Abstract
An imbalance in the differentiation potential of bone marrow mesenchymal stem cells (BMSCs) is an important pathogenic mechanism underlying osteoporosis (OP). N6-methyladenosine (m6A) is the most common post-transcriptional modification in eukaryotic cells. The role of the Wilms’ tumor 1-associated protein (WTAP), a member of the m6A functional protein family, in regulating BMSCs differentiation remains unknown. We used patient-derived and mouse model-derived samples, qRT-PCR, western blot assays, ALP activity assay, ALP, and Alizarin Red staining to determine the changes in mRNA and protein levels of genes and proteins associated with BMSCs differentiation. Histological analysis and micro-CT were used to evaluate developmental changes in the bone. The results determined that WTAP promoted osteogenic differentiation and inhibited adipogenic differentiation of BMSCs. We used co-immunoprecipitation (co-IP), RNA immunoprecipitation (RIP), methylated RNA immunoprecipitation (MeRIP), RNA pulldown, and dual-luciferase assay to explore the direct mechanism. Mechanistically, the expression of WTAP increased during osteogenic differentiation and significantly promoted pri-miR-181a and pri-miR-181c methylation, which was recognized by YTHDC1, and increased the maturation to miR-181a and miR-181c. MiR-181a and miR-181c inhibited the mRNA expression of SFRP1, promoting the osteogenic differentiation of BMSCs. Our results demonstrated that the WTAP/YTHDC1/miR-181a and miR-181c/SFRP1 axis regulated the differentiation fate of BMSCs, suggesting that it might be a potential therapeutic target for osteoporosis.
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Introduction
Osteoporosis is a common systemic skeletal disorder characterized by low bone mass and destruction of the bone microstructure, gradually resulting in bone fragility and increased fracture risk [1,2,3,4]. During osteoporosis, the adipogenic differentiation of bone marrow mesenchymal stem cells (BMSCs) is enhanced, and osteogenic differentiation is weakened. An imbalance in the differentiation of BMSCs is the main cause of osteoporosis [5]. Understanding the mechanism of osteogenic differentiation of BMSCs holds the key to the development of therapeutic interventions for osteoporosis [6].
N6-methyladenosine (m6A) is the most common post-transcriptional RNA modification in eukaryotic cells and is carried out by the RNA methyltransferase complex, which comprises methyltransferase-like 3 (METTL3), methyltransferase-like 14 (METTL14), and Wilms’ tumor 1-associated protein (WTAP) [7,8,9,10,11,12,13]. This process can be reversed by “erasers,” such as demethylases, including alkylation repair homolog protein 5 (ALKBH5) and fat mass and obesity-associated protein (FTO) [14,15,16,17,18]. The transcripts modified with m6A could be identified by “readers,” such as YT521-B homology (YTH) domain-containing proteins (YTHDF1-3, YTHDC1, and YTHDC2) and insulin-like growth factor 2 mRNA-binding proteins (IGF2BPs; including IGF2BP1/2/3) to achieve the corresponding functional adjustment [19,20,21,22,23]. Several studies have demonstrated that m6A methylation regulates the balance between osteogenesis and adipogenesis of BMSCs [24,25,26,27], yet how m6A modification is involved in the pathogenesis of osteoporosis remains relatively unknown.
MicroRNAs (miRNAs) are small noncoding RNAs that negatively regulate gene expression by interacting with target mRNAs to destabilize them or restrain their translation [28,29,30,31]. MiRNAs regulate up to 60% of the human protein-coding genes. Several studies have reported that miRNAs are widely involved in bone proliferation, apoptosis, and inflammation [26, 27]. MiRNAs play a major role in regulating BMSCs differentiation, which seems to be closely correlated with the pathogenesis of osteoporosis [28]. MiR-26b regulates subchondral BMSCs through β-catenin and reduces the bone loss caused by abnormal occlusion [32]. Thus, further investigation of the function of miRNAs in the etiology, treatment, and prognosis of osteoporosis is urgently needed.
