Osteoarthritis is one of the leading causes of pain and disability in the aged population due to articular cartilage damage. This warrants investigation of signaling mechanisms that could protect cartilage from degeneration and degradation. Here we show in a murine model of experimental osteoarthritis that YAP activation by transgenic overexpression or by deletion of its upstream inhibitory kinases Mst1/2 preserves articular cartilage integrity, whereas deletion of YAP in chondrocytes promotes cartilage disruption. Our work shows that YAP is both necessary and sufficient for the maintenance of cartilage homeostasis in osteoarthritis. Mechanistically, inflammatory cytokines, such as TNFα or IL-1β, trigger YAP/TAZ degradation through TAK1-mediated phosphorylation. Furthermore, YAP directly interacts with TAK1 and attenuates NF-κB signaling by inhibiting substrate accessibility of TAK1. Our study establishes a reciprocal antagonism between Hippo-YAP/TAZ and NF-κB signaling in regulating the induction of matrix-degrading enzyme expression and cartilage degradation during osteoarthritis pathogenesis.
Osteoarthritis (OA) is one of the most common degenerative diseases and the incidence increases significantly with age. The disease is characterized by progressive degradation of articular cartilage, subchondral bone thickening, and osteophyte formation, which ultimately leads to loss of joint mobility and joint functions. Cartilage loss is caused by multifactorial parameters, including excessive production of matrix-degrading enzymes such as aggrecanases and matrix metalloproteinases (MMPs)1, accelerated chondrocyte hypertrophy and increased focal calcification of joint cartilage. These conditions are commonly characterized by elevated expression of Col10a1 and alkaline phosphatase2,3,4. Eventually, cells undergo apoptosis, which leads to destruction of cartilage tissues5. Articular chondrocytes differ from growth plate chondrocytes as they do not normally undergo proliferation, maturation, hypertrophy, apoptosis, and ossification6,7. However, the molecular mechanisms regulating these processes in articular chondrocytes remain unclear. These regulatory processes are highly relevant to the onsets, pathogenesis, and progression of OA.
A variety of cytokines and chemokines are ectopically expressed in OA chondrocytes, synovial macrophages, and fibroblasts. Pro-inflammatory mediators such as tumor necrosis factor alpha (TNFα), interleukin-1 beta (IL-1β), and IL-6 are implicated in OA pathophysiology8. These catabolic factors activate a series of pathways including NF-κB signaling, which plays a major role in OA pathogenesis9. It has been shown that NF-κB signaling orchestrates mechanical, inflammatory, and oxidative stress-activated processes that contribute to cartilage tissue damage and thus representing an attractive therapeutic target for OA treatment10,11,12. A better understanding of the mechanism in modulating NF-κB signaling activity stands essential for the development of effective therapeutic intervention.
Hippo signaling is identified to control organ size and tissue regeneration in many organs13,14. Central to this pathway is a kinase cascade consisting of MST1/2, SAV, LATS1/2, and MOB1A/B. When the Hippo signaling is active, a series of phosphorylation events via MST and LATS kinases ultimately leads to the phosphorylation of YAP/TAZ, the key effectors of the pathway. Phosphorylated YAP is sequestered in the cytoplasm, which inhibits its transcriptional activity. By contrast, inactivation of the Hippo pathway increases YAP/TAZ nuclear translocation. Subsequently, they interact with TEADs or other transcription factors to regulate downstream signaling cascades in order to control cell proliferation, apoptosis, differentiation, and maturation15. We have shown that Hippo pathway mediates its effect through YAP in regulating chondrocyte differentiation at multiple steps during endochondral ossification and bone repair. YAP promotes chondrocyte proliferation but inhibits subsequent maturation by binding with different transcription factors implicated in chondrocyte differentiation16. Whether Hippo pathway or YAP regulates articular cartilage homeostasis similar to that of skeletal development remains elusive. Previous studies have firmly established pivotal role of Hippo-YAP/TAZ pathway in embryonic development, tissue homeostasis, and tumorigenesis. Recently, several studies have uncovered novel roles of Hippo signaling in regulating innate immunity, autoimmunity, and cancer immunity17,18,19. However, whether the Hippo-YAP/TAZ pathway plays a role in regulating inflammatory response during OA pathogenesis remains elusive.
Here, we investigated the roles of Hippo pathway and YAP in maintaining articular cartilage integrity during OA pathogenesis. We found that Hippo signaling mediates its signals through YAP to control articular cartilage homeostasis. YAP is necessary and sufficient to attenuate OA progression by inhibiting inflammatory responses triggered by NF-κB signaling. Furthermore, inflammatory cytokines activates Hippo signaling and promotes YAP phosphorylation mediated by TAK1 and association with β-TRCP for proteasome-mediated degradation. Our findings suggest that targeting YAP is a viable strategy for treating OA.
Reduced expression of YAP in osteoarthritic cartilage
To investigate the function of YAP in articular cartilage maintenance, we first examined the endogenous expression of YAP, a key mediator of Hippo signaling, in the knee joints from 1- to 6-month-old wild-type mice (Fig. 1a, b). When the mice were young at 1- and 2-month-old, strong YAP expression was observed in all zones of the articular cartilage. As the mice aged, we found that YAP expression was gradually reduced and its expression was remarkably lower in the 6-month-old mice. These data suggest a gradual reduction of YAP in articular chondrocyte maturation. As OA is one of the ageing related diseases, we thus recapitulated the degenerative condition of articular cartilage by performing surgically induced OA in adult wild-type mice. We found that injured articular cartilage also showed significant reduction of YAP expression and its expression level correlated coherently to the severity of cartilage degradation in OA conditions as shown by knee joint sections at 4 and 10 weeks post operation respectively (Fig. 1c, d). Furthermore, YAP expression levels were concomitantly reduced according to the severity and OARSI grade of OA in human patient samples20 (Fig. 1e, f). Altogether, our findings suggest that YAP expression is highly correlated to the pathogenesis of OA.
YAP attenuates cartilage degradation during OA progression
To elucidate the functional role of YAP in OA pathogenesis in vivo, we first generated Mst1f/f;Mst2f/f;Col2a1-Cre mutant mice in which Hippo signaling is inactivated in chondrocytes. The mutant mice were phenotypically normal with no obvious skeletal defect including articular cartilage, albeit YAP expression was strongly upregulated in articular cartilage (Supplementary Figure 1a, b). Next, we surgically induced osteoarthritic condition in the mutant mice and examined the articular cartilage degradation. Two months after surgery, we found that the integrity of articular cartilage of the Mst1f/f;Mst2f/f; Col2a1-Cre mutant mice was maintained significantly better than that of the control group under both ACLT (Anterior Cruciate Ligament Transection) and DMM (Destabilization of the Medial Meniscus) surgical conditions (Fig. 2a, b and Supplementary Figure 1c). The expression of YAP was maintained at a higher level in the mutant mice, but Mmp13 (matrix metalloproteinases 13) expression was significantly lower (Fig. 2c, d). In addition, inflammation was less severe in the peripheral fibrous tissues with fewer synovial lining cells around the knee joint of the mutant mice as shown by F4/80 and CD11b expression (Supplementary Figure 1d). Next, we isolated primary chondrocytes from the newborn mutant mice and treated them with TNFα in culture. Consistent with the in vivo phenotypes, the ECM (extracellular matrix) degradation enzymes, such as Mmps and Adamts4/5 (a disintegrin and metalloproteinase with thrombospondin motifs 4/5), were significantly upregulated, while the expression of the cartilage extracellular matrix components (Col2a1 and Aggrecan), Yap1/Taz and their target genes was greatly inhibited in response to TNFα treatment in control chondrocytes (Fig. 2e and Supplementary Figure 1e). However, deletion of Mst1/2 in chondrocytes attenuated these effects induced by TNFα (Fig. 2e and Supplementary Figure 1e). Collectively, our data indicate that activation of YAP in articular chondrocytes attenuates OA progression.
