Oxygen-dependent asparagine hydroxylation of the ubiquitin-associated (UBA) domain in Cezanne regulates ubiquitin binding

Deubiquitinases (DUBs) are vital for the regulation of ubiquitin signals, and both catalytic activity of and target recruitment by DUBs need to be tightly controlled. Here, we identify asparagine hydroxylation as a novel posttranslational modification involved in the regulation of Cezanne (also known as OTU domain–containing protein 7B (OTUD7B)), a DUB that controls key cellular functions and signaling pathways. We demonstrate that Cezanne is a substrate for factor inhibiting HIF1 (FIH1)- and oxygen-dependent asparagine hydroxylation. We found that FIH1 modifies Asn35 within the uncharacterized N-terminal ubiquitin-associated (UBA)-like domain of Cezanne (UBACez), which lacks conserved UBA domain properties. We show that UBACez binds Lys11-, Lys48-, Lys63-, and Met1-linked ubiquitin chains in vitro, establishing UBACez as a functional ubiquitin-binding domain. Our findings also reveal that the interaction of UBACez with ubiquitin is mediated via a noncanonical surface and that hydroxylation of Asn35 inhibits ubiquitin binding. Recently, it has been suggested that Cezanne recruitment to specific target proteins depends on UBACez. Our results indicate that UBACez can indeed fulfill this role as regulatory domain by binding various ubiquitin chain types. They also uncover that this interaction with ubiquitin, and thus with modified substrates, can be modulated by oxygen-dependent asparagine hydroxylation, suggesting that Cezanne is regulated by oxygen levels.

Deubiquitinases (DUBs) 2 are essential players in the ubiquitin system. They reverse and shape ubiquitin signals and hence control the complex ubiquitin code and its cellular consequences (1). Deregulation of DUBs has been linked to a variety of diseases like cancer, neurodegeneration, and inflammatory diseases. To safeguard proper DUB function, multiple layers of regulatory mechanisms evolved in the cell, which ensure the correct abundance and localization of DUBs or directly regulate their catalytic activity (2). Among others, posttranslational modifications (PTMs) and accessory domains within DUBs are employed to control DUB function.
Cezanne (OTUD7B) is a member of the ovarian tumor protease (OTU) family, and its catalytic OTU domain targets Lys 11 -linked ubiquitin chains with high selectivity (3,4). Structural studies of the OTU domain alone and in complex with Lys 11 -linked diubiquitin suggest that Cezanne is autoinhibited in the absence of ubiquitin. The OTU domain contacts the distal molecule of all chain types via an exposed S1 site. However, an S1Ј site is not present until Lys 11 -linked diubiquitin is bound across the active site (4). These conformational rearrangements upon diubiquitin binding explain the selectivity of the OTU domain for Lys 11 -linked ubiquitin chains.
Although the structural and biochemical properties of Cezanne's catalytic OTU domain have been extensively characterized in vitro, the functional role of the additional two ubiquitinbinding domains (UBDs) and of the almost 50% of a Cezanne molecule that is predicted to be unstructured remain elusive. One study linked the C-terminal A20-type zinc finger (ZnF) to the inhibition of ligand-dependent EGF receptor degradation by Cezanne (5), and a recent publication suggested a role for the N-terminal ubiquitin-associated (UBA)-like domain in recruitment of Cezanne to activated TNF receptor complex (6). During the last decade, Cezanne has been associated with multiple cellular processes, including the regulation of NF-B (7,8), hypoxia signaling (9), mTORC2 signaling (10), and human cell cycle progression (11). Interestingly, Cezanne-dependent cleavage of ubiquitin chain types conjugated to respective substrates has not always been in accordance with former in vitro studies. Some reports have suggested that in addition to Lys 11linked polyubiquitin, full-length Cezanne can also process Lys 48 -and Lys 63 -linked ubiquitin chains in vivo (8,10). However, it is not yet understood whether Cezanne's ability to cleave linkage types other than Lys 11 in a cellular context depends on cofactors present in the cell, on an acute increase in local concentrations of Cezanne that would allow cleavage of different chain types ("proximity effect"), or on distinct regions within the full-length enzyme itself. Therefore, studying the accessory domains of Cezanne like the UBA domain (UBA Cez ) will add to our understanding of how modified substrates are discriminated by Cezanne.
UBA domains are short sequence motifs of ϳ45 amino acids that adopt a compact three-helix bundle. Like other UBDs, UBA domains recognize ubiquitinated substrates via interaction with ubiquitin and serve to decode ubiquitin signals into a cellular response (12). Originally identified in shuttle factors, UBA domains have also been found in various other proteins, including autophagy receptors, E3 ubiquitin ligases, and DUBs. For most UBA domains, an unusually large hydrophobic surface patch has been described (13). The so-called MGF motif is highly conserved and part of the connecting loop between helix ␣1 and ␣2. The MGF motif is not required to maintain the local structure of the UBA domain but contributes to the hydrophobic surface patch for interaction with ubiquitin. In addition, a dileucine motif in helix ␣3 is present in most UBA domains and involved in ubiquitin binding (13). With very few exceptions (e.g. the UBA domain of the E3 ubiquitin ligase Cbl-b (14, 15) or of the yeast protein Swa2p (16)), UBA domains engage the hydrophobic Ile 44 patch of ubiquitin via the same surface comprising MGF and LL motifs. Interestingly, the UBA domain of the autophagy receptor p62 needs to be phosphorylated to bind Lys 63 -linked ubiquitin chains with sufficient affinity and to enable p62 to act as an autophagy receptor for ubiquitinated protein aggregates (17). This observation shows that the interaction between ubiquitin and UBA domains can be regulated by PTMs.
Our work presented here demonstrates that UBA Cez is posttranslationally modified by the asparaginyl ␤-hydroxylase factor inhibiting HIF1 (FIH1) and thereby associates a novel PTM with a UBD. Interestingly, in an MS-based interactome study, FIH1 was previously identified as a binding partner of Cezanne (18). FIH1 belongs to the family of 2-oxoglutarate and Fe(II)dependent dioxygenases (19), and FIH1 is a key regulator of the cellular oxygen-sensing machinery that controls the transcriptional activity of hypoxia-inducible factor 1-␣ (HIF1␣). In the presence of oxygen, FIH1 hydroxylates a conserved asparagine residue in the C-terminal transactivation domain of HIF1␣, which blocks its interaction with the co-activator p300 (20,21) and renders HIF1␣ inactive. In addition to HIF1␣, other targets of FIH1 have been described, most of them containing a common interaction motif known as the ankyrin repeat domain (22). For example, hydroxylation of apoptosis-stimulating p53binding protein 2 (ASPP2), a regulator of apoptosis and cell polarity, impairs its association with partitioning-defective 3 homolog (PAR-3), which in turn results in relocation of ASPP2 from cell-cell contacts to the cytosol (23). Furthermore, FIH1mediated hydroxylation inhibits the ion channel transient receptor potential vanilloid 3 (TRPV3) (24) and negatively regulates the interactome of the OTU family DUB OTUB1 (25). More recently, it has been shown that invading pathogens like Legionella pneumophilia exploit host FIH1-dependent asparagine hydroxylation by recruiting FIH1 to the pathogen-containing vacuole and that hydroxylation of translocated effector proteins are indispensable for their function (26). These examples illustrate the diversity of asparagine hydroxylation signals and how the addition of one oxygen atom can modulate protein-protein interactions.
Here, we identified a putative consensus site for FIH1-dependent hydroxylation in Cezanne. We confirmed the interaction between Cezanne and FIH1 by immunoprecipitation assays and revealed that Cezanne is posttranslationally hydroxylated at Asn 35 in an FIH1-and oxygen-dependent manner, establishing Cezanne as a novel substrate for FIH1. The modified asparagine residue is part of Cezanne's UBA domain (UBA Cez ), which belongs to the conserved protein domain family "UBA_like_SF" (cd14347) (27). However, the functionality of UBA Cez has never been proven. Our work showed that UBA Cez binds polyubiquitin of different linkage types (e.g. Lys 11 , Lys 48 , Lys 63 , and linear/Met 1 ), although it lacks critical UBA domain features like the conserved MGF motif. NMR titration experiments revealed that UBA Cez binds monoubiquitin and linear diubiquitin via a noncanonical surface comprising helix ␣2 and ␣3, with K D values comparable with other described ubiquitin-UBD interactions. Importantly, hydroxylation of Asn 35 greatly reduced the interaction of UBA Cez with ubiquitin.

