Functional Implications of O-GlcNAcylation-dependent Phosphorylation at a Proximal Site on Keratin 18*

Keratins 8/18 (K8/18) are phosphoglycoproteins and form the major intermediate filament network of simple epithelia. The three O-GlcNAcylation (Ser29, Ser30, and Ser48) and two phosphorylation (Ser33 and Ser52) serine sites on K18 are well characterized. Both of these modifications have been reported to increase K18 solubility and regulate its filament organization. In this report, we investigated the site-specific interplay between these two modifications in regulating the functional properties of K18, like solubility, stability, and filament organization. An immortalized hepatocyte cell line (HHL-17) stably expressing site-specific single, double, and triple O-GlcNAc and phosphomutants of K18 were used to identify the site(s) critical for regulating these functions. Keratin 18 mutants where O-GlcNAcylation at Ser30 was abolished (K18-S30A) exhibited reduced phosphorylation induced solubility, increased stability, defective filament architecture, and slower migration. Interestingly, K18-S30A mutants also showed loss of phosphorylation at Ser33, a modification known to regulate the solubility of K18. Further to this, the K18 phosphomutant (K18-S33A) mimicked K18-S30A in its stability, filament organization, and cell migration. These results indicate that O-GlcNAcylation at Ser30 promotes phosphorylation at Ser33 to regulate the functional properties of K18 and also impact cellular processes like migration. O-GlcNAcylation and phosphorylation on the same or adjacent sites on most proteins antagonize each other in regulating protein functions. Here we report a novel, positive interplay between O-GlcNAcylation and phosphorylation at adjacent sites on K18 to regulate its fundamental properties.

There is no consensus sequence for O-GlcNAc modification. However, it is often observed on the same or proximal Ser/Thr residues that are used for phosphorylation, thereby negatively regulating phosphorylation (23). These two modifications can regulate each other by competitively blocking the site (34), sterically hindering the addition at an adjacent or proximal site (26), or by influencing their respective enzymes (35,36). This type of reciprocal interplay between O-GlcNAcylation and phosphorylation to regulate protein functions is observed on several proteins, including intermediate filaments like neurofilaments (neurofilament-M) and cytoskeleton-associated proteins like Tau (37,38). With recent advances in mass spectrometry, more complex and extensive cross-talk between O-GlcNAcylation and phosphorylation on many cellular proteins has been discovered (36).
Although O-GlcNAcylation (gSer 29 , 5 gSer 30 , and gSer 48 ) (39) and phosphorylation (Ser(P) 33 and Ser(P) 52 ) (5,40) occur at proximal sites on keratin 18, their mutual interplay in regulating its functional properties is largely unexplored. In our previous report, we showed that total O-GlcNAcylation on keratins 8/18 can regulate solubility, filament organization, and stability (17). In this study, we aim to understand the site-specific role of K18 O-GlcNAcylation in regulating proximal phosphorylation and functional properties. Using a panel of site-specific O-GlcNAcylation and phosphorylation mutants of K18 along with antibodies that can detect site-specific phosphorylation, we demonstrate that these two modifications exhibit substantial cross-talk at proximal sites on K18 to regulate solubility, stability, and filament organization and also cellular processes such as migration. We also uncover a novel role for O-GlcNAcylation to promote phosphorylation at proximal sites. These findings represent the first detailed characterization of site-specific interplay between O-GlcNAcylation and phosphorylation of intermediate filament protein along with identification of a unique, phosphorylation-promoting role for O-GlcNAcylation.
Cell Culture-The HHL17 cell line was routinely cultured and maintained in DMEM containing 0.03% glutamine, 10 units/ml penicillin G-sodium, 10 g/ml streptomycin sulfate, 25 g/ml amphotericin B, and 10% FBS at 37°C and 5% CO 2 . For different drug/inhibitor treatments, cycloheximide, PUGNAc, and okadaic acid were used at concentrations of 200 M/ml, 100 M/ml, and 400 nM/ml, respectively, for various times.