To further determine the functions of YAP in protecting cartilage degradation during OA progression, we overexpressed YAP in chondrocytes by generating Col2a1-Yap1tg/+ transgenic mice16. No obvious skeletal phenotype was observed in the articular cartilage of Yap1 heterozygous transgenic mice (Supplementary Figure 2a, b). Under osteoarthritic condition, Col2a1-Yap1tg/+ transgenic mice displayed remarkably better cartilage integrity than that of the wild-type mice (Fig. 2f, g and Supplementary Figure 2c). In addition, Mmp13 expression in the articular chondrocytes of Col2a1-Yap1tg/+ transgenic mice was significantly lower and less inflammatory cells were recruited as shown by F4/80 and CD11b expression in the synovial lining cells of Col2a1-Yap1tg/+ transgenic mice (Fig. 2h, i and Supplementary Figure 2d). TNFα or IL1β treatment in transgenic chondrocytes led to lower induction of matrix-degrading enzymes, but higher expression of cartilage ECM and YAP target genes than those of the wild-type chondrocytes (Fig. 2j and Supplementary Figure 2e, f). Our results suggest that YAP protects articular cartilage from degradation during OA pathogenesis.
Loss of YAP exaggerates cartilage destruction during OA
To examine whether YAP is required to protect articular cartilage integrity during OA pathogenesis, we genetically removed Yap1 in chondrocytes by generating Yap1f/f;Col2a1-Cre mutant mice. No obvious cartilage defect in the articular cartilage was observed in the adult Yap1f/f;Col2a1-Cre mutant mice (Supplementary Figure 3a, b). However, under OA condition, cartilage degradation was significantly more severe than that of the control mice (Fig. 3a, b). Immunohistochemical staining revealed substantial reduction of YAP expression and elevated Mmp13 expression in the articular cartilage of the Yap1f/f;Col2a1-Cre mutant mice under osteoarthritic condition as compared to the control animals (Fig. 3c, d). Accordingly, TNFα treatment led to increased expression of matrix-degrading enzymes and decreased expression of ECM components and YAP target genes in the primary chondrocytes from Yap1f/f;Col2a1-Cre newborn mice (Fig. 3e, f). In addition, inflammatory cells were accumulated in the synovium of Yap1f/f;Col2a1-Cre mice with OA (Fig. 3g), which are mirror results as compared to that of the Col2a1-Yap1tg/+ transgenic mice. Altogether, our results indicate that YAP is necessary and sufficient to protect cartilage degradation in OA condition.
Next, we asked whether pharmacological treatment with agents that regulate YAP activity affects OA progression similarly to the genetic manipulation of the Hippo pathway. Lysophosphatidic acid (LPA) has been shown to inhibit LATS1/2 thereby activating YAP21. Conversely, verteporfin (VP) binds to YAP and inhibits its interaction with TEADs22. We first validated the effects of these agents in primary chondrocytes. As expected, LPA treatment inhibited YAP phosphorylation and stabilized YAP proteins in primary chondrocytes (Supplementary Figure 4a), whereas VP treatment inhibited YAP activities and thereby led to its degradation (Supplementary Figure 4b). Next, we examined their effects in articular cartilage in vivo under OA condition. Consistent with our mouse genetic models, alginate beads soaked with either LPA or VP and implanted into the articular joint cavity of wild-type mice immediately after OA surgery exhibited similar effects on articular cartilage integrity as Yap1 transgenic or knockout mice, respectively (Supplementary Figure 4c–f). Moreover, co-treatment of IL-1β or TNFα with LPA or VP in culture showed consistent results in the expression of matrix-degrading enzymes and ECM, respectively, as the Mst1/2 or Yap1 mutant chondrocytes (Supplementary Figure 4g, h). Thus, our data indicate that pharmacological activation of YAP protects osteoarthritic cartilage degradation.
Inflammatory cytokines promote YAP degradation
As pro-inflammatory cytokines, such as TNFα, IL-1β, and IL-6, are implicated in OA pathophysiology9,23, the effect of these inflammatory cytokines on Hippo signaling was examined in primary chondrocytes to mimic the pathological conditions of OA. We found that the expression of Mst1/2 and Lats1/2 displayed no obvious changes upon treatment with TNFα or IL-1β (Supplementary Figure 5a). Notably, the expression of Yap1/Taz and their target genes Ctgf and Cyr61 was reduced in response to TNFα treatment in primary chondrocytes (Fig. 4a and Supplementary Figure 5a). Consistently, Gal4/TEAD4-luciferase reporter activity was inhibited in response to TNFα treatment in a dose dependent manner in primary chondrocytes (Fig. 4b). Moreover, TNFα treatment also suppressed YAP-induced Gal4/TEAD4-luciferase reporter activity in HEK293A cells (Fig. 4c). However, at protein level, MST1 and LATS1 were strongly activated as shown by increased phosphorylation levels shortly after TNFα or IL-1β stimulation, respectively (Fig. 4d). The phosphorylation levels of both YAP and TAZ were greatly increased (Fig. 4d). Moreover, we found that the total protein levels of YAP and TAZ were reduced after TNFα or IL-1β treatment in primary chondrocytes (Fig. 4e). As ubiquitin-mediated proteolysis is one of the most common mechanisms for protein degradation, we examined whether YAP is removed through proteasome upon TNFα stimulation. We found that YAP protein levels were restored upon proteasome inhibitor MG132 treatment, but not lysosomal inhibitor chloroquine (Chlq) (Fig. 4f). In addition, TNFα treatment resulted in remarkable poly-ubiquitination modification and degradation of YAP (Fig. 4g, h). Furthermore, immunofluorescence analysis revealed that YAP was exported to the cytoplasm after TNFα stimulation in primary chondrocytes or in IL-1β-treated HeLa cells (Fig. 4i and Supplementary Figure 5b). Taken together, our data indicate that inflammatory cytokines trigger Hippo pathway activation and promote proteasomal degradation of YAP.