Cezanne harbors a FIH1 consensus site
FIH1 selectively hydroxylates asparagine residues within the LX5(D/E)⌽N⌽ motif (where ⌽ represents aliphatic amino acids) in multiple eukaryotic proteins. The addition of the strong electronegative oxygen atom to the ␤-carbon of asparagine residues increases the polarity of a protein and can act as a hydrogen bond donor and acceptor. Therefore, hydroxylation is an efficient intracellular tool to regulate protein-protein interactions (28). A global proteomic analysis of deubiquitinating enzymes and their associated protein complexes showed that FIH1 interacts with Cezanne (18). Furthermore, we identified a putative consensus site for FIH1-dependent hydroxylation in Cezanne (Fig. 1A). We have previously demonstrated that Cezanne is crucial for the HIF-dependent cellular adaptation to hypoxia and thus it interacts with the prime substrate of FIH1 (9,29). Based on these findings, we hypothesized that Cezanne is a novel substrate for FIH1.
First, we confirmed and characterized the interaction between Cezanne and FIH1. Co-immunoprecipitation experiments demonstrated that FIH1 interacts with Cezanne in HEK293 cells (Fig. 1B). Interestingly, the catalytic inactive mutant FIH1 (H199A) and the dimerization-deficient mutant FIH1 (L340R) did not bind Cezanne (Fig. 1C). In the context of HIF1␣ regulation, it has been shown that disruption of FIH1 EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding dimerization abolishes HIF1␣ binding and hydroxylation by FIH1 (30), further strengthening our hypothesis that Cezanne interacts with FIH1 as its substrate. Using truncated Cezanne variants, we mapped the minimal FIH1-binding region of Cezanne to the catalytic OTU domain (Fig. 1D). Another remarkable observation was that the interaction between Cezanne and FIH1 was lost when cells were exposed to hypoxia (1% oxygen) for 6 -8 h (Fig. 1E), a condition in which FIH1 activity is decreased. Our results suggest that Cezanne is in complex with FIH1 and that this association depends on FIH1 hydroxylase activity.