Plasmids, Site-directed Mutagenesis, Cloning, and Stable Expression-Human K18 WT-YFP cDNA (a gift from Dr. Rudolf Leube and Dr. Reinhard Windoffer, Johannes Gutenberg University) and K18 O-GlcNAcylation triple mutant (TM) (S29A/S30A/S48A) cDNA (a gift from Prof. Bishr Omary, Michigan Medical School) were used to generate site-specific (Ser-to-Ala) single and double O-GlcNAc mutants of K18 using the QuikChange II site-directed mutagenesis kit according to the protocol of the manufacturer. K18-WT and all mutants were further cloned into EYFP-lentiviral vector (42). Using the QuikChange II site-directed mutagenesis kit, K18-S33A, K18-S52A, K18-S33D, and K18-S30A/S33D were generated from EYFP-K18-WT cloned in the lentiviral vector. The primers used for site-directed mutagenesis are listed in supplemental Table 1.
Infectious lentivirus to express K18-WT and various mutants was produced as described previously (42). To generate K18-WT and various K18 mutants expressing stable cell lines, HHL-17 cells were infected with infectious lentivirus in the presence of Polybrene (8 g/ml) at 80 -90% confluence. After infection (24 h), stable cells expressing the transgene were selected and maintained in complete medium containing puromycin (0.8 g/ml).
Protein Isolation and Immunoblotting-Total cell lysates were prepared by solubilizing HHL17 cells in 2% SDS cell lysis buffer (62.5 mM Tris and 2% SDS (pH 6.8)). Differential extraction of soluble and filamentous keratin was performed as described in Ref. 17. In brief, soluble keratins were extracted by resuspending cells in phosphate-buffered saline containing 1% Nonidet P40, 5 mM EDTA, protease inhibitor mixture (1 mM phenylmethylsulfonyl fluoride, 10 M leupeptin, 10 M pepstatin, and 25 g/ml aprotinin), and phosphatase inhibitor mixture for 20 min at 4°C, followed by centrifugation (16,000 ϫ g, 1 h.). The supernatant was collected as the soluble fraction, and the resulting insoluble pellet was solubilized in 2% SDS cell lysis buffer (pellet). Proteins from total, soluble, and insoluble lysates in 1ϫ Laemmli sample buffer were resolved on 12% SDS-PAGE, transferred to PVDF membranes, and probed with antibodies as indicated. Membranes were washed three times with Tris-buffered saline (20 mM Tris and 500 mM NaCl (pH 7.5)) containing 0.1% Tween 20 for 30 min, incubated with antimouse or anti-rabbit secondary antibodies coupled to horseradish peroxidase, and visualized using enhanced chemiluminescence. After Western blotting, the membrane was stained with Coomassie Brilliant Blue R-250, which served as a control for equal loading. For immunoprecipitation, cells were lysed in phosphate buffer (PBS (150 mM NaCl and 10 mM phosphate (pH 7.4)) containing 2% Empigen, phosphatase, and protease inhibitor mixture, followed by immunoprecipitation as described in Ref. 17.
Purification of the Glycosylated Form of K8 and 18 -To differentially extract cellular K8 and K18 fractions, total cell lysates were resolved on 10% PAGE along with a prestained protein ladder. After electrophoresis, the gel was incubated in 4 M sodium acetate solution for 2 h at Ϫ20°C. Proteins in the gel can be visualized as clear transparent bands against the white opaque gel because of precipitation of free SDS in the gel. The protein bands in the region of K8 (52 kDa) and keratin 18 (48 kDa) were separately collected in microcentrifuge tubes by excising the gel with reference to standard molecular weight markers. The gel pieces were crushed in 500 l of extraction buffer (0.5% SDS, 150 mM NaCl, and 62.5 mM Tris (pH 6.8)), and the tubes were vortexed vigorously for 45 min at room temperature. Following this, the samples were centrifuged for 5 min at 10,000 ϫ g, and the supernatant was collected into a fresh tube. SDS from the extracted samples was removed by adding 150 mg of activated SM-2 Biobeads, followed by incubation at room temperature for 2 h with gentle rocking. The sample was centrifuged at 2000 ϫ g for 5 min at room temperature to pellet the SM-2 Biobeads, and the supernatant containing cellular fractions of either keratin 8 or 18 was collected and stored at Ϫ20°C. O-GlcNAcylated proteins from these fractions were extracted using WGA-Sepharose beads as described previously (17). Glycosylated K8 and 18 from these samples were immunoprecipitated using K8-and K18-specific monoclonal antibodies as described previously (17).