TAK1 associates with and phosphorylates YAP/TAZ independent of LATS
The direct phosphorylation of YAP/TAZ by LATS1/2 kinases leads to YAP/TAZ cytoplasmic retention and degradation mediated by SCF/β-TRCP E3 ubiquitin ligase in response to various stimuli24,25. We asked whether TNFα-induced YAP/TAZ phosphorylation and degradation are dependent on LATS1/2. Intriguingly, a decrease of YAP/TAZ protein levels was still observed in LATS1/2 DKO (double knockout) HEK293A cells in response to TNFα stimulation (Fig. 5a). In addition, the reduced YAP/TAZ protein levels were restored when cells were treated with MG132, but not chloroquine (Fig. 5a and Supplementary Figure 6a). These results suggest that TNFα-induced proteasomal degradation of YAP/TAZ is independent of LATS1/2 kinases. As we observed an increased phosphorylation of YAP/TAZ upon TNFα treatment in chondrocytes, this prompted us to test whether kinases in the TNFα-activated NF-κB pathway are involved in the phosphorylation of YAP/TAZ. We co-expressed YAP with a series of kinases related to the NF-κB pathway in HEK293T cells (Fig. 5b). Of note, Flag-tagged YAP or TAZ displayed a significant mobility shift only when TAK1 kinase was co-expressed (Fig. 5b and Supplementary Figure 6b). Moreover, the kinase-dead mutant of TAK1 (TAK1-KD) was unable to promote the mobility shift of YAP or TAZ in phos-tag gel assay (Fig. 5c). These results suggest that YAP/TAZ are the targets of TAK1 for phosphorylation modification. In addition, overexpression of YAP-5SA where all LATS1/2 kinases phosphorylation sites were mutated, also displayed a remarkable mobility shift on SDS-PAGE in the presence of TAK1 kinase in wild-type or LATS1/2 DKO cells respectively (Fig. 5d, e). These data indicate that TAK1 phosphorylates YAP through a LATS1/2 kinases independent mechanism.
To further investigate the molecular mechanisms how TAK1 regulates YAP activity, we tested whether TAK1 directly associates with and phosphorylates YAP. By co-immunoprecipitation assay, we observed an interaction of TAK1 and YAP in endogenous proteins or using overexpression of reciprocal tagged proteins in HEK293T cells (Fig. 5f, g and Supplementary Figure 6c). Next, we used an in vitro kinase assay to test whether TAK1 directly phosphorylates YAP. We found that TAK1 purified from HEK293T cells phosphorylated YAP purified from a separate set of HEK293T cells or GST-YAP recombinant proteins isolated from Escherichia coli (Fig. 5h, i). Since phosphorylation of YAP at S127 leads to its cytoplasmic retention, and we found that TNFα treatment stimulates YAP translocation into cytoplasm (Fig. 4i and Supplementary Figure 5b). These observations prompted us to test whether TAK1 phosphorylates YAP at S127. Our in vitro kinase assay showed that S127 of GST-YAP recombinant protein was phosphorylated in the presence of TAK1, but not TAK1-KD (Fig. 5j). Furthermore, expression of TAK1 enhanced S127 phosphorylation of Flag-tagged YAP in LATS1/2 DKO HEK293A cells (Fig. 5k). To identify additional and potential phosphorylation sites on YAP by TAK1, we next performed mass spectrometry analysis of Flag-tagged YAP co-expressed with HA-tagged TAK1 or TAK1-KD. We observed a substantial increased percentage of several phosphorylation sites of YAP in the presence of TAK1 (Supplementary Figure 6d and Supplementary Dataset 1, 2). We subsequently generated a series of YAP mutations targeting these sites (Supplementary Figure 6e). However, we did not identify specific sites targeted by TAK1 by examining the mobility shift of YAP induced by TAK1. Thus, our data indicate that TAK1 directly phosphorylates YAP at multiple sites.
TAK1 inhibits YAP activity through β-TRCP
Next, we tested whether TAK1 promotes YAP degradation. We found that TAK1 expression triggered degradation of endogenous YAP and TAZ in a dose dependent manner in HEK293T cells (Fig. 6a). Conversely, the basal levels of YAP and TAZ were increased in TAK1-KO HEK293T cells (Fig. 6b). More importantly, TNFα-induced degradation of YAP/TAZ was significantly compromised in the TAK1-KO HEK293A cells (Fig. 6c). Next, we investigated whether TAK1 modulates YAP/TEAD transcriptional activity. As expected, there was an increased expression of YAP target genes, such as CTGF and CYR61, in TAK1-KO HEK293T cells (Fig. 6d). Expression of TAK1 inhibited Gal4/TEAD4-luciferase reporter activity as compared to the control and TAK1-KD mutant (Fig. 6e). Furthermore, YAP induced a higher reporter activity in TAK1-KO HEK293T cells (Fig. 6f). Consistently, TNFα-induced reduction of reporter activity was also compromised in TAK1-KO HEK293T cells (Fig. 6g). These results indicate that TAK1 promotes YAP degradation and suppresses its activity.
To further explore how TAK1 contributes to YAP degradation, we first examined whether TAK1 promotes YAP ubiquitination. We found that the expression of TAK1 enhanced K48-linked poly-ubiquitination modification of YAP protein (Fig. 6h). Previous study demonstrates that Hippo-regulated YAP degradation is through SCF-β-TRCP-mediated ubiquitination25. Therefore, we tested whether β-TRCP is involved in YAP degradation regulated by TAK1. Notably, expression of TAK1, but not TAK1-KD mutant, greatly enhanced the interaction of YAP with β-TRCP (Fig. 6i). Conversely, knockout of TAK1 inhibited YAP poly-ubiquitination modification and abrogated YAP–β-TRCP interaction (Fig. 6j, k). In addition, endogenous YAP and TAZ proteins were remarkably stabilized in the TAK1-KO HEK293T cells, but degraded quickly over time in HEK293T cells in a CHX (Cycloheximide) chase experiment (Fig. 6l). Together, our results support the functional importance of TAK1 in inhibition of YAP activity by stimulating β-TRCP-mediated YAP ubiquitination and degradation during inflammatory cytokine stimulation.
YAP attenuates NF-κB pathway by inhibiting IKKα/β activation
One of the complications for OA pathogenesis is inflammation23. Inflammatory cytokines TNFα and IL-1β are implicated in cartilage degradation through regulating NF-κB and JNK signaling pathways11,12,26. We asked whether YAP modulates the activity of TNFα signaling and its subsequent actions in regulating articular cartilage integrity during OA condition. In primary chondrocytes, overexpression of YAP inhibited TNFα-induced JNK and p65 activation (Supplementary Figure 7a). Treatment of JNK inhibitor SP600125 only inhibited TNFα-induced upregulation of Adamts5 and Mmp3. However, treatment of TAK1 inhibitor 5Z-7-Oxozeaenol (5Z-7-O) greatly inhibited all TNFα or IL1β effects and evoked a broad suppression of Adamts and Mmp expression (Supplementary Figure 7b, c and d). In Col2a1-Yap1tg/+ transgenic chondrocytes, we found that NF-κB signaling activity was greatly attenuated after TNFα stimulation as shown by reduced phosphorylation of p65 while JNK signaling was only slightly inhibited by YAP (Fig. 7a and Supplementary Figure 7e). To further verify that YAP modulates NF-κB signaling activity, we examined the cellular localization of p65 in response to YAP overexpression. p65 was translocated into the nucleus under IL-1β treatment in primary chondrocytes (Fig. 7b). However, when YAP was overexpressed, IL-1β-induced nuclear translocation of p65 was significantly inhibited (Fig. 7b). More importantly, a significantly reduced expression of phosphorylated p65 in the Col2a1-Yap1tg/+ mutant chondrocytes under osteoarthritic condition was observed as compared to the controls (Fig. 7c). These data strongly suggest that YAP expression attenuates NF-κB signaling to protect cartilage degradation during OA.