This study aimed to investigate whether the interaction between m6A modification and miRNAs could regulate the osteogenic differentiation ability of BMSCs and thus affect osteoporosis. Our study showed that the expression of WTAP was lower in patients with osteoporosis than in normal controls, and the expression of WTAP increased during osteogenic induction. Increasing the expression of WTAP significantly enhanced the m6A modification of pri-miR-181a and pri-miR-181c. After that, YTHDC1 recognizes the methylation modification of pri-miR-181a and pri-miR-181c and promotes its maturation. Elevated expression of miR-181a and miR-181c resulted in decreased expression of the target gene secreted frizzled-related protein 1 (SFRP1), which promoted the osteogenic differentiation of BMSCs. Our research revealed that WTAP could promote osteogenic differentiation and inhibit adipogenic differentiation of BMSCs through the YTHDC1/ miR-181a and miR-181c /SFRP1 axes, which could be of significance in developing therapeutic targets for osteoporosis.
Results
The expression of WTAP was decreased in the bone tissue of osteoporosis patients and ovariectomized mice
To investigate the potential role of m6A methylation in osteogenic differentiation, we first compared m6A methylation levels in bone tissues of patients with osteoporosis and found that m6A levels were decreased compared to those in normal individuals (Fig. 1A). To elucidate the regulatory mechanism of m6A modification, we analyzed the expression of methylase and demethylase during osteogenic differentiation of BMSCs by qRT-PCR and WB, and the results showed that the expression of methylase WTAP was significantly increased (Fig. 1B, C). Therefore, we collected patient samples for verification, and both qRT-PCR and WB showed that the expression of WTAP in the bone tissues of osteoporosis patients was significantly decreased (Fig. 1D, E). We established an ovariectomized (OVX) mouse model of osteoporosis. The WTAP expression level in the bone tissue of OVX mice was also significantly reduced compared with that in the sham group after 2 months (Fig. 1F, G). These results indicate that WTAP expression is down-regulated in osteoporotic bone tissue. However, it is not clear how WTAP expression changes during BMSCs differentiation. Therefore, we used qRT-PCR and WB to determine whether WTAP was specifically up-regulated during osteogenic differentiation and down-regulated during adipogenic differentiation (Supplementary Fig. 1A and Fig. 1H).
WTAP promoted osteogenic differentiation of BMSCs and impaired adipogenic differentiation
Next, we investigated the role of WTAP in BMSCs differentiation. The WTAP overexpression (OE-WTAP) virus was used to transfect mouse primary BMSCs, and the overexpression efficiency was confirmed by qRT-PCR and WB (Supplementary Fig. 1B and Fig. 1I). As shown in Supplementary Fig. 1C, OE-WTAP promoted the transcription of osteogenesis-related genes including collagen type I (Col1), runt-related transcription factor 2 (Runx2), alkaline phosphatase (Alp), bone morphogenetic protein-2 (Bmp2), and osteopontin (Opn) during osteogenic differentiation. The protein levels of COL1, RUNX2, BMP2, and OPN showed the same trend (Fig. 1J). Furthermore, ALP activity, ALP staining, and alizarin red staining showed that ALP activity and extracellular matrix mineralization were significantly increased in the OE-WTAP group (Fig. 1K, L). On the other hand, overexpression of WTAP decreased the adipogenic ability of BMSCs. Both mRNA (lipoprotein lipase(Lpl), adipocyte-specific fatty acid-binding protein (aP2), CCAAT/enhancer-binding protein α(C/ebpα), CCAAT/enhancer-binding protein-beta (C/ebpβ), peroxisome proliferator-activated receptor-γ (Ppar-γ) (Supplementary Fig. 1D)) and protein (PPAR-γ, C/EBPα, and C/EBPβ (Fig. 1M)) levels of adipogenic genes were decreased in OE-WTAP group during adipogenic differentiation. Lentivirus-mediated knockdown of WTAP (Supplementary Fig. 1E and Fig. 1N) reduced osteogenic gene expression (Supplementary Fig. 1F and Fig. 1O), ALP activity, and extracellular matrix calcification (Fig. 1P, Q) during osteogenic differentiation and increased the expression of adipogenic genes during adipogenic differentiation (Supplementary Fig. 1G and Fig. 1R). Our preliminary results suggest that WTAP can simultaneously increase the osteogenic potential of BMSCs and decrease their adipogenic potential.