Scratch Healing Assay-For wound healing assays, 6-well culture dishes were coated overnight with 10 g/ml fibronectin in serum-free DMEM at 4°C. HHL17 cells stably expressing O-GlcNAcylation and phosphorylation site-specific mutants were seeded at a density of 1 million cells/ml of complete medium and incubated at 37°C for 24 h in a CO 2 incubator. The cells were serum-starved for 24 h for inhibiting cell proliferation. A straight, uniform wound (ϳ400 m in width) was made using a micropipette tip on the monolayer, and the cells were maintained in serum-free DMEM. The wound closure of cells in response to the immobilized fibronectin was measured for 25 h by time-lapse imaging of at least three different positions across the length of the wound using a Carl Zeiss inverted microscope at ϫ10 magnification.
Densitometry Quantitation and Statistical Analysis-Densitometric quantitation of scanned images was performed by ImageJ 1.43 software (National Institutes of Health). Band intensities were normalized to respective loading controls. Statistical analysis was performed using GraphPad Prism 5. Significance was analyzed by unpaired Student's t test for two samples and two-way analysis of variance for grouped data. *, p Ͻ 0.05; **, p Ͻ 0.01; and ***, p Ͻ 0.001 were considered significant. Photoshop (CS2, Adobe) was used for preparing the figures.

Phosphorylation-induced Solubility of Keratin 18 Is Dependent on Its O-GlcNAcylation at Serine 30 -Because both
O-GlcNAcylation and phosphorylation on keratin 18 are known to increase its solubility (17), we investigated whether perturbing keratin 18 O-GlcNAcylation alters its phosphorylation-dependent solubility. For this purpose, we generated stable lines of HHL17 cells expressing various O-GlcNAcylation and phosphorylation mutants of K18, as depicted in Fig. 1A. The expression of the YFP-tagged K18 transgene in these stable lines was confirmed by immunofluorescence and immunoblotting (data not shown). To assess phosphorylation-induced solubility, we treated stable cell lines with OA, a broad-spectrum phosphatase inhibitor that increases phosphorylation and thereby the solubility of keratin 8/18 filaments. OA treatment led to a notable increase in solubility of K18-WT, whereas the solubility of K18-TM (S29A/S30A/S48A) was unaltered (Fig. 1, B and C). Similarly, stable HHL17 cells expressing K18-S29A and K18-S48A mutants exhibited an increase in solubility, whereas mutation of Ser 30 prevented OA-induced solubility of K18 (K18-S30A) (Fig. 1, D and E), similar to the triple O-GlcNAc mutant of K18 (Fig. 1, B and C). This suggests that phosphorylation-induced solubility of K18 is dependent on its O-GlcNAcylation at Ser 30 .
O-GlcNAcylation at Serine 30 Regulates the Stability of K18 -O-GlcNAcylation of keratin 18 reduces its stability by mediating ubiquitination-dependent proteasomal degradation (17). Because disassembly and sequestration of keratin 18 subunits into a soluble pool could be a prerequisite for its degradation (43), we predicted that K18 O-GlcNAcylation at serine 30 could target it for degradation and reduce its stability. The sta-bility of the WT and various K18 O-GlcNAcylation mutants was assessed after inhibiting protein synthesis with cycloheximide. Compared with K18-WT, which shows a significant reduction upon CHX treatment, the level of K18-TM remained unchanged (Fig. 2, A and B). It was interesting to note that, among all K18 O-GlcNAc mutants, those that harbored S30A were highly stable with an unaltered protein level upon cycloheximide treatment (Fig. 2, C-F). To test whether increasing O-GlcNAcylation at Ser 30 could reduce the stability of K18, K18-WT and various O-GlcNAc mutant-expressing cells were treated with PUGNAc, a potent O-GlcNAcase inhibitor. PUGNAc treatment is known to cause increased O-GlcNAcylation and subsequent degradation of K8/18 (17). However, K18-TM, which lacks all sites of glycosylation, exhibited resistance to PUGNAc-mediated degradation (data not shown) (17). Both K18 mutants with the S30A mutation (K18-TM and K18-S30A) exhibited no reduction upon PUGNAc treatment, whereas K18 with Ser 30 (K18-WT, K18-S29A, and K18-S48A) showed a marked reduction in protein levels (Fig. 2, G-J). These results conclusively indicate that O-GlcNAcylation specifically at Ser 30 determines the stability of K18.