To explore the molecular basis of YAP/TAZ in regulating the activity of NF-κB pathway, we first examined the effect of YAP/TAZ on NF-κB luciferase reporter. As measured by the NF-κB luciferase reporter, we observed a profound inhibition of TNFα-induced NF-κB transactivation by both YAP-5SA and transcriptionally inactive YAP-6SA, similar to that of wild-type YAP (Fig. 7d). Furthermore, YAP greatly suppressed TAK1-, IKKα/β- (inhibitor of nuclear factor kappa-B kinase subunit alpha/beta), or IKKγ-induced NF-κB reporter activity (Fig. 7e–h,). However, YAP only slightly inhibited p65-induced NF-κB reporter activity (Fig. 7i,). These data suggest that YAP acts upon the components upstream of p65. Similarly, TAZ exhibited consistent inhibitory effects as YAP on NF-κB luciferase reporter assays (Supplementary Figure 8a-e). These observations suggest that YAP/TAZ-mediated suppression on NF-κB activity might be a direct effect rather than through their transcriptional targets.
To further explore the mechanism of how YAP inhibits NF-κB signaling activity, we examined whether YAP interacts with the components upstream of p65 in the NF-κB pathway. Intriguingly, an interaction of YAP with IKKα/β and IKKγ was detected by co-immunoprecipitation assays (Fig. 7j). Next, we examined whether YAP inhibits NF-κB activity through suppressing the TAK1-IKKs cascade activation. TRAFs-mediated TAK1 K63-linked poly-ubiquitylation is critical for TAK1 activation. We found that K63-linked poly-ubiquitylation and phosphorylation of TAK1 were not affected by YAP overexpression (Supplementary Fig. 8f, g). Intriguingly, YAP overexpression abrogated the association of TAK1 with IKKα (Fig. 7k) and the phosphorylation of IKKα and IKKβ was significantly impeded by YAP or TAZ expression, respectively, in HEK293T cells (Fig. 7l, m, and Supplementary Figure 8h-k). All of these data suggest that YAP/TAZ antagonize NF-κB activity by preventing TAK1 substrate accessibility and subsequent activation of IKKα/β.
Activated IKKs complex induces phosphorylation and degradation of IκBα and subsequent activation of p65 and translocation of p50/p65 heterodimer into the nucleus. As β-TRCP complex is the ubiquitin ligase for ubiquitination of IκBα27,28,29, we first examined whether YAP impeded the interaction of IκBα with β-TRCP. The ubiquitination of IκBα and the interaction between IκBα and β-TRCP were greatly reduced when YAP was overexpressed (Supplementary Figure 8l, m). Next, we examined p65 activation in the presence of YAP. Consistent with the reduced IKKα/β activation, the phosphorylation of p65 was attenuated in response to TNFα stimulation when YAP or TAZ was overexpressed in HEK293A cells, respectively (Fig. 7n and Supplementary Figure 8n). In addition, purified GST-YAP protein from Escherichia coli was sufficient to inhibit the phosphorylation of p65 by IKKα/β as revealed by the in vitro kinase assay (Supplementary Figure 8o, p). Together, our findings indicate that YAP inhibits TAK1 substrate accessibility, abrogates IKKα/β activation and suppresses IκBα degradation, and p65 activation and nuclear translocation, which results in attenuation of NF-κB signaling activity.
To further investigate the role of YAP in NF-κB signaling more specifically, we knocked down Yap1 in primary chondrocytes isolated from newborn mice. TNFα treatment in Yap1-knockdown chondrocytes resulted in consistent results as in the Yap1f/f;Col2a1-Cre mutant chondrocytes with increased expression of Adamts4/5 and Mmp genes (Supplementary Figure 9a). Next, we generated YAP-KO HEK293T cells using CRIPSR/Cas9 system. There was an increased phosphorylation of p65 and IKKα/β in the YAP-KO HEK293T cells (Fig. 7o and Supplementary Figure 9b). In line with the results from YAP-knockdown chondrocytes, complete removal of YAP in the HEK293T cells resulted in a more sensitive response to TNFα stimulation as reflected by NF-κB luciferase reporter assay (Supplementary Figure 9c). These results indicate that YAP deficiency potentiates NF-κB signaling activity.
Collectively, our results suggest a reciprocal antagonism between Hippo-YAP/TAZ and NF-κB signaling in articular chondrocytes during the OA pathogenesis (Supplementary Figure 9d). Inflammatory cytokines promote YAP proteasomal degradation via TAK1-mediated YAP phosphorylation and ubiquitination. Reciprocally, YAP inhibits cartilage degradation through association with TAK1 and IKKs complex, which prevents the IKKα/β activation and subsequent NF-κB translocation into the nucleus.
This study shows that YAP mediates the function of Hippo pathway to control articular cartilage homeostasis during OA by antagonizing NF-κB signaling. In particular, genetic removal of both Mst kinases in chondrocytes displays the same phenotypes as YAP transgenic mice in protecting articular cartilage. This effect can also be achieved by LPA treatment, which activates YAP during osteoarthritic condition. By contrast, removal of Yap1 in chondrocytes exaggerates cartilage degradation. Upon excessive mechanical stress, which is common risk factors for OA, inflammatory cytokines such as TNFα or IL-1β are secreted and trigger NF-κB signaling activation. Our study reveals that these inflammatory cytokines are able to activate the Hippo pathway. Since extracellular growth factors responsible for the activation of the Hippo pathway remain largely unclear, our study provides new insight in the control of the Hippo pathway. Previous studies showed that mechanical stimuli such as cell–cell contact and high cell density activate Hippo pathway and inhibit YAP activity. These effects are mediated through junction proteins such as α-catenin30,31, polarity proteins32, GPCR signaling21, or mechanical stress33. Our findings further unravel additional signaling cues that are able to activate Hippo pathway in regulating tissue homeostasis and provide insights into how Hippo-YAP/TAZ signaling coordinate cell growth and various environmental stimuli in physiological and pathological conditions.
Our current study shows that YAP associates with TAK1 to prevent IKKα/β activation, and thus inhibiting NF-κB signaling (Supplementary Figure 9d). It has been previously shown that YAP can be phosphorylated by LATS1/2 subsequently undergo proteasomal degradation mediated by β-TRCP complex after CK1-mediated phosphorylation25. Alternatively, YAP undergoes lysosomal degradation upon phosphorylation by IKKε at S43118. Here, we demonstrate that TAK1 is able to directly phosphorylate YAP at multiple sites independently of LATS and subsequently presents and interacts with the complex with β-TRCP for proteasomal degradation. Our finding reveals another mechanism on regulating the activity of YAP and delineates the reciprocal antagonistic relationship between Hippo and NF-κB signaling. In our model, YAP attenuates NF-κB signaling activation and results in reduced ECM degradation by inhibiting the induction of matrix-degrading enzymes. Indeed, a number of NF-κB inhibitors have been reported to play anti-inflammatory functions in OA. For instance, glucocorticoids are potent NF-κB inhibitors that induce the expression of IκBα and increase cytosolic retention of NF-κB34,35. In our study, YAP or its activator also inhibits TNFα-induced IκBα degradation and NF-κB nuclear localization. Thus, it is not surprising that YAP preserves cartilage integrity by modulating NF-κB signaling activity, which is a major pathway implicated in OA pathogenesis. In addition, it has been recently shown that cactus, a Drosophila IκBα homolog, is a direct target of Yorkie in regulating innate immunity system in fruit fly36. Interestingly, a recent study showed that YAP activates NF-κB activity through suppression of USP31, a negative regulator of NF-κB signaling, in soft tissue sarcomas37. These findings suggest that the crosstalk between Hippo pathway and NF-κB signaling are highly conserved in regulating inflammatory responses with distinct mechanism. Of note, our data also demonstrate that YAP/TAZ interfere with IKKα/β activation and IκBα stability in the mammalian system by inhibiting TAK1 function. Indeed, TAK1 inhibitor 5Z-7-O has been shown to have therapeutic values in inflammatory diseases38. As such, simultaneous targeting of Hippo and NF-κB pathway or more specifically YAP/TAK1 is a plausible strategy for better outcome of OA therapy.