The UBA domain of Cezanne is hydroxylated by FIH1
Using SILAC-based MS, we tested whether Cezanne is indeed hydroxylated by FIH1. We generated CRISPR/Cas9-   EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding mediated FIH1 knockout (KO) HEK293 cells ( Fig. 2A) and expressed GFP-Cezanne in these cells in the absence and presence of exogenous FIH1. As additional control, Cezanne-and FIH1-expressing cells were treated with hypoxia (1% oxygen) for 16 h (Fig. 2B). Subsequently, GFP-Cezanne was immunoprecipitated using nano-traps, and peptides were generated by tryptic digest, separated by LC, and analyzed by tandem MS. Hydroxylation of Asn 35 (mass change of ϩ16 Da in the corresponding peptide) was robustly detected in the presence of FIH1 and oxygen (Fig. 2, C and D). Under hypoxic conditions, when FIH1 activity was limited, or in the absence of FIH1 protein, hydroxylation of Asn 35 was significantly reduced. Depletion of FIH1 did not change Cezanne protein level, suggesting that expression or stability of Cezanne did not depend on hydroxylation ( Fig. 2A and Fig. S1A). Moreover, there is no evidence that FIH1 is a substrate for Cezanne-mediated deubiquitination, at least Cezanne does not seem to remove proteolytic ubiquitin signals from FIH1, because Cezanne knockdown does not affect FIH1 protein level (9). In summary, our observations confirmed that the predicted FIH1 consensus site of Cezanne is recognized by the hydroxylase and that Cezanne is modified in an oxygen-and FIH1-dependent manner. Interestingly, the hydroxylated asparagine residue lies within the UBA domain of Cezanne, suggesting that asparagine hydroxylation, a PTM that has never been associated with a UBD before, may regulate the interaction between UBA Cez and ubiquitin.

Hydroxylation of Asn 35 affects UBA-ubiquitin binding
Based on our finding that UBA Cez is hydroxylated, we investigated the properties of this domain and a potential regulation of ubiquitin binding by hydroxylation in more detail. At this point, we had no evidence that UBA Cez has a direct effect on the catalytic activity of Cezanne. In vitro DUB assays showed that

EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding
the presence of UBA Cez did not alter the ability of Cezanne's catalytic OTU domain to cleave Lys 11 -linked tetraubiquitin ( Fig. S1B). Furthermore, the addition of FIH1 protein to the in vitro reaction did not affect the activity of Cezanne, excluding the possibility that interaction with FIH1 regulates Cezanne activity allosterically (Fig. S1C).
Sequence alignment of multiple UBA domains showed that UBA Cez contains neither the conserved MGF motif nor a dileucine motif (Fig. 3A), which form a hydrophobic surface patch and play an important role in ubiquitin recognition by other UBA domains (31). Also, it has never been shown in vitro that UBA Cez is a functional UBD and indeed binds ubiquitin. This is GST-Cez1-55 GST-Cez1-55_N35T GST-Cez1-55_N35F GST + + EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding more than a formality because, for example, the UBA domains of the E3 ubiquitin ligases Cbl-b and c-Cbl share a high sequence similarity, and both adopt the typical UBA fold, a compact three-helix bundle. However, only Cbl-b is able to efficiently interact with ubiquitin (14). We designed a human UBA Cez construct for recombinant expression based on the structure prediction provided by the Phyre2 server (32) (predicted UBA domain: residues 4 -49) and performed in vitro pulldown experiments. Numerous UBA domains bind polyubiquitin in strong preference to monoubiquitin, and some of them selectively bind specific linkage type(s) (12,33). To determine whether UBA Cez exhibits selectivity toward a certain ubiquitin linkage type, we compared the binding efficiency of Lys 11 -, Lys 48 -, and Lys 63 -linked tetraubiquitin. UBA Cez co-precipitated all tested ubiquitin chain types in a GSH-S-transferase (GST) pulldown experiment, which confirmed the integrity of the UBD and its ability to bind polyubiquitin (Fig. 3B).
Although our experiments suggested that UBA Cez binds Lys 63linked ubiquitin chains slightly better than the other polyubiquitin chains (Fig. 3B), this observation is likely due to the dimeric GST tag that has been shown to position two UBA domains for avid interactions with Lys 63 -linked polyubiquitin, but not other ubiquitin linkage types (33).
To investigate a potential impact of asparagine hydroxylation on the UBA Cez -ubiquitin interaction, we first created different UBA Cez mutant constructs and analyzed their ability to bind tetraubiquitin. We focused on linear (Met 1 -linked) ubiquitin chains because they are structurally very similar to Lys 63linked polyubiquitin and readily bound UBA Cez (Fig. 3C, lane  1). In contrast to lysine-linked ubiquitin chains that are conjugated via isopeptide bonds and need to be enzymatically assembled, linear ubiquitin chains can be recombinantly expressed in large quantities and allowed us further biochemical and structural analyses. Mutation of Asn 35 to a threonine residue in UBA Cez (N35T), which exhibits a hydroxyl group at its ␤-carbon similar to hydroxylated asparagine, resulted in less efficient binding to Halo-tagged tetraubiquitin as compared with the WT domain (Fig. 3C, lane 2), whereas mutation of Asn 35 to a bulky phenylalanine residue, UBA Cez (N35F), almost completely abolished interaction with ubiquitin (Fig. 3C, lane 3). Moreover, GST-tagged UBA Cez (N35T) and UBA Cez (N35F) bound and immobilized less efficiently ubiquitinated proteins from HEK293 cell lysates treated with MG132 than did WT UBA Cez (Fig. 3D).
To further explore how asparagine hydroxylation impacts ubiquitin binding, we co-expressed FIH1 and GST-tagged UBA Cez in Escherichia coli and subsequently purified the recombinant, hydroxylated UBA domain (Fig. 4A). FIH1 was able to directly modify UBA Cez at Asn 35 within the bacterial cells. Hydroxylation of purified UBA Cez was confirmed by MS (Fig. 4B). Using a GST pulldown assay, we then compared binding efficiency of linear tetraubiquitin with unmodified and hydroxylated UBA Cez , respectively. We revealed that hydroxylation of UBA Cez significantly reduced its interaction with tetraubiquitin (Fig. 4C), which confirmed the results obtained by using mutant UBA Cez (N35T) and (N35F) (Fig. 3, C and D).
Together, our data show that UBA Cez binds differently linked ubiquitin chains independent of classic UBA features and that FIH1-mediated hydroxylation of Asn 35 impairs UBA domainubiquitin binding.

