent mTOR regulation contributes to the observed autophagy phenotype. Taken together, USP11 is a novel, versatile, negative regulator of autophagy, and an important addition to our knowledge on the regulation of autophagy by the ubiquitin system.