Previous studies showed that Lubricin, a proteoglycan that is abundantly expressed in articular cartilage, which functions to protect cartilage integrity39,40, also regulates the expression and localization of NF-κB during OA41. It seems that regulation of NF-κB pathway is a key mechanism in controlling articular cartilage homeostasis. Our findings that Hippo pathway or YAP modulates NF-κB signaling activity provide additional insights on how the NF-κB signaling activity could be fine-tuned or precisely controlled during OA pathogenesis. Recent studies demonstrate a direct regulation between Hippo-YAP/TAZ and innate antiviral pathways, which are involved kinases such as TBK1 and IKKε kinases17,18. Our study uncovered TAK1/IKKα/β kinases and YAP/TAZ complex as a hub linking inflammatory responses triggered by NF-κB signaling and chondrocyte proliferation and survival regulated by YAP/TAZ during OA pathogenesis. Interestingly, TAK1, TBK1, and IKKε directly interact with YAP/TAZ, and YAP/TAZ substantially suppress the activity of both TAK1 and TBK1. Our study also showed that TAK1 phosphorylates YAP/TAZ at multiple sites independent of LATS1/2, although the functional significance of these sites was not investigated in the current study. Further work is required to identify and clarify the TAK1-mediated YAP/TAZ phosphorylation. Structural analysis on how YAP interacts with TAK1, TBK1, or IKKα/β will offer new insight into the molecular basis of inhibitory effect of YAP on these kinases.
During postnatal cartilage growth and osteoarthritic-induced cartilage degradation, we observed that YAP expression was gradually reduced. This expression pattern is highly similar to that of chromatin protein Hmgb2 (High mobility group box protein 2), a marker of chondroprogenitor cells in the articular cartilage that function to maintain cartilage integrity42,43. As YAP also regulates chondroprogenitor cell proliferation and is required for its maintenance16, it is tempting to suggest that YAP can also be used as a marker for the integrity of articular cartilage. Furthermore, both YAP and Hmgb2 are transcriptional regulators and it is possible that they work co-operatively to regulate articular cartilage homeostasis. Interestingly, Hmgb2 has been identified as a potential transcriptional target of YAP/TEADs in a genome-wide ChIP assay44. Their specific mechanistic interactions warrant further investigation.
Our previous work demonstrated that YAP regulates multiple steps during chondrocyte differentiation and maturation and it is also implicated in bone repair16. In contrast to its inhibitory role in bone repair, our current study shows that YAP attenuates cartilage degradation during OA progression and preserves cartilage integrity. Indeed, YAP plays similar roles in inhibiting chondrocyte maturation during skeletal development, postnatal cartilage growth, and fracture healing. The impairment of cartilaginous callus formation during bone repair is a result of inhibition of chondrocyte maturation. However, during early stage of bone repair, cell proliferation of chondroprogenitor cells and early committed chondrocytes are increased with YAP expression. Similar results were obtained in ATDC5 cells45, and C3H10T1/2 cells46. In addition, a recent study also showed that YAP expression is upregulated in the Gdf5-lineage cells in the synovium during cartilage repair47. The cell population contributing to cartilage repair is dependent on and regulated by YAP. All these findings are consistent with our current study that YAP plays positive roles in cartilage repair.
Our work here showed that inflammatory cytokines trigger YAP/TAZ degradation mediated by TAK1. However, both YAP and TAK1 have been implicated in response to mechanical stimuli. TAK1 is activated upon cartilage injury48 and YAP activity is inhibited upon mechanical stress33. It seems that the trigger on TAK1/YAP action is multifactorial in OA development, in which both mechanical stress and inflammatory stimuli will result in similar actions on TAK/YAP. As recent views suggest that mechanical injury predisposes cartilage to OA development and it is believed to be the most critical etiologic factors49,50, and that mechanical injury also triggers the secretion of inflammatory cytokines, our findings in the current study may also be contributed by excessive mechanical load. The involvement of TAK1/YAP actions stimulated by both mechanical and inflammatory stimuli raises the importance of this pathway to be a potential target for therapeutic strategy for OA treatment.
Tibial plateau and femoral condyle specimens from human subjects with osteoarthritis undergoing total knee joint replacement surgery were collected with the approval by the Department of Health of Hong Kong and The Institutional Review Board of The Chinese University of Hong Kong. Full written consents were obtained before the operative procedure. The specimens were processed for histological examination and were categorized according to the International Cartilage Repair Society (ICRS) scoring system.
The Mst1f/f51, Mst2f/f51, Yap1f/f52, Col2a1-Cre53, and Col2a1-Yap116 mouse lines have been described previously. All animal experiments were performed according to procedures approved by the Animal Experimentation Ethics Committee of the Chinese University of Hong Kong and Zhejiang University.
Experimental OA animal models
ACLT or DMM surgery was performed using 10-week-old male C57/B6 mice at the right knee joint54,55. Briefly, 12-week-old mice undergo the anterior cruciate ligament transection (ACLT) surgery via an incision on the medial para-patellar of the right knee joint capsule with longitudinal incision on the anterior cruciate ligament (ACL) and menisci resection. The destabilization of the medial meniscus DMM surgical instability models of osteoarthritis is similar to the ACLT surgery but without resection of menisci. A sham operation with the control mice of the same age was performed with a similar incision at the right joint capsule without anterior cruciate ligament incision and menisci resection. Animals were killed at 4 or 8 weeks after surgery. Dissected joints were processed for either histopathological or molecular analysis.
Chemicals and reagents
Verteporfin (VP) (SML05434), MG132 (C2211), 5Z-7-Oxozeaenol (O9890), and IL-1β (SRP6169 (human) and SRP8033(mouse)) were purchased from Sigma. SP600125 (T3109) was purchased from TargetMol. Lysophosphatidic acid (LPA) (sc-201053) was purchased from Santa Cruz. Cycloheximide (CHX) (2112 s) and TNFα (5178 (mouse) and 8902 (human)) was purchased from Cell Signaling. The Phos-tag TM Acrylamide AAL-107 was purchased from the NARD Institute. Kinase-dead TAK1 (TAK1-KD) construct was created by mutating lysine 63 to tryptophan. Kinase-dead IKKα (IKKα-KD) construct was created by mutating lysine 44 to alanine. Kinase-dead IKKβ (IKKβ-KD) construct was created by mutating lysine 44 to methionine.
Cell culture and transfection
HEK293A (ATCC), HEK293T (ATCC), and HeLa (ATCC) cells were cultured in DMEM medium with 10% FBS. All the cells were cultured at 37 °C in cell culture incubator with humidified environment in 5% CO2. Lipofectamine 3000 (Invitrogen) or polythylenimine (PEI) (Polysciences) transfection reagents were used for plasmid transfection. All cell lines used were tested for mycoplasma contamination using the Mycoplasma Test Kit (Shanghai Yise Medical Technology Co. Ltd, PM008).