O-GlcNAcylation and Phosphorylation Exhibit Both a Cooperative and Antagonistic Relationship at Proximal Sites on
K18 -Both O-GlcNAcylation and phosphorylation on keratin 18 correlate positively with solubility (17). To address whether these two modifications on keratin 18 exhibit cross-talk or act independently to regulate K18 properties, we first investigated whether these two modifications coexist on K18. To achieve this, keratin 8 and keratin 18 were separated, purified, and renatured from preparative SDS-PAGE gels (as described under "Experimental Procedures"). The purified K8 and K18 fractions were clean, with no detectable cross-contamination of keratin 8 and 18 isoforms (Fig. 3A). O-GlcNAcylated proteins from these fractions were purified on WGA beads, followed by immunoprecipitation to enrich O-GlcNAcylated K8 and K18. Purified O-GlcNAcylated K8 and K18 showed notable levels of phosphorylation (Fig. 3B), suggesting co-existence of these two modifications on K8 and K18. We further aimed to investigate the relationship/cross-talk between these two modifications on K18 by assessing the levels of site-specific phosphorylation (Ser(P) 33 and Ser(P) 52 ) on various O-GlcNAc mutants of K18. The site-specific K18-Ser(P) 33 and K18-Ser(P) 52 phosphoantibodies have been reported previously (5,40). The specificity of K18-Ser 33 phosphoantibody was further confirmed using cells expressing phosphorylation mutants of K18 (K18-S33A and S52A) (data not shown). K18-TM showed a significant reduction in basal levels of Ser(P) 33 , whereas the levels of Ser(P) 52 were notably higher compared with K18-WT (Fig. 3, C-E), suggesting that O-GlcNAcylation on K18 exhibits a cooperative relationship with Ser(P) 33 and a reciprocal relationship with Ser(P) 52 . The existence of an inverse relationship between gSer 48 and Ser(P) 52 (Fig.  4, A and B). This PUGNAc-mediated increase in Ser(P) 33 levels was seen only in K18 mutants where Ser 30 O-GlcNAcylation site was available, viz. K18-S29A and K18-S48A (Fig. 4, C and  D). These results confirm that O-GlcNAcylation of K18 at Ser 30 can positively influence phosphorylation at Ser 33 . Because the dynamics of phosphorylation are regulated by the activities of specific kinases and phosphatases acting on that site, we predicted that inhibition of phosphatases by OA could restore Ser(P) 33 levels in K18-S30A mutants. OA treatment led to a notable increase in Ser(P) 33

levels on K18-WT and K18
O-GlcNAc mutants where Ser 30 O-GlcNAcylation can occur, viz. K18-S29A and K18-S48A (Fig. 4, E and F). This suggests that O-GlcNAcylation of K18 at Ser 30 is essential for the occurrence of phosphorylation at serine 33. We aimed to further investigate whether this cooperativity is mutual, with Ser(P) 33 regulating O-GlcNAcylation at Ser 30 . To address this, we used stable cells where the K18 mutant can be O-GlcNAcylated only at serine 30 (K18-S29A/S48A) because antibodies recognizing site-specific O-GlcNAcylation on keratin 18 are not available. It was interesting to note that treating these cells with OA led to an increase in Ser(P) 33 with no notable change in O-GlcNAcylation at serine 30 (Fig. 4, G and H). This suggests that the cooperative interplay between modifications at these two sites is one-sided, with gSer 30 acting as an upstream switch for phosphorylation at Ser 33 .
O-GlcNAcylation-mediated Phosphorylation of Keratin 18 at Serine 33 Regulates Its Stability-Because O-GlcNAcylation at Ser 30 induces solubility and subsequent degradation of K18 along with increased phosphorylation at Ser 33 (Figs. 1-4), it is possible that Ser(P) 33 mediates the effect of gSer 30 on the solubility and stability of K18. Although phosphorylation at Ser 33 has been shown previously to regulate solubility (5, 45) and shear stress-induced reorganization of keratin 8/18 filaments (14), its role in regulating the stability of keratin 18 is still unclear (46). To investigate the role of site-specific phosphorylation on K18 in regulating its stability, cells expressing K18-WT and phosphorylation mutants (K18-S33A and K18-S52A) were treated with cycloheximide. Although K18-WT and K18-S52A exhibited reduced K18 levels upon cycloheximide treatment, the protein levels of K18-S33A remained unchanged, suggesting a role for Ser(P) 33 in regulating the stability of K18 (Fig. 5, A and B). It is possible that O-GlcNAcylation at serine 30 can influence the stability of K18 either directly by aiding ubiquitination or indirectly by stabilizing Ser(P) 33 , which would lead to increased solubility and subsequent degradation. To understand this, stable cells expressing K18 phosphorylation mutants (K18-S33A and K18-S52A) were treated with PUGNAc to increase O-GlcNAcylation on K18. PUGNAc treatment led to reduced levels of K18-S52A but not K18-S33A (Fig. 5, C and D). These results indicate that O-GlcNAcylation at Ser 30 regulates the solubility and stability of keratin 18 mainly by stabilizing Ser(P) 33 . To confirm this, we assessed the stability of K18 after rescuing the phosphorylation at Ser 33 by substituting with a phosphomimetic mutation (S33D). However, both K18-S33D and K18-S30A/ S33D showed higher stability, as assessed by cycloheximide treatment, suggesting that S33D does not substitute for phosphorylation at Ser 33 and therefore could not rescue the enhanced stability of K18 upon loss of phosphorylation at Ser 33 (Fig. 5, E and F).