WTAP supplementation decreases bone loss induced by ovariectomy
To evaluate the potential role of WTAP in bone loss induced by ovariectomy, ovariectomized 10-week-old mice were treated with an intravenous injection of WTAP overexpression lentivirus or control lentivirus starting 3 days after ovariectomy (Fig. 2A). WTAP expression decreased in the BMSCs of OVX mice and increased in OVX+ OE-WTAP mice 2 months later (Supplementary Fig. 2A). Bone mass was compared among sham-operated (Sham), ovariectomized (OVX), negative control lentivirus-treated OVX (OVX+ Vector), and WTAP-overexpressing lentivirus-treated OVX mice (OVX+ OE-WTAP). Hematoxylin-eosin (H&E) staining (Fig. 2B) and Masson’s staining (Supplementary Fig. 2B) revealed that trabecular bone was significantly less in the femurs of OVX mice than in those of Sham mice. Staining also showed that WTAP overexpression decreased trabecular bone loss in OVX+ Vector mice. Micro-CT analysis revealed that WTAP overexpression decreased ovariectomy-induced bone loss (Fig. 2C, D). In addition, advanced osteoblastic bone formation after WTAP overexpression was confirmed by calcein double-labeling analysis (Fig. 2E). WTAP overexpression increased COL1, RUNX2, BMP2, and OPN expression in femur samples from ovariectomized mice, as evidenced by immunohistochemical staining analysis (Fig. 2F and Supplementary Fig. 2C). To evaluate the effect of WTAP supplementation on the osteogenic and adipogenic differentiation of BMSCs, BMSCs were isolated from sham, OVX, OVX+ Vector, and OVX+ OE-WTAP mice, and their osteogenic and adipogenic differentiation activities were compared. WTAP overexpression not only advanced osteoblastic differentiation (Fig. 2G, H) but also dampened adipogenic differentiation (Fig. 2I, J) of BMSCs after ovariectomy. Taken together, these results demonstrate that WTAP supplementation decreases ovariectomy-induced bone loss.
WTAP promoted osteogenic differentiation of BMSCs and impaired adipogenic differentiation of BMSCs by promoting the expression of miR-181a and miR-181c
It has been demonstrated that m6A methylation promotes post-transcriptional modification of miRNAs. To explore the mechanism by which WTAP regulates BMSCs differentiation, we performed high-throughput miRNA sequencing of BMSCs in the Vector and OE-WTAP groups during osteogenic differentiation (Fig. 3A). We used qRT-PCR to verify the sequencing results in BMSCs from mice in the Vector and OE-WTAP group and found 9 miRNAs were highly expressed after WTAP overexpression during osteogenic differentiation (Fig. 3B). We used bone samples from osteoporosis patients for verification and found that the expression levels of miR-181a and miR-181c were decreased in the bone tissues of the patients (Fig. 3C). Further evaluation showed that the expression of miR-181a and miR-181c in bone tissue (Fig. 3D) and circulating plasma (Fig. 3E) in osteoporosis patients was down-regulated. The same trend was observed in the femur bone of sham-operated (normal) and ovariectomized (OVX) mice (Fig. 3F). At the cellular level, we first conducted osteogenic induction of BMSCs and found that the expression of miR-181a and miR-181c increased (Fig. 3G). In contrast, the expression of miR-181a and miR-181c significantly decreased after WTAP knockdown (Fig. 3H).
Next, we explored the effects of miR-181a and miR-181c on the differentiation potential of BMSCs. BMSCs were treated with miRNA mimics or inhibitors, and gene interference efficiency was determined by qRT-PCR (Supplementary Fig. 3A). The results showed that miR-181a and miR-181c mimics increased the expression levels of osteogenic-related genes in BMSCS during osteogenic induction (Fig. 3I and Supplementary Fig. 3B, D, E). ALP activity and extracellular matrix mineralization were also significantly increased (Fig. 3J, K, and Supplementary Fig. 3F, G). In contrast, miR-181a and miR-181c inhibitors reduced the expression of osteogenic-related genes (Fig. 3I and Supplementary Fig. 3B, D, E), ALP activity, and extracellular matrix calcification (Fig. 3J, K, and Supplementary Fig. 3F, G) in BMSCs. During adipogenic induction, miR-181a and miR-181c mimics reduced the gene expression levels of adipogenic genes in BMSCs, while miRNA inhibitors increased those in BMSCs (Fig. 3L and Supplementary Fig. 3C, H, I).