CRISPR/Cas9-mediated genomic editing for knockout constructs
Guide RNA sequences targeting TAK1, LATS1, LATS2, or YAP were cloned into the plasmids PX459 (Addgene #62988). Constructs were transfected into HEK293A or HEK293T cells by PEI transfection reagent. Twenty-four hours after transfection, cells were selected by puromycin (1.5 μg/ml) for 72 h. Single colonies were picked and identified by immunoblotting. Guide RNA, shRNA, and siRNA sequences are listed in Supplementary Table 1.
Isolation of articular chondrocytes
Primary chondrocytes were isolated from the P1–P3 newborn mouse according to the previous protocol56. Briefly, skin and soft tissues were removed from the hind limb of the pups. Tibial plateau, femoral heads, and femoral condyles were dissected and harvested under sterile conditions. The collected tissues were washed in PBS for 20 min at 37 °C. The cartilage tissue was digested using Collagenase type I (200 U/ml, Roche) for 20 min at 37 °C to remove the soft tissue. Cartilage pieces were retrieved and incubated with digestion buffer (Collagenase type I (200 U/ml) and Collagenase type D (0.5 mg/ml)) for 60 min at 37 °C. After digestion, cell suspension was subjected to centrifugation at 400×g for 5 min. Primary chondrocytes were seeded in culture plates. Only the first passage cells were used for experiments.
RNA extraction and quantitative RT-PCR
Total RNA from cultured cells was isolated using TRIzol Reagent (Invitrogen, USA) according to the manufacture’s protocol. Two microgram total RNA was reversely transcribed using M-MLV Reverse Transcript Kit (Invitrogen, USA). Quantitative PCR was then performed using SYBR Green 2X PCR Master Mix (Applied Biosystems) on an Applied Biosystems 7900 system (Applied Biosystems, USA). Target gene threshold cycles (Ct values) were normalized to Gapdh as an endogenous control. The sequences of the primers are listed in Supplementary Table 1.
Primary chondrocytes or HEK293T cells were transfected with either pGL3-basic, NF-κB or Gal4/TEAD4-luciferase reporter plasmid together with pRL-TK vector (Promega, USA) as reference controls using Lipofectamine 3000 (Invitrogen, USA). Cells were subjected to luciferase activity measurement as described in Dual luciferase reporter assay kit (Promega, USA). NF-κB reporter plasmid was a gift from Dr. Zongping Xia (Zhejiang University). Gal4/TEAD4 luciferase reporter was a gift from Dr. Bin Zhao (Zhejiang University).
SDS-PAGE, Phos-tag SDS-PAGE, and immunoblot analysis
Gels for SDS-PAGE or Phos-tag SDS-PAGE were prepared according to the manufacturer’s instructions (NARD Institute). Equal amount of protein was loaded into each well and separated by SDS-PAGE or Phos-tag SDS-PAGE. After blocking in 5% milk or 3% BSA, the membrane was incubated with primary antibody at 4 °C overnight. The membrane was washed and subjected to incubation with the HRP-conjugated secondary antibody for 2 h at room temperature. Antibody information is described in Supplementary Table 2. Uncropped blot images are provided in Supplementary Figure 10.
After transfection with indicated plasmid for 24 h, HEK293T cell lysates were collected on ice. Twenty microliter Anti-Flag M2 magnetic beads or Anti-Myc Agarose Affinity Gel antibody was added to the lysate, incubated at 4 °C for 8 h under gentle agitation. The beads were washed with washing buffer for five times. Finally, the beads were eluted with 2 × SDS loading buffer. The eluted protein was analyzed by SDS/PAGE and followed by immunoblot analysis.
Primary articular chondrocytes or HEK293T cells were transfected with plasmids expressing Flag-YAP, Flag-IκBα, or HA-ubiquitin. Cells were pre-treated with MG132 at 10 μM for 2 h and then treated with TNFα at 5 ng/ml. Cell lysates were harvested and rocked with 20 μl Anti-Flag M2 magnetic beads at 4 °C for 8 h. The beads were washed five times. Bound proteins were boiled and analyzed by SDS/PAGE followed by immunoblot analysis. HA-ubiquitin plasmid was donated from Dr. CHEUNG Wing Tai (The Chinese University of Hong Kong). HA-K63-ubiquitin plasmid was a gift from Dr. Zongping Xia (Zhejiang University).
In vitro kinase assay
HA or Flag-tagged TAK1, IKKα/β, p65 and HA-YAP proteins were purified from HEK293T cells. GST-tagged YAP proteins were purified from E.coli by glutathione agarose slurry and eluted with glutathione. Purified proteins were washed with kinase washing buffer (40 mM Hepes and 200 mM NaCl, pH 7.5) for three times, and once with kinase assay buffer (30 mM Hepes, 50 mM KAC, and 5 mM MgCl2, pH 7.5). Purified kinase and YAP proteins were mixed with ATP or ATP-γ-S (500 μM) in kinase assay buffer. After 30 min kinase reaction in 30 °C, EDTA (final concentration 20 mM, pH 8.0) was added to terminate the reaction at 30 °C for 5 min. Then, PNBM (final concentration 2.5 mM) was added to form a thiophosphate ester side chain at 25 °C for 40 min. Western blot was performed using anti-Thiophosphate ester antibody or phospho-specific antibody to analyze the kinase activity.
Nano-liquid chromatography-tandem mass spectrometry analysis
Nano-liquid chromatography-tandem mass spectrometry (nano-LC-MS/MS) analysis for protein identification and label-free quantification was performed by Phoenix National Proteomics Core service57. YAP proteins were trypsin digested at 37 °C for 16 h and desalted using C18 Zip-Tips (Millipore) according to the manufacturer’s instructions. Next, the samples were resuspended in water and subjected to LC-MS/MS. The samples were separated using in-house made 12 cm length reverse phase columns (150 μm id) packed with Ultimate XB-C18 1.9 μm resin (Welch materials). The liquid chromatography was performed using an Easy nanoLC system (Thermo Fisher Scientific, USA). Phosphorylated peptides and site quantitation were carried out based on the extracted ion current chromatograms of the monoisotopic peaks. Tandem mass spectra corresponding to the putative phosphorylation-modified peptides and sites were verified by manual inspection of their fragmentation pattern.
Immunofluorescence and imaging analysis
Primary articular chondrocytes or HeLa cells were plated on coverslips. After treatment with TNFα or IL-1β at 5 ng/ml for 0, 15, 30, or 60 min, cells were then fixed with pre-cooled methanol on ice for 20 min. Cells were then washed with PBST (PBS, 0.1% Triton X-100), followed by blocking with 3% BSA at room temperature for 30 min. Cells were incubated with primary antibodies for YAP or p65, diluted in 3% BSA at 1:100 for 2 h at room temperature. After three washes with PBST, cells were incubated with secondary antibodies in 3% BSA for 2 h. Nuclei were stained with 0.5 μg/ml of DAPI (PBST) at room temperature for 10 min. Cells were mounted with ProLong® Gold Antifade (P36930, Thermo Fisher) and viewed with a Confocal system with inverted microscope (Olympus FV1000). Images were analyzed using the scientific software module of Imaris.