O 30 and Ser(P) 33 cooperate to regulate the solubility and stability of K18, we hypothesized that modifications at these two sites could also regulate filament organization of K18. Intensity quantification of K18-WT filaments across the cell reveal that filament density is highest around the nucleus and gradually decreases toward the cell periphery (Fig. 6, A and  B) (19). This organization was severely affected in both K18-TM and K18-S30A, which displayed increased filament accumulation around the nucleus with collapse of peripheral filaments, whereas the filament organization of the K18-S29A and K18-S48A mutants was similar to K18-WT (Fig. 6, C-F). Moreover, rescue of O-GlcNAcylation at Ser 30 in K18-S29A/ S48A could restore the abnormal filament organization of K18-TM (Fig. 6, G and H), implying a key role for gSer 30 in supporting the filament organization of K18. Because gSer 30 on K18 leads to phosphorylation at Ser 33 , we predicted that loss of Ser(P) 33 could phenocopy the filament organization of K18-S30A and K18-TM. As expected, the K18-S33A mutant exhibited perinuclear aggregation and loss of peripheral filaments, whereas the filament organization of the K18-S52A mutant was similar to K18-WT (Fig. 6, I and J). This is also supported by previous reports that show that K18-Ser(P) 33 plays a key role in regulating filament organization and that loss of phosphorylation at this site (K18-S33A) causes the collapse of filaments around the nucleus (5). To confirm these results, we assessed the filament organization in the K18-S33D and K18-S30A/ S33D phosphomimetic mutants. The collapsed filament organization was not rescued in either of these stable lines, suggesting that S33D is unable to compensate for phosphorylation at Ser 33 (Fig. 6, K and L). These results imply that gSer 30 -dependent phosphorylation of Ser 33 is essential for maintaining the normal filament organization of keratin 18. To further investigate the cellular impact of the cooperativity between gSer 30 and Ser(P) 33 , we assessed the migration of site-specific O-GlcNAcylation and phosphorylation mutants on fibronectin substrate in a scratch wound assay. It is interesting to note that only S30A and S33A O-GlcNAc and phosphomu-  tants of K18, respectively, exhibited reduced migration and wound closure compared with the WT (Fig. 7, A-D). The other O-GlcNAcylation and phosphorylation mutants of K18 (S29A, S48A, and S52A) showed migration similar to K18-WT (Fig. 7,  A-D). These results further highlight the importance of Ser 30 O-GlcNAcylation-mediated Ser 33 phosphorylation on keratin 18 in modulating cellular processes like migration.

Discussion
On most phosphoglycoproteins discovered so far, O-GlcNAcylation and phosphorylation antagonize each other in site occupancy and regulation of protein functions (47). However, this seems unclear for K18 because both of these modifications exhibit similar changes under certain conditions, like mitotic arrest (48) and heat stress (49), whereas, during induced hepatotoxicity, they exhibit an inverse relationship (50). Of the two phosphorylation sites mapped on keratin 18, Ser(P) 33 causes increased solubility during mitosis and filament reorganization in response to shear stress (5,14), whereas Ser(P) 52 is known to regulate filament reorganization under stress conditions (51). Mutating the three known O-GlcNAcylation sites of K18 (Ser 29 , Ser 30 , and Ser 48 to Ala) led to altered filament organization and decreased both solubility and degradation of keratin 18 (17). However, it is still unclear whether this regulatory role of O-GlcNAcylation is site-specific and whether it is dependent on its cross-talk with phosphorylation. Here we demonstrate a hitherto unreported, positive cross-talk between Ser 30 O-GlcNAcylation and Ser 33 phosphorylation on K18, and this cross-talk is responsible for regulating K18 solubility, filament organization, and stability (Fig. 8).