MiR-181a and miR-181c mimics and inhibitors rescued the effect of WTAP intervention on osteogenic differentiation of BMSCs
When we transfected the WTAP-overexpressing cells with the miR-181a and miR-181c inhibitor, we observed a partial inhibition of the increased expression of osteogenic differentiation markers (Fig. 4A, E and Supplementary Fig. 4A, C) as well as increased ALP activity and extracellular matrix mineralization (Fig. 4B, C, F, H). The decreased expression of adipogenic differentiation-related markers was also partially rescued by miR-181a and miR-181c inhibitors (Fig. 4D, G, and Supplementary Fig. 4B, D).
When WTAP-knockdown cells were transfected with miR-181a and miR-181c mimics, we found that miR-181a and miR-181c mimics increased the expression of osteogenic differentiation markers (Supplementary Fig. 4E, F, K, L), ALP activity, and extracellular matrix mineralization (Supplementary Fig. 4G, H, M, N). However, adipogenic differentiation promoted by WTAP-knockdown cells was blocked by miR-181a and miR-181c mimics (Supplementary Fig. 4I, J, O, P).
In conclusion, WTAP affects the differentiation ability of BMSCS by altering the expression of miR-181a and miR-181c.
WTAP-mediated m6A modification of pri-miR-181a and pri-miR-181c promotes its maturation
To explore whether WTAP regulates the expression of miR-181a and miR-181c through m6A modification, we measured m6A levels in cells and found that m6A levels increased during osteogenic differentiation, and the trend of m6A was in line with WTAP expression (Fig. 5A). Next, we studied the relationship between WTAP, miR-181a, and miR-181c expression. During osteogenic differentiation of BMSCs, pri-miR-181a and pri-miR-181c decreased, while miR-181a and miR-181c increased. As expected, when WTAP was overexpressed, pri-miR-181a and pri-miR-181c levels decreased, while miR-181a and miR-181c accumulated. However, when WTAP was knocked down, pri-miR-181a and pri-miR-181c accumulated, whereas mature miR-181a and miR-181c decreased (Fig. 5B). The results of MeRIP showed that osteogenic differentiation of MSCs led to the hypermethylation of pri-miR-181a and pri-miR-181c (Fig. 5C). Furthermore, MeRIP also showed that WTAP overexpression significantly increased the methylation of pri-miR-181a and pri-miR-181c (Fig. 5D), whereas WTAP knockdown significantly abrogated the methylation of pri-miR-181a and pri-miR-181c (Fig. 5E). These findings suggest that WTAP promotes the transition of pri-miR-181a and pri-miR-181c to mature miR-181a and miR-181c. The results of MeRIP also showed there are no m6A modifications on the miR-181a and miR-181c (Supplementary Fig. 5A–C). To elucidate the regulatory mechanism of m6A modification, we analyzed the expression of methylase and demethylase during osteogenic differentiation of BMSCs using WB, and the results showed that the expression of methylase WTAP was significantly increased (Fig. 1C). Co-IP analysis showed that METTL3 and METTL14 interacted with WTAP to form a methyltransferase complex during osteogenic differentiation (Fig. 5F). This may induce hypermethylation of pri-miR-181a and pri-miR-181c. Subsequently, we performed RNA pull-down and WB and detected osteogenic differentiation (Fig. 5G) and increased WTAP expression (Fig. 5H), promoting the interaction between pri-miR-181a and pri-miR-181c and methyltransferase complexes, including METTL3 and METTL14. Moreover, the knockdown of WTAP abolished the interaction of pri-miR-181a and pri-miR-181c with METTL3 and METTL14 (Fig. 5I). These results suggest that WTAP-mediated m6A modification of pri-miR-181a and pri-miR-181c contributes to the osteogenic differentiation of BMSCs.