The UBA domain of Cezanne interacts with ubiquitin via a unique binding mode
Our pulldown experiments suggested that UBA Cez binds ubiquitin in a noncanonical way because it lacks conserved domain properties. For further characterization of how UBA Cez interacts with ubiquitin, we performed NMR titration experiments in which nonlabeled UBA domain was titrated to 15 Nlabeled linear diubiquitin (Fig. 5, A-D). Binding of UBA Cez resulted in significant chemical shift perturbations (CSP) that were predominantly in the fast to intermediate exchange modes (Fig. 5A and Fig. S2). This corresponds to rather weak interactions between the two proteins, as typically observed for UBA domains (K D in the range of 100 M) (12). Interestingly, one-third of residues in the spectra of linear diubiquitin showed double resonances in the free form (similar to the free linear diubiquitin NMR spectra presented previously (34)), indicating a conformational nonequality of the proximal and distal ubiquitin moieties. For many residues, this nonequality was enhanced upon interaction with UBA Cez (Fig. S2). To distinguish between CSP located on the distal and proximal ubiquitin, we first mapped all CSP on the distal ubiquitin moiety, filtered out all double peaks in the spectra from the CSP mapping, and transferred them onto the proximal ubiquitin moiety to create a resulting map of CSP on linear diubiquitin (Fig. S3).
CSP mapping on the linear diubiquitin three-dimensional structure (PDB code 2W9N (35)) revealed a rather specific interface that included residues of both the distal and proximal ubiquitin, as well as the linker region (Fig. 5C). However, the absolute orientation of the binding interface could not be sufficiently resolved due to various linear diubiquitin structures available that show different angles of the orientation of both ubiquitin moieties.
To determine the binding surface of linear diubiquitin on the UBA Cez , we performed the reverse titration experiment in which nonlabeled diubiquitin was titrated to 15 N-labeled UBA Cez (Fig. 5, E-H). Most residues of UBA Cez showed CSP in the fast exchange mode. However, some residues in the domain showed CSP in the intermediate exchange with significant resonances broadening and therefore a different dynamic behavior upon interaction with linear diubiquitin. CSP sequential mapping revealed that these residues are located at the C-terminal region of UBA Cez but also included Leu 22 (Fig. 5F). Because no structure of Cezanne's UBA domain was available, we modeled a structure using protein online tools (www.proteinmodelportal.org, 3 with NMR structure of human UBA-like domain of OTUD7A as a template) and mapped the calculated CSP on this model ( Fig.  5G and Fig. S4). Surprisingly, the residues that are most affected by the interaction with linear diubiquitin were located around helices ␣2 and ␣3 of the UBA Cez and formed an extended hydrophobic area on the domain surface. Notably, Asn 35 exhibited no CSP upon the addition of linear diubiquitin (neither for backbone HN nor for side-chain NH 2 group). Our pulldown experiments showed that mutation or hydroxylation of Asn 35 affected ubiquitin binding (Figs. 3 (C and D) and 4C), indicating a potential conformational effect of these modifications, rather than an involvement in ubiquitin binding. Similar properties were observed for residues Ser 9 and Leu 10 , which were previously suggested to be involved in UBA Cez -ubiquitin interaction (6) but showed no or only minor CSP in our NMR titration experiments. The overall ubiquitin binding mode observed for UBA Cez differed significantly from other UBA domains. Most of the UBA-ubiquitin interactions studied so far indicate that ubiquitin is bound via helices ␣1 and ␣3 of UBA domains, and thus via a different surface than on UBA Cez .
To understand whether ubiquitin polymerization affects the binding of UBA Cez , we repeated the NMR experiments with monoubiquitin (Fig. S5). Monoubiquitin interacted with UBA Cez in a fast exchange mode, showing a lower affinity and absence of conformational uncertainties. Accordingly, some residues, such as Leu 8 or Ile 13 , showed intermediate exchange behavior in linear diubiquitin and fast exchange mode in monoubiquitin upon binding to UBA Cez (Fig. S5, A-D). Similar changes were observed for the interaction mode in reciprocal titration ( 15 N-labeled UBA Cez was titrated with nonlabeled linear di-or monoubiquitin). Whereas CSP for interaction between UBA Cez and linear diubiquitin were in the fast to intermediate exchange mode, the binding of monoubiquitin resulted in a fast exchange mode exclusively (Fig. S5, E-H). Additionally, some residues of UBA Cez showed a different CSP pattern (e.g. Ala 7 and Leu 22 ; Fig. S5, E and G) upon binding of either linear di-or monoubiquitin, indicating not only a difference in the binding modes, but also involvement of these residues in the specific recognition of ubiquitin chains.

EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding
Based on the NMR titration experiments, we calculated K D values for six residues of linear diubiquitin and UBA Cez upon their interaction, respectively (Fig. 5 (D and H) and Fig. S6). In both cases, global fit for all residues showed K D values of ϳ0.14 mM and was therefore in agreement with reported affinities for other UBA domains and ubiquitin. Calculated K D values for the same residues in the case of interaction between UBA Cez and monoubiquitin resulted in values between 0.26 and 0.32 mM, which are 2-fold higher than for diubiquitin (Fig. S6, A-D), indicating that ubiquitin chain polymerization does not enhance the binding affinities dramatically.
To investigate the impact of FIH1-dependent hydroxylation of UBA Cez on its capacity to bind ubiquitin, we recorded NMR spectra of the 15 N-labeled hydroxylated form of UBA Cez (Asn 35 OH) and mutant UBA Cez (N35T). Our data confirmed that neither hydroxylation nor mutation of Asn 35 in UBA Cez interferes with the overall fold of the protein (Fig. S7). However, comparison of the NMR spectra of modified and WT UBA Cez revealed that the changes in resonance position are not limited to the closest Asn 35 neighborhood but extended to a number of residues located N-and C-terminally to Asn 35 (Fig. S7, A-C). This fact suggests that Asn 35 modification affects the local structure and/or dynamics of residues in these areas and could influence binding of ubiquitin. Indeed, NMR titration experiments for UBA Cez with hydroxylated and mutated Asn 35 showed their reduced affinity to monoubiquitin (Fig. S7, D and  E).
In summary, our NMR analyses reveal that UBA Cez physically interacts with monoubiquitin and linear polyubiquitin in the absence of the well-characterized MGF motif via a noncanonical binding surface involving helices ␣2 and ␣3 of the UBA domain and that Ala 7 and Leu 22 in UBA Cez seem to participate in specific recognition of linear ubiquitin chains. However, dimerization of two ubiquitin molecules does not enhance UBA Cez affinity to the monoubiquitin moiety. Furthermore, Asn 35 is not involved in direct contacts to ubiquitin; its hydroxylation rather changes the local structure and/or dynamics of UBA Cez regions that contact ubiquitin directly. These changes reduce the affinity of UBA Cez to monoubiquitin.

Discussion
Different layers of DUB regulation have been described to ensure proper enzymatic function. PTMs, regulatory domains within DUBs, and the incorporation of DUBs into macromolecular complexes are means of both temporal and spatial control. In addition to its catalytic OTU domain, Cezanne comprises two UBDs and a nuclear localization signal, which have been suggested to regulate Cezanne's cellular localization and its recruitment to substrates (5,6,36). Furthermore, several phosphorylation sites within Cezanne have been described (37); their functions, however, remain elusive.
Here, we identify Cezanne as novel substrate for the asparaginyl ␤-hydroxylase FIH1 and determine that Cezanne is posttranslationally hydroxylated at Asn 35 within its UBA domain in an oxygen-and FIH1-dependent manner. We demonstrate that UBA Cez nonselectively binds Lys 11 -, Lys 48 -, Lys 63 -, and Met 1linked (linear) ubiquitin chains in vitro, although it lacks the classic hydrophobic ubiquitin interaction motifs described in other UBA domains. Importantly, hydroxylation of Asn 35 inhibits ubiquitin binding by UBA Cez . Our study is the first one implicating asparagine hydroxylation in the regulation of UBA domain-ubiquitin interactions.
Cezanne has been associated with multiple cellular pathways, most recently with the regulation of mitotic progression (11). Although the catalytic OTU domain of Cezanne selectively hydrolyzes Lys 11 -linked ubiquitin chains in vitro, various studies reported a Cezanne-dependent abundance of several ubiquitin linkage types in vivo (8,10). One possible explanation for this discrepancy could be proximity effects, meaning that an acute increase in local concentration of Cezanne at its substrates in response to respective stimuli could allow the DUB to hydrolyze linkage types other than Lys 11 as well. The effect of proximity consists predominantly in increasing the effective concentration of the reactants and thereby increasing the reaction kinetics and allowing reactions that would not yield products in the absence of the concentration effect (38). In accordance with this model, Cezanne readily cleaves Lys 63 -linked ubiquitin chains in vitro at higher enzyme concentrations (Fig.  S1D). The two UBDs located at the N and C terminus of Cezanne could further promote an increase in Cezanne concentra- EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding tion at its substrates by additionally binding polyubiquitin attached to substrates and/or other proteins that are in complex with Cezanne substrates. Consistent with this, it has been shown that Cezanne deubiquitinates EGFR and thereby inhibits the ligand-dependent degradation of the receptor and that the A20-like ZnF of Cezanne is essential for this effect (5). In contrast to UBA Cez , which binds ubiquitin via the classic Ile 44 patch of ubiquitin (Fig. 5B), Cezanne's ZnF interacts with the ubiquitin surface centered on Asp 58 . In the absence of the ZnF, Cezanne failed to inhibit EGFR degradation. In addition, it has been suggested that Cezanne is recruited to the activated TNFR complex via UBA Cez , where it binds Lys 63 -linked ubiquitin chains and exerts its function as a negative regulator of NF-B activation (6). Our in vitro studies confirm the ability of UBA Cez to bind Lys 63 -linked polyubiquitin and also show that UBA Cez interacts with Lys 11 -, Lys 48 -, and Met 1 -linked ubiquitin chains. Recruitment of Cezanne to and accumulation at substrates modified with ubiquitin linkage types other than Lys 11 thus appears feasible. Alternatively, Cezanne could serve to preclude unwanted assembly of Lys 11 -linked ubiquitin chains on these proteins. Furthermore, hydroxylation of UBA Cez , which impairs the ability of the domain to bind ubiquitin, could prevent nonspecific accumulation of Cezanne at ubiquitinated substrates and interacting proteins.
FIH1-dependent asparagine hydroxylation is more abundant than originally anticipated. In addition to the transcription factor HIF1␣, multiple other FIH1 substrates have been identified in the last decade. Asparagine hydroxylation mainly regulates protein-protein interactions. In the case of Cezanne, this PTM is located within its UBA domain, namely at Asn 35 . To understand the function of hydroxylation in the context of UBA Cez , we mutated Asn 35 in an attempt to mimic hydroxylation or rather to introduce spatial constraints for ubiquitin binding and observed that both threonine and phenylalanine residues at position 35 significantly reduce the interaction with ubiquitin in pulldown experiments, just as hydroxylation of Asn 35 did. Interestingly, our NMR data imply that Asn 35 is not part of the UBA Cez surface that is recognized by ubiquitin, which suggests that asparagine hydroxylation, or threonine and phenylalanine residues at position 35 within the UBA domain, probably affect the structural integrity of the domain. It has been proposed that asparagine residues are preferentially located at the N-cap position of ␣-helices, and our predicted structure of UBA Cez positions Asn 35 within this area. The N-cap residue is the first amino acid whose ␣-carbon lies approximately in the cylinder formed by the helix backbone and approximately along the helical spiral path. It is the first residue (I) whose CO group is hydrogen-bonded to the HN group of residue Iϩ4 (or sometimes Iϩ3; therefore it can also be described as the residue prior to the helix). In addition, the ␦-oxygen of asparagine residues can form a hydrogen bond to the backbone NH group of residue Asn 3 (or sometimes Asn 2 ) exposed in the first turn of the helix (39). It has been suggested that asparagine residues could help to specify the location of the helix N terminus, because it can simultaneously stabilize the first helical turn by providing an additional interaction equal to that of a residue and also discourage further helix propagation in the N-terminal direction by competing with the backbone to provide that interaction (39). It is thus likely that mutation of Asn 35 , or changing polarity of the asparagine side chain by hydroxylation of the ␤-carbon, can change the spatial organization of helix ␣3 relative to the other helices. Because UBA Cez specifically engages ubiquitin via a surface comprising helices ␣2 and ␣3, hydroxylation of Asn 35 could therefore affect ubiquitin binding, although it is not part of the direct interacting surface. Consistently, we observed by NMR titration experiments that hydroxylation of Asn 35 or its mutation reduces the affinity of UBA Cez to monoubiquitin. Furthermore, the observed differences in NMR spectra of UBA Cez (Asn 35 OH) and UBA Cez (N35T) compared with that of the WT domain confirm our hypothesis that hydroxylation of Asn 35 , a residue not part of the UBA Cez -ubiquitin binding interface, affects the conformation and/or dynamics of UBA Cez regions directly participating in ubiquitin recognition. Although calculated K D values of the UBA Cez -monoubiquitin interaction only moderately increased upon Asn 35 hydroxylation, we hypothesize that the observed drop in affinity for ubiquitin will be even more pronounced with increasing numbers of conjugated ubiquitin moieties in the chain as observed in our pulldown experiments using tetraubiquitin (Fig. 4C).
Interestingly, within the UBA domain of OTUD7A (Cezanne 2), Cezanne's closest but rather unstudied relative, there is a threonine residue at the corresponding position for Asn 35 (i.e. Thr 57 ). The UBA domain is highly conserved between Cezanne and OTUD7A. Our pulldown assays showed that a threonine residue at this position within the UBA domain strongly reduced interaction with ubiquitin. Therefore, it can be assumed that UBA OTUD7A binds ubiquitin less efficiently than UBA Cez and that the UBA domain may not contribute to OTUD7A recruitment to substrates and interacting proteins in the same way as UBA Cez . Furthermore, our group has shown that Cezanne plays an important role for proper HIF target gene expression in hypoxic condition by stabilizing HIF1␣ (9). FIH1 has a high affinity for oxygen and remains partially functional in hypoxia. An additional purpose for Cezanne hydroxylation in the context of HIF1␣ regulation could be to sequester FIH1, thereby reducing HIF1␣ CTAD hydroxylation and further promoting HIF activity.