Safranin O staining
Safranin O staining was carried out according to the previous protocol (IHC World). The bone section slides were rehydrated to distilled water and stained with Weigert’s iron hematoxylin for 10 min. After washing in running water, the slides were stained with 0.05% Fast Green solution. The slides were put into 1% acetic acid directly without washing and incubated for no more than 15 s. Slides were stained with 0.1% Safranin O solution for 5 min. After washing in running water for 1 min, the slides were dehydrated and cleared with 95% ethyl alcohol, absolute ethyl alcohol, and xylene. Slides were mounted using resinous mounting medium.
Immunohistochemistry was performed according to the manufacture’s protocol of Histostain-Plus IHC Kit (Invitrogen, USA). Briefly, after deparaffinization and rehydration, slides were quenched in 3% H2O2 in methanol, rinsed three times in PBS. The slides were subjected to antigen retrieval using Trypsin for 20 min at 37 °C. After washing 3 times in PBS, the slides were incubated with blocking reagent for 30 min. The slides were incubated with primary antibodies, biotinylated secondary antibodies, enzyme conjugated substrate and developed with diaminobenzidine (DAB) chromogen.
The comparisons between multiple groups, such as OARSI scores, were performed using multiple comparisons by one-way ANOVA followed by Turkey’s test. For qRT-PCR data expressed as relative fold changes, Student’s t-test and one-way ANOVA with Dunnett’s test were used for pairwise comparisons and multi-group comparison, respectively. Results are represented as mean ± s.d. p values < 0.05 were considered to be significant. Equal variances were assumed. All analyses were performed with GraphPad Prism software (Version 6.0). No statistical methods were used to predetermine sample size. The experiments were not randomized and the investigators were not blinded to allocation during experiments and outcome assessment.
The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium via the PRIDE partner repository with the dataset identifier PXD01125658. All data supporting the conclusions are either provided in the manuscript or available from the authors upon request.
Poole, A. R. et al. Proteolysis of the collagen fibril in osteoarthritis. Biochem. Soc. Symp. 70, 115–123 (2003).
Pfander, D., Swoboda, B. & Kirsch, T. Expression of early and late differentiation markers (proliferating cell nuclear antigen, syndecan-3, annexin VI, and alkaline phosphatase) by human osteoarthritic chondrocytes. Am. J. Pathol. 159, 1777–1783 (2001).
von der Mark, K. et al. Type X collagen synthesis in human osteoarthritic cartilage. Indication of chondrocyte hypertrophy. Arthritis Rheum. 35, 806–811 (1992).
Fuerst, M. et al. Calcification of articular cartilage in human osteoarthritis. Arthritis Rheum. 60, 2694–2703 (2009).
Kuhn, K., D’Lima, D. D., Hashimoto, S. & Lotz, M. Cell death in cartilage. Osteoarthr. Cartil. 12, 1–16 (2004).
Pacifici, M. et al. Cellular and molecular mechanisms of synovial joint and articular cartilage formation. Ann. N. Y. Acad. Sci. 1068, 74–86 (2006).
Pacifici, M., Koyama, E. & Iwamoto, M. Mechanisms of synovial joint and articular cartilage formation: recent advances, but many lingering mysteries. Birth. Defects Res. C Embryo. Today 75, 237–248 (2005).
Yasuda, T. Activation of Akt leading to NF-kappaB up-regulation in chondrocytes stimulated with fibronectin fragment. Biomed. Res. 32, 209–215 (2011).
Kapoor, M., Martel-Pelletier, J., Lajeunesse, D., Pelletier, J. P. & Fahmi, H. Role of proinflammatory cytokines in the pathophysiology of osteoarthritis. Nat. Rev. Rheumatol. 7, 33–42 (2011).
Goldring, M. B. & Otero, M. Inflammation in osteoarthritis. Curr. Opin. Rheumatol. 23, 471–478 (2011).
Marcu, K. B., Otero, M., Olivotto, E., Borzi, R. M. & Goldring, M. B. NF-kappaB signaling: multiple angles to target OA. Curr. Drug. Targets 11, 599–613 (2010).
Rigoglou, S. & Papavassiliou, A. G. The NF-kappaB signalling pathway in osteoarthritis. Int. J. Biochem. Cell. Biol. 45, 2580–2584 (2013).
Pan, D. Hippo signaling in organ size control. Genes Dev. 21, 886–897 (2007).
Zhao, B., Tumaneng, K. & Guan, K. L. The Hippo pathway in organ size control, tissue regeneration and stem cell self-renewal. Nat. Cell Biol. 13, 877–883 (2011).
Yu, F. X., Zhao, B. & Guan, K. L. Hippo pathway in organ size control, tissue homeostasis, and cancer. Cell 163, 811–828 (2015).
Deng, Y. et al. Yap1 regulates multiple steps of chondrocyte differentiation during skeletal development and bone repair. Cell Rep. 14, 2224–2237 (2016).
Zhang, Q. et al. Hippo signalling governs cytosolic nucleic acid sensing through YAP/TAZ-mediated TBK1 blockade. Nat. Cell Biol. 19, 362–374 (2017).
Wang, S. et al. YAP antagonizes innate antiviral immunity and is targeted for lysosomal degradation through IKKvarepsilon-mediated phosphorylation. Nat. Immunol. 18, 733–743 (2017).
Moroishi, T. et al. The hippo pathway kinases LATS1/2 suppress cancer immunity. Cell 167, 1525–1539 e1517 (2016).
Pritzker, K. P. et al. Osteoarthritis cartilage histopathology: grading and staging. Osteoarthr. Cartil. 14, 13–29 (2006).
Yu, F. X. et al. Regulation of the Hippo-YAP pathway by G-protein-coupled receptor signaling. Cell 150, 780–791 (2012).
Liu-Chittenden, Y. et al. Genetic and pharmacological disruption of the TEAD-YAP complex suppresses the oncogenic activity of YAP. Genes Dev. 26, 1300–1305 (2012).
Robinson, W. H. et al. Low-grade inflammation as a key mediator of the pathogenesis of osteoarthritis. Nat. Rev. Rheumatol. 12, 580–592 (2016).
Zhao, B. et al. Inactivation of YAP oncoprotein by the Hippo pathway is involved in cell contact inhibition and tissue growth control. Genes Dev. 21, 2747–2761 (2007).
Zhao, B., Li, L., Tumaneng, K., Wang, C. Y. & Guan, K. L. A coordinated phosphorylation by Lats and CK1 regulates YAP stability through SCF(beta-TRCP). Genes Dev. 24, 72–85 (2010).
Ismail, H. M. et al. Interleukin-1 acts via the JNK-2 signaling pathway to induce aggrecan degradation by human chondrocytes. Arthritis Rheumatol. 67, 1826–1836 (2015).
Yaron, A. et al. Identification of the receptor component of the IkappaBalpha-ubiquitin ligase. Nature 396, 590–594 (1998).
Winston, J. T. et al. The SCFbeta-TRCP-ubiquitin ligase complex associates specifically with phosphorylated destruction motifs in IkappaBalpha and beta-catenin and stimulates IkappaBalpha ubiquitination in vitro. Genes Dev. 13, 270–283 (1999).