Bioinformatics analysis revealed the presence of possible methylation sites GGACU and GGACC motifs in the exon region of pri-miR-181a and pri-miR-181c transcripts, respectively. A double luciferase reporter containing wild-type or mutant pri-miR-181a and pri-miR-181c sequences before firefly luciferase was constructed, in which A at the m6A site was replaced by U (Fig. 5J). The results showed that WTAP overexpression significantly reduced the luciferase activities of pri-miR-181a and pri-miR-181c wild-type reporters compared to mutant-type reporters. Knockdown of WTAP increased the luciferase activities of the pri-miR-181a and pri-miR-181c wild-type reporters (Fig. 5K). Luciferase activity showed that the point mutation decreased the modification of pri-miR-181a and pri-miR-181c by WTAP. These results suggest that increased m6A modification by WTAP up-regulates pri-miR-181a and pri-miR-181c maturation.
YTHDC1-mediated methylation recognition promoted the maturation of pri-miR-181a and pri-miR-181c
To elucidate the regulatory mechanism of WTAP on pri-miR-181a and pri-miR-181c, we investigated whether readers are involved in regulating miR-181a and miR-181c biogenesis. RNA pull-down and WB showed that the expression of the readers did not change significantly during osteogenic induction. WB also showed that pri-miR-181a-m6A and pri-miR-181c-m6A instead of pri-miR-181a and pri-miR-181c were directly bound to YTHDC1 (Fig. 6A, D and Supplementary Fig. 5D). However, osteogenic differentiation did not increase the expression of YTHDC1 or the interaction between pri-miR-181a-m6A, pri-miR-181c-m6A, and YTHDC1 (Fig. 6A, D). Similar results were found in WTAP overexpression cells (Fig. 6B, E) and WTAP-knockdown cells (Fig. 6C, F). In addition, RIP confirmed the direct coupling of YTHDC1 with pri-miR-181a and pri-miR-181c (Fig. 6G). Moreover, the interaction increased in WTAP overexpression cells (Fig. 6H) and decreased in WTAP-knockout cells (Fig. 6I). Therefore, we hypothesized that YTHDC1 was a ‘reader’ of pri-miR-181a and pri-miR-181c after methylation, although its expression did not change with osteogenic differentiation.
To confirm this hypothesis, we conducted functional tests. First, we screened three small interference RNAs for knocking out YTHDC1 and chose siYTHDC1-2, with the highest knockout efficiency, for all subsequent experiments (Fig. 6J and Supplementary Fig. 5E). We found that the expression of pri-miR-181a and pri-miR-181c in the cells was increased, and the expression of miR-181a and miR-181c was decreased with YTHDC1 knockout (Fig. 6K). We also conducted functional experiments and concluded that the osteogenic differentiation ability of MSCS after YTHDC1 knockout was weakened (Fig. 6L–N and Supplementary Fig. 5F), and the adipogenic differentiation potential was enhanced (Fig. 6O and Supplementary Fig. 5G), consistent with the expression of miR-181a and miR-181c.
We then conducted phenotypic recovery assays to determine whether WTAP promotes miR-181a and miR-181c expression via YTHDC1. Knockdown of YTHDC1 in BMSCs restored the changes induced by the overexpression of WTAP, including miR-181a and miR-181c expression (Supplementary Fig. 5H), osteogenic differentiation potential (Supplementary Fig. 5I-L) as well as adipogenic differentiation potential (Supplementary Fig. 5M, N). This suggests that WTAP regulates miR-181a and miR-181c expression through YTHDC1. On the other hand, transfection with miR-181a (Supplementary Fig. 6A–F) and miR-181c mimics (Supplementary Fig. 6G–L) restored the effect of YTHDC1 knockout on the differentiation ability of BMSCs, suggesting that YTHDC1 knockdown regulated the differentiation of BMSCs through miR-181a and miR-181c. Therefore, our data proved that YTHDC1 is an indispensable regulator of WTAP that promotes pri-miR-181a and pri-miR-181c biogenesis.