Cell culture and transfection
HEK293 and 293T cells were obtained from Leibnitz Institute DSMZ-German Collection of Microorganisms and Cell Culture (DSMZ nos. ACC 305 and ACC 635, respectively) and grown in DMEM-GlutaMAX TM -I medium (Gibco/Life Technologies) supplemented with 10% (v/v) fetal bovine serum (Gibco/Life Technologies) and 50 units/ml penicillin and 50 g/ml streptomycin (GE Healthcare) at 37°C and 5% CO 2 . PCR-based Mycoplasma contamination tests were regularly performed using the VenorGeM Classic kit (Minerva Biolabs). Hypoxia treatment at 1% oxygen was achieved using a Whitley H35 Hypoxystation (Meintrup DWS Laborgeräte). To avoid reoxygenation, cells were lysed in the hypoxia chamber. For immunoblotting, 1 ϫ 10 6 cells/well were seeded in 6-well plates and transfected after 24 h with 1-3 g of DNA using polyeth-EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding yleneimine, 25 kDa, linear (PEI) (Polysciences Europe). For 1 g of DNA, 3 l of PEI (1 mg/ml) and 200 l of prewarmed Opti-MEM medium (Gibco/Life Technologies) were used. After transfection, cells were cultured for 24 h prior to lysis.

Co-immunoprecipitation
1 ϫ 10 6 HEK293 cell/well were seeded in 6-well plates and transfected after 24 h. GFP-tagged Cezanne constructs were co-expressed with untagged FIH1 (WT or mutants) for 24 h. Cells were washed with PBS and lysed on ice for 10 min (10 mM Tris-HCl (pH 7.5), 150 mM NaCl, 1% Triton X-100, 1 ϫ cOmplete, EDTA-free protease inhibitors (Roche Applied Science), 100 mM PMSF, 100 mM NaF). Cell debris was removed by centrifugation at 15,000 ϫ g for 10 min at 4°C. Per sample, 2-3 wells of a 6-well plate were transfected and combined after lysis. 10% of clarified lysate was taken as the input sample and mixed with 4ϫ LDS sample buffer (Invitrogen/Life Technologies) supplemented with 20 mM DTT. 10 l of GFP-Trap agarose slurry (Chromotek)/well of a 6-well plate were mixed with the clarified lysate and incubated on a rotary shaker for 1 h at 4°C. The beads were washed five times with wash buffer (10 mM Tris-HCl (pH 7.5), 150 mM NaCl, 1ϫ cOmplete, EDTA-free protease inhibitors (Roche Applied Science)). Immobilized proteins were eluted with 40 l of 2ϫ LDS sample buffer (Invitrogen/Life Technologies) supplemented with 20 mM DTT. 20 l of IP sample and 15 l of input sample were analyzed by SDS-PAGE and immunoblotting.