Spencer, E., Jiang, J. & Chen, Z. J. Signal-induced ubiquitination of IkappaBalpha by the F-box protein Slimb/beta-TrCP. Genes Dev. 13, 284–294 (1999).
Schlegelmilch, K. et al. Yap1 acts downstream of alpha-catenin to control epidermal proliferation. Cell 144, 782–795 (2011).
Silvis, M. R. et al. alpha-catenin is a tumor suppressor that controls cell accumulation by regulating the localization and activity of the transcriptional coactivator Yap1. Sci. Signal 4, ra33 (2011).
Grzeschik, N. A., Parsons, L. M., Allott, M. L., Harvey, K. F. & Richardson, H. E. Lgl, aPKC, and Crumbs regulate the Salvador/Warts/Hippo pathway through two distinct mechanisms. Curr. Biol. 20, 573–581 (2010).
Dupont, S. et al. Role of YAP/TAZ in mechanotransduction. Nature 474, 179–183 (2011).
Auphan, N., DiDonato, J. A., Rosette, C., Helmberg, A. & Karin, M. Immunosuppression by glucocorticoids: inhibition of NF-kappa B activity through induction of I kappa B synthesis. Science 270, 286–290 (1995).
Scheinman, R. I., Cogswell, P. C., Lofquist, A. K. & Baldwin, A. S. Jr. Role of transcriptional activation of I kappa B alpha in mediation of immunosuppression by glucocorticoids. Science 270, 283–286 (1995).
Liu, B. et al. Toll receptor-mediated hippo signaling controls innate immunity in Drosophila. Cell 164, 406–419 (2016).
Ye, S. et al. YAP1-mediated suppression of USP31 enhances NFkappaB activity to promote sarcomagenesis. Cancer Res. 78, 2705–2720 (2018).
Ninomiya-Tsuji, J. et al. A resorcylic acid lactone, 5Z-7-oxozeaenol, prevents inflammation by inhibiting the catalytic activity of TAK1 MAPK kinase kinase. J. Biol. Chem. 278, 18485–18490 (2003).
Kozhemyakina, E. et al. Identification of a Prg4-expressing articular cartilage progenitor cell population in mice. Arthritis Rheumatol. 67, 1261–1273 (2015).
Waller, K. A. et al. Role of lubricin and boundary lubrication in the prevention of chondrocyte apoptosis. Proc. Natl Acad. Sci. USA 110, 5852–5857 (2013).
Iqbal, S. M. et al. Lubricin/Proteoglycan 4 binds to and regulates the activity of Toll-Like Receptors In Vitro. Sci. Rep. 6, 18910 (2016).
Taniguchi, N. et al. Chromatin protein HMGB2 regulates articular cartilage surface maintenance via beta-catenin pathway. Proc. Natl Acad. Sci. USA 106, 16817–16822 (2009).
Taniguchi, N. et al. Aging-related loss of the chromatin protein HMGB2 in articular cartilage is linked to reduced cellularity and osteoarthritis. Proc. Natl Acad. Sci. USA 106, 1181–1186 (2009).
Zhao, B. et al. TEAD mediates YAP-dependent gene induction and growth control. Genes Dev. 22, 1962–1971 (2008).
Yang, B. et al. YAP1 negatively regulates chondrocyte differentiation partly by activating the beta-catenin signaling pathway. Int. J. Biochem. Cell. Biol. 87, 104–113 (2017).
Karystinou, A. et al. Yes-associated protein (YAP) is a negative regulator of chondrogenesis in mesenchymal stem cells. Arthritis Res. Ther. 17, 147 (2015).
Roelofs, A. J. et al. Joint morphogenetic cells in the adult mammalian synovium. Nat. Commun. 8, 15040 (2017).
Ismail, H. M., Didangelos, A., Vincent, T. L. & Saklatvala, J. Rapid activation of transforming growth factor beta-activated kinase 1 in chondrocytes by phosphorylation and K(63) -linked polyubiquitination upon injury to animal articular cartilage. Arthritis Rheumatol. 69, 565–575 (2017).
Gruber, J. et al. Induction of interleukin-1 in articular cartilage by explantation and cutting. Arthritis Rheum. 50, 2539–2546 (2004).
Burleigh, A. et al. Joint immobilization prevents murine osteoarthritis and reveals the highly mechanosensitive nature of protease expression in vivo. Arthritis Rheum. 64, 2278–2288 (2012).
Song, H. et al. Mammalian Mst1 and Mst2 kinases play essential roles in organ size control and tumor suppression. Proc. Natl Acad. Sci. USA 107, 1431–1436 (2010).
Xin, M. et al. Regulation of insulin-like growth factor signaling by Yap governs cardiomyocyte proliferation and embryonic heart size. Sci. Signal. 4, ra70 (2011).
Ovchinnikov, D. A., Deng, J. M., Ogunrinu, G. & Behringer, R. R. Col2a1-directed expression of Cre recombinase in differentiating chondrocytes in transgenic mice. Genesis 26, 145–146 (2000).
Brandt, K. D. Animal models of osteoarthritis. Biorheology 39, 221–235 (2002).
D’Souza, W. N., Ng, G. Y., Youngblood, B. D., Tsuji, W. & Lehto, S. G. A review of current animal models of osteoarthritis pain. Curr. Pharm. Biotechnol. 12, 1596–1612 (2011).
Gosset, M., Berenbaum, F., Thirion, S. & Jacques, C. Primary culture and phenotyping of murine chondrocytes. Nat. Protoc. 3, 1253–1260 (2008).
Ding, C. et al. Proteome-wide profiling of activated transcription factors with a concatenated tandem array of transcription factor response elements. Proc. Natl Acad. Sci. USA 110, 6771–6776 (2013).
Deutsch, E. W. et al. The ProteomeXchange Consortium in 2017: supporting the cultural change in proteomics public data deposition. Nucleic Acids Res. 54, D1100–D1106 (2017).
We thank members of the Song’s and Mak’s groups for stimulating discussion. We thank Drs. Zongping Xia, Pinglong Xu, and Bin Zhao at Life Sciences Institute, Zhejiang University for the reagents and helpful discussion. This work was supported by the National Natural Science Foundation of China (grant number 31471368) and the Zhejiang Provincial Natural Science Foundation of China (grant number LR16C120001) to H.S., and the National Natural Science Foundation of China (grant number 81700002) and the International Postdoctoral Research Fellowship Program to Y.D., and the Seed Fund of the School of Biomedical Sciences, The Chinese University of Hong Kong (4620504) to K.M. H.S. is a scholar in the National 1000 Young Talents Program.
The authors declare no competing interests.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Deng, Y., Lu, J., Li, W. et al. Reciprocal inhibition of YAP/TAZ and NF-κB regulates osteoarthritic cartilage degradation. Nat Commun 9, 4564 (2018). https://doi.org/10.1038/s41467-018-07022-2
Biomarker Research (2022)
Resolvin D1 inhibits the proliferation of osteoarthritis fibroblast-like synoviocytes through the Hippo-YAP signaling pathway
BMC Musculoskeletal Disorders (2022)
Selenophosphate synthetase 1 deficiency exacerbates osteoarthritis by dysregulating redox homeostasis
Nature Communications (2022)
Bone Research (2022)
Fusobacterium nucleatum reduces METTL3-mediated m6A modification and contributes to colorectal cancer metastasis
Nature Communications (2022)