SFRP1 is a common downstream target of miR-181a and miR-181c in BMSCs
miRNAs inhibit gene expression mainly by binding and silencing the 3′-UTR region. Therefore, we used TargetScan and mirWalk to screen for possible downstream targets of miR-181a and miR-181c, respectively. We focused on SFRP1 because of its important role in the osteogenic differentiation of BMSCs. The expression of SFRP1 in osteoporotic bone tissues was higher than in normal tissue samples (Fig. 7A, B). Similar results were observed in the bone tissues of ovariectomized mice (Fig. 7C, D). To further explore the direct relationship between miR-181a, miR-181c, and SFRP1, we constructed a dual-luciferase reporter gene containing the 3′UTR of SFRP1 and the mutant 3′UTR of SFRP1 (Fig. 7E). The results showed that miR-181a and miR-181c mimics significantly reduced the luciferase activity of the SFRP1 wild-type reporter gene compared to that of the mutant reporter gene (Fig. 7F). Manipulating the expression of WTAP, miR-181a, and miR-181c showed that the expression of SFRP1 was directly related to phenotypic changes (Fig. 7G–I and Supplementary Fig. 7A–D). We also manipulated the expression of WTAP and miR simultaneously, and the results showed that the decreased expression of SFRP1 in the OE-WTAP group could be reversed at the mRNA and protein levels in cells co-transfected with OE-WTAP and miR inhibitors. In contrast, the increase in SFRP1 levels in the shWTAP group was reversed in cells co-transfected with shWTAP and miR mimics (Fig. 7J–M and Supplementary Fig. 7E–H). We then directly knocked down SFRP1 expression (Fig. 7N and Supplementary Fig. 7I), which resulted in a decrease in the osteogenic differentiation potential (Fig. 7O–R) and an increase in the adipogenic differentiation ability (Fig. 7S, T) of BMSCs. We simultaneously transfected siSFRP1, miR-181a, and miR-181c inhibitors into cells and found that phenotypic changes caused by miR-181a and miR-181c inhibitors were restored by siSFRP1 (Supplementary Fig. 7J–U). These results indicate that miR-181a and miR-181c can directly bind to the 3’UTR of SFRP1, promote osteogenic differentiation, and inhibit adipogenic differentiation by negatively regulating the expression of SFRP1. These results demonstrated that the WTAP/YTHDC1/miR-181a and miR-181c/SFRP1 axes promote osteogenic differentiation and inhibit the adipogenic differentiation of BMSCs.
Discussion
Bone is continuously remodeled in a dynamic process in which osteoblasts are responsible for bone formation [33]. Osteoblasts are mainly derived from BMSCs in the bone marrow stroma and have the potential to differentiate into various functional cell types under certain conditions. Promoting the osteogenic differentiation of BMSCs is crucial for treating metabolic bone diseases like osteoporosis [2].
m6A regulates various pathological and physiological processes, including the multidirectional differentiation of BMSCs [24]. Many studies have shown that m6A modification regulates the balance between the osteogenic and adipogenic differentiation of BMSCs [15, 26, 27, 31, 32, 34]. For example, Mettl3 overexpression in BMSCs protected mice from estrogen deficiency-induced osteoporosis [26]. The m6A “reader,” YTHDF1, can promote the osteogenesis of BMSCs through translational regulation of ZNF839 [22]. Alkbh1-mediated DNA N6-methyladenine modification promotes osteogenic differentiation of BMSCs [18]. FTO regulates adipogenesis by controlling the cell cycle via an m6A-YTHDF2-dependent mechanism [16].
However, the mechanism by which WTAP regulates BMSCs differentiation of BMSCs is not well-studied [35,36,37]. WTAP is an important member of the m6A methyltransferase complex of cellular mRNA [35,36,37,38,39,40]. Most mRNAs bound to WTAP and METTL3 contain a consensus m6A motif [9, 10]. The RNA-binding capacity of METTL3 was greatly reduced in the absence of WTAP, suggesting that WTAP may play a role in regulating the recruitment of the m6A methyltransferase complex to mRNA targets [41].
We found that WTAP was up-regulated during osteogenic differentiation and down-regulated during the adipogenic differentiation of BMSCs. In addition, WTAP was significantly down-regulated in the bone tissue of patients with osteoporosis. Functional studies revealed that WTAP promoted osteogenic differentiation and inhibited adipogenic differentiation of BMSCs both in vitro and in vivo.