Solubility of the K8/18 network is known to play an essential role in degradation because filament or aggregated K8/18, although ubiquitinated, cannot be degraded by proteasomes unless they are disassembled into soluble form (43). Phosphorylation at serine 33 plays an important role in the solubility and reorganization of keratin 8/18 filament network mainly during mitosis and shear stress (5,14). Moreover, it is also a binding site for the 14-3-3 class of proteins, which further aids in the solubility of K8/18 filaments (45). In addition to this, OA-mediated inhibition of phosphatases led to an increase in Ser(P) 33 levels along with enhanced binding to 14-3-3 in HT-29 epithelial cells (5,45), whereas abrogation of phosphorylation at Ser 33 had no effect on OA-induced solubility of the K18-S33A mutant when expressed in NIH3T3 fibroblasts (5). Although these reports strongly indicate a role for Ser(P) 33 in mediating K18 solubility, they also point to varied effects of modifications on the solubility of keratin 18 in different cell types (5,45). Of the three sites of O-GlcNAcylation, it was interesting to observe that loss of gSer 30 was enough to stall the phosphorylationinduced solubility during OA treatment (Fig. 1). Further to this, the loss of gSer 30 also led to an increased stability of K18 (Fig. 2), suggesting that O-GlcNAcylation at Ser 30 could be central to not only phosphorylation-dependent solubility but also subsequent degradation. On most proteins, O-GlcNAcylation protects against proteasomal degradation either directly or by antagonizing phosphorylation (52). O-GlcNAcylation could also target the protein for degradation, as in the case of the kinase CK2, where O-GlcNAcylation at Ser 347 leads to degradation by antagonizing phosphorylation at Thr 344 (53). In either of the cases, O-GlcNAcylation regulates protein stability by antagonizing phosphorylation. Interestingly, this seemed contrary on K18 because phosphorylation-induced solubility and degradation were totally dependent on O-GlcNAcylation at serine 30 ( Figs. 1 and 2).
The co-existence of both these modifications on K18 seems plausible because they exhibit similar changes during conditions associated with increased solubility and filament reorganization. Indeed, the presence of notable phosphorylation on O-GlcNAcylated K8 and K18 species confirms the co-occurrence of these modifications (Fig. 3B). However, because of the presence of multiple sites of both these modifications, they could exhibit a mutually exclusive relationship at proximal sites but can still co-exist at distal sites. Further analysis using site-specific K18 O-GlcNAc mutants along with sitespecific K18 phosphorylation antibodies indicate both a cooperative and antagonistic interplay between these modifications at proximal sites (Fig. 3, C-E). Although O-GlcNAcylation at Ser 30 promotes phosphorylation at Ser 33 (Fig. 3, F-I), O-GlcNAcylation at Ser 48 antagonizes phosphorylation at Ser 52 (data not shown). Although a previous study supports the presence of a reciprocal relationship between gSer 48 and Ser(P) 52 (44), the existence of a promotive/cooperative relationship between gSer 30 and Ser(P) 33 is both interesting and novel. Furthermore, global high-throughput phosphoproteomics upon elevated O-GlcNAc levels does support the prevalence of such a non-reciprocal, co-operative interplay on many proteins (36). Such a type of synergistic relationship between O-GlcNAcylation and phosphorylation exists in the catalytic cleft of the calcium/calmodulin-dependent kinase IV (CAMKIV) kinase, albeit at distal sites, where mutation of the glycosylation sites Thr 57 /Ser 58 to alanine on calcium/ calmodulin-dependent kinase IV causes a drastic reduction in basal activating phosphorylation at Thr 200 (35).