Antibodies
The following antibodies at the indicated concentrations were used in this study: All primary antibodies were diluted in 3% BSA (prepared in TBST, 0.05% Tween 20, and 0.05% sodium azide). Secondary antibodies were diluted in 5% nonfat dried milk (prepared in TBST).

Cloning and site-directed mutagenesis
Oligonucleotide primers were designed with the In-Fusion Cloning Primer Design Tool (Clontech) and purchased from Sigma-Aldrich. FLAG-HA-OTUD7B (a gift from Wade Harper, Addgene plasmid 22550) was used as template to amplify Cezanne/OTUD7B (full-length and truncated versions) for cloning into pEGFP-N1 mammalian expression vector and pOPINK or pETDuet-1 bacterial expression vector using the In-Fusion cloning system (In-FusionHD Cloning Kit, Clontech) according to the manufacturer's instructions. pcDNA3-FIH1 was a gift from Eric Metzen (Addgene plasmid 21399). Linear diubiquitin was purchased as an E. coli codonoptimized DNA sequence (GenScript) that was cloned into the NdeI and BamHI sites present in pET39 bacterial expression vector using T4 DNA ligase (New England Biolabs). The resulting linear diubiquitin construct included an N-terminal His 10 tag followed by a tobacco etch virus cleavage site.
Site-directed mutagenesis of Cezanne and FIH1 was performed using the QuikChange method. A 50-l reaction mix containing 40 ng of template DNA, 1ϫ Phusion HF buffer (New England Biolabs), 1 mM dNTPs, 10 pmol of forward and reverse primers containing the desired mutation(s), 3% DMSO, 0.5 l (1 unit) of Phusion High-Fidelity DNA polymerase (New England Biolabs), and autoclaved Milli-Q water was subjected to PCR using the following program: 98°C for 2 min, (98°C for 30 s; 55°C for 20 s; 72°C for 1 min/kb) ϫ 35 cycles; 72°C for 10 min, and 4°C until further processing. The PCR was incubated with 2 l of DpnI (New England Biolabs) for 2 h at 37°C, and the amplified plasmid was purified using the QIAQuick gel extraction kit (Qiagen). Stellar TM competent cells (Clontech) were transformed using the purified plasmid. Successful mutation was verified by SANGER sequencing (Microsynth SeqLab).
Complementary oligonucleotides were annealed for 5 min at 95°C and subsequently cooled down for 15 min at room temperature. Annealed primers were diluted to 0.5 M in nucleasefree water and cloned into pLentiCRISPRv2 via BsmBI restriction enzyme (New England Biolabs) digest and subsequent ligation with T4 DNA ligase (New England Biolabs). Stellar TM competent cells (Clontech) were transformed with the ligation EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding reaction, and correct clones were identified by SANGER sequencing (Microsynth SeqLab) using the U6 primer.

Generation of high-titer lentivirus and viral transduction
7.5 ϫ 10 5 HEK293T cells were seeded into a 6-well plate and cultivated in DMEM without antibiotics 24 h prior to transfection. Cells were transfected with Lipofectamine 2000 (Invitrogen/Life Technologies) by mixing the reagent with 200 l of Opti-MEM and 3.3 g of transfer vector containing the gRNAs (pLentiCRISPRv2), 2.7 g of PAX2 (a gift from Didier Trono, Addgene plasmid 12260), and 1 g of pMD2.G (a gift from Didier Trono, Addgene plasmid 12259). The transfection mix was incubated for 30 min at room temperature and afterward dropwise added to HEK293T cells. Medium was replaced with fresh DMEM containing 10% (v/v) fetal bovine serum (Gibco/ Life Technologies) and 50 units/ml penicillin and 50 g/ml streptomycin (GE Healthcare) 12 h after transfection. Supernatant containing lentiviral particles was collected after 24 and 48 h. Supernatants were pooled and frozen at Ϫ80°C.
For viral transduction, supernatants have been thawed at room temperature, sterile-filtered through 0.45-m filters, and mixed with 10 g of Polybrene (Sigma-Aldrich) to infect 1 ϫ 10 6 HEK293 cells. Stable transduced cells were selected with puromycin, and the efficiency of FIH1 knockout was confirmed by immunoblotting using antibody against FIH1.