This cooperative interplay between gSer 30 and Ser(P) 33 not only responds to an acute pharmacological increase in O-GlcNAcylation but also seems to be unidirectional, with gSer 30 acting as a switch for phosphorylation at Ser 33 (Fig. 4). Thus, O-GlcNAcylation at Ser 30 can facilitate phosphorylation at Ser 33 either by aiding or hindering interactions with kinases and phosphatases, respectively. The possibility of gSer 30 facilitating interaction with kinase(s) seems more probable because the loss of Ser(P) 33 in K18-TM and S30A mutants could not be restored upon inhibiting phosphatases (Fig. 4, E and F). It is also important to note that OA-induced enhanced association of 14-3-3 with K18 is marginally reduced but not completely diminished in the triple glycosylation mutant when expressed in baby hamster kidney fibroblasts (5). Although this suggests that Ser 33 could still be basally phosphorylated in the absence of glycosylation at Ser 30 , it also hints at the possibility of different kinases involved in phosphorylating Ser 33 in different cell sys-tems (5,14,54). Overall, these results suggest that gSer 30 controls the solubility and degradation of K18 by stabilizing phosphorylation at Ser 33 . This seems plausible because phosphorylation on many proteins acts as a signal for ubiquitination-mediated proteasomal degradation (55). Even on K8, shear stress-induced phosphorylation at Ser 73 enables E2 ligases to mediate proteasomal degradation (56). Indeed, loss of phosphorylation at Ser 33 increased the stability of K18, which could not be rescued by increasing O-GlcNAcylation on K18 (Fig. 5, A-D) or by phosphomimetic substitution at Ser 33 (Fig. 5, E and F). Although substitution with negatively charged residues like aspartate rescues loss of Ser/Thr phosphorylation on many proteins, on keratin 18, S33D does not seem to substitute for phosphorylation (Fig. 5, E and F) (5). These findings imply that O-GlcNAcylation at Ser 30 predominantly aids in the phosphorylation at Ser 33 , which in turn causes increased solubility and subsequent degradation of K18.
Phosphorylation at Ser 33 is also a key regulator of K18 solubility and filament organization both in cultured cells and hepatocyte in vivo (5,45,57). In general, keratins 8/18 exhibit a gradient of filament network with highly bundled filament near the nucleus and fine, thin filaments at the cell periphery (58). As reported previously, expression of K18-S33A mutant led to disruption of filament organization, visualized as highly concentrated perinuclear filaments and a collapsed peripheral filament network, whereas the architecture of K8/18 is unaltered in K18-S52A mutants or K18-WT-expressing cells (Fig. 6, C, D, I, and J) (5). Among the O-GlcNAcylation mutants, only K18-S30A mimicked the perinuclear collapsed network of K18, as seen in K18-S33A phosphomutant (Fig. 6, C-H). The defects in filament organization in K18-S33A and K18-S30A could not be rescued by S33D mutations, suggesting that, similar to K18 stability, S33D cannot substitute for Ser(P) 33 to rescue filament organization. These observations further strengthen the regulatory role of gSer 30 in promoting Ser(P) 33 , which in turn dictates the solubility, filament organization, and turnover of keratin 18.
The dynamic reorganization of keratin 8/18 filaments is essential for the plasticity of the keratin filament network during many cellular processes, including cell migration. Rapid changes in keratin network dynamics are initiated especially in the lamellipodia of migrating cells (58). It is also important to note that phosphorylation of keratin 8 alone can play a critical role in mediating the migration of epithelial tumor cells and hepatocytes (9,59). Interestingly, loss of O-GlcNAcylation at Ser 30 or phosphorylation at Ser 33 on K18 was sufficient to reduce the migrating potential of hepatocytes, indicating that both gSer 30 and gSer 33 act cooperatively to impact filament dynamics during cell migration (Fig. 7).
Taken together these results demonstrate a synergism between S30 O-GlcNAcylation and Ser 33 phosphorylation on keratin 18 in regulating its functional properties like solubility, filament organization, and stability (Fig. 7). The cycling of O-GlcNAc on cellular proteins is tightly linked to glucose metabolism (60,61) and is often deregulated in multiple pathological conditions like diabetes and cancer (32). These findings raise the possibility of factors like glucose metabolism to regulate keratin 8/18, mainly in metabolically active cells like hepatocytes. The positive regulation of phosphorylation by proximal O-GlcNAcylation opens up new avenue to understand the functional regulation of phosphoglycoproteins. Understanding how O-GlcNAcylation can facilitate phosphorylation on K18 will be important because this type of interplay might be as abundant as reciprocal cross-talk.
Author Contributions-P. S. K. performed the experiments, generated mutants, designed the experiments, analyzed the data, interpreted the results, and wrote the manuscript. S. B. conceived and supervised the work, generated the mutants, performed the purification and immunoprecipitation of WGA-bound (glycosylated) keratins, designed the experiments, supervised data analysis, interpreted the results, and wrote the manuscript. R. D. K. conceived and supervised the work, designed the experiments, supervised data analysis, and wrote the manuscript. M. M. V. supervised the work and wrote the manuscript.