Protein expression and purification
All proteins were expressed in Rosetta TM (DE3) competent cells (Novagen). Respective cultures were grown at 37°C until A 600 of 0.6 was reached. Protein expression was induced with 0.2-0.5 mM isopropyl ␤-D-thiogalactopyranoside (IPTG) overnight at 25°C. Bacterial cultures were harvested by centrifugation and flash-frozen in liquid nitrogen. Bacterial pellets were thawed and cells were lysed by using a French press (Therma Electron). Lysis buffer for purification via His tag contained 500 mM sodium chloride, 50 mM sodium phosphate, 1 mg/ml lysozyme, 1 mg/ml DNase, 100 mM PMSF, 5 mM imidazole, 1ϫ cOmplete, EDTA-free protease inhibitors (Roche Applied Science). Lysis buffer for purification via GST tag contained 270 mM sucrose, 50 mM Tris-HCl, 1 mg/ml lysozyme, 1 mg/ml DNase, 100 mM PMSF, 1ϫ cOmplete, EDTA-free protease inhibitors (Roche Applied Science). Cell lysates were cleared by centrifugation and filtered through a 0.45-m syringe filter. The supernatant was either applied onto a 5-ml HiTrap TM TALON crude column (GE Healthcare) using the ÄKTA Pure 25 system or transferred into a glass chromatography column containing equilibrated GSH Sepharose TM 4B (GE Healthcare). For site-specific cleavage of the GST tag, immobilized fusion proteins were incubated with 30 mM PreScission protease (GE Healthcare) at 4°C for 16 h. For purification of GST-tagged proteins, immobilized fusion proteins were eluted from GSH Sepharose TM 4B (25 mM Tris (pH 8.0), 150 mM NaCl, 25 mM GSH reduced). Proteins were further purified using a Superdex TM 75 10/300 GL size-exclusion chromatography column (GE Healthcare) equilibrated in 25 mM Tris-HCl (pH 7.5), 150 mM NaCl. Purified proteins were concentrated using Amicon Ultra-4 concentrators (Millipore).
For NMR experiments, proteins were expressed in Luria-Bertani or M9 medium containing the 15 N-labeled NH 4 Cl and 13 C-labeled glucose. For expression of the UBA domain, Rosetta TM (DE3) competent cells (Novagen) were transformed with pOPINK-Cezanne (residues 1-55). Protein expression was induced with 0.25 mM IPTG for 12 h at 25°C. For monoubiquitin and linear diubiquitin expression, T7 Express cells (New England Biolabs) were transformed with corresponding pET39 plasmids, induced with 0.2 mM IPTG, and harvested after 4 h of incubation at 37°C. Monoubiquitin and linear diubiquitin were purified according to previous work (41). Protein samples were equilibrated in buffer containing 25 mM HEPES (pH 7.5), 50 mM NaCl, 5% D 2 O prior to NMR experiments.

Pulldown (PD) assays
For GST pulldown experiments, equal amounts of GST and GST-tagged UBA domain were immobilized on GSH Sepharose TM 4B (GE Healthcare). After incubation for 1 h at 4°C on a rotary shaker, beads were washed two times with PD buffer (150 mM NaCl, 50 mM Tris (pH 7.5), 5 mM DTT, 0.1% Nonidet P-40). Subsequently, 3 g of differently linked tetraubiquitin chains were applied to coupled GST or GST-UBA beads in PD buffer containing 0.5 g of BSA. Ubiquitin chains were incubated overnight at 4°C on a rotary shaker. The next day, beads were washed five times with PD buffer and eluted with 4ϫ LDS sample buffer (Invitrogen) supplemented with 20 mM DTT and boiled for 2 min at 95°C.
For semi-in cellulo experiments, equal amounts of GST and GST-tagged UBA domain were immobilized on GSH beads. After incubation for 1 h at 4°C on a rotary shaker, beads were washed two times with PD buffer (150 mM NaCl, 50 mM Tris (pH 7.5), 5 mM DTT, 0.1% Nonidet P-40). Subsequently, cell lysate from 293 cells (three wells of a 6-well plate were combined) treated for 2 h with 20 M MG132 was applied to coupled GST and coupled GST-UBA beads and incubated for 2 h on a rotary shaker at 4°C. Beads were washed five times with PD buffer and eluted with 4ϫ LDS sample buffer (Invitrogen) supplemented with 20 mM DTT and boiled for 2 min at 95°C.
For HaloTag pulldown experiments, 100 l of HaloTag bead (Promega) suspension was incubated with 300 g of Halotagged protein (Halo-linear tetraubiquitin or HaloTag alone) in Halo resin buffer (150 mM NaCl, 100 mM Tris (pH 7.5), 0.05% Nonidet P-40) at 4°C for 1 h at room temperature. Input (before incubation) and supernatant (after incubation) samples were analyzed with SDS-PAGE followed by Instant Blue (Expedeon) staining to analyze whether beads were equally saturated with Halo-tagged protein. Beads were washed three times with Halo resin buffer. 2.5 g of GST or GST-UBA protein were incubated for 1 h at 4°C on a rotary shaker with immobilized Halo-protein. Afterward, beads were washed three times with Halo resin buffer and spun down at 800 ϫ g for 5 min. Proteins were eluted with 2ϫ LDS sample buffer (Invitrogen) supplemented with 20 mM DTT and boiled for 5 min at 95°C.

In vitro Cezanne DUB assay
Cezanne  or Cezanne(129 -449) was diluted in 10 l of DUB dilution buffer (25 mM Tris-HCl (pH 7.5), 150 mM NaCl, 10 mM DTT) and preincubated for 10 min at room EDITORS' PICK: Cezanne hydroxylation and ubiquitin binding temperature. 1 g of differently linked tetraubiquitin chains or diubiquitin was prepared in 10 l of 10ϫ DUB reaction buffer (500 mM Tris-HCl (pH 7.5), 500 mM NaCl, 50 mM DTT). To start the hydrolysis reaction, DUB and substrate were mixed in a 1:1 ratio and incubated at 37°C for the indicated times. Reactions were stopped by adding 4ϫ LDS sample buffer (Invitrogen/Life Technologies) supplemented with 20 mM DTT and boiled for 30 s at 95°C. Samples were analyzed by SDS-PAGE on 4 -20% gradient precast or 15% self-made gels and visualized by silver staining (Silver Stain Plus Kit, Bio-Rad).