To explore the mechanism by which WTAP regulates the osteogenic differentiation of BMSCs, we conducted miRNA sequencing and found that miR-181a and miR-181c were highly expressed when WTAP was overexpressed. Some studies have confirmed the role of miR-181c in osteoporosis diagnosis [42, 43], but the mechanism underlying the changes in expression has not yet been investigated. Further, the correlation between miR-181a and miR-181c and BMSCs differentiation has not been clarified. We measured the expression of miRNAs in the plasma and bone tissue and found that miR-181a and miR-181c could be used as diagnostic markers of osteoporosis. miR-181a and miR-181c promoted osteogenic differentiation and inhibited adipogenic differentiation of BMSCs.
Furthermore, we found that WTAP was significantly up-regulated and interacted with METTL3 and METTL14 to increase the formation of the methyltransferase complex during osteogenic differentiation, thereby enhancing m6A modification of pri-miR-181a and pri-miR-181c. The methylation sites of pri-miR-181a and pri-miR-181c were confirmed by a luciferase assay, which also indicated that WTAP promoted the expression of miR-181a and miR-181c by methylating pri-miR-181a and pri-miR-181c.
mRNA transcripts with m6A modifications are typically regulated by YTH or IGF2BP [19,20,21,22,23, 44]. To elucidate the m6A modified reader, we performed an RNA pull-down assay and confirmed that YTHDC1 is a reader of pri-miR-181a and pri-miR-181c. We demonstrated that YTHDC1 depletion resulted in an overall reduction of miR-181a and miR-181c and concomitant accumulation of pri-miR-181a and pri-miR-181c in BMSCs, suggesting that YTHDC1-mediated decay of pri-miR-181a and pri-miR-181c mRNA is, at least in part, due to the reduced stability of its mRNA transcript.
MiRNAs generally inhibit the expression of target genes by binding to the 3′-UTR region [29]. We identified SFRP1 as a downstream target of miR-181a and miR-181c. SFRP1 is an antagonist of the Wnt signaling pathway, which is important for maintaining bone homeostasis. SFRP1 deficiency results in reduced apoptosis of osteoblasts and osteocytes [42, 45]. Therefore, WTAP-mediated up-regulation of miR-181a and miR-181c further regulated BMSCs differentiation by negatively regulating the expression of SFRP1.
However, this study has many limitations. For example, the mechanism of WTAP up-regulation during osteogenic differentiation has not yet been fully elucidated. WTAP itself, as a protein-coding gene, can be modified by methylation, acetylation, or other post-transcriptional regulators. Although METTL3 and METTL14 were not up-regulated during osteogenic differentiation, their binding to WTAP was enhanced. It is unclear how METTL3 and METTL14 are involved in BMSCs differentiation together with WTAP. Further studies are needed to elucidate the important role of m6A modification in BMSCs differentiation.
In summary, our study proposed a mechanism of WTAP in the process of BMSCs differentiation and revealed that WTAP up-regulated the m6A modification of pri-miR-181a and pri-miR-181c. Furthermore, the expression levels of miR-181a and miR-181c were increased by YTHDC1, which resulted in the downregulation of SFRP1 expression and osteogenic differentiation. These results suggest that WTAP may serve as a potential therapeutic target for metabolic bone disease.
Methods
Human specimens
The specimens were obtained from female patients and control subjects without osteoporosis or other bone-related anomalies. All subjects with other diseases and smoking or drinking histories were excluded. All participants signed written informed consent. Specimen collection was conducted by the Department of Orthopedics, Qilu Hospital of Shandong University. This study was approved by the Medical Ethics Committee of the Qilu Hospital of Shandong University.
Ethics statement
We collected serum and bone samples from female OP patients and healthy female volunteers without OP and other bone-related anomalies from the Department of Orthopedics, Qilu Hospital of Shandong University (Jinan, Shandong, China). The experiments were approved by the Medical Ethics Committee of Shandong University Qilu Hospital.
Cell culture
All mice used in this study were maintained in a specific pathogen-free (SPF) facility. After anesthesia, primary BMSCs were isolated from the tibia and femur of 8-week-old mice by flushing the bone marrow with α-minimum essential medium (α-MEM). Cells were seeded in 100 mm culture dishes and cultured in α-MEM. After 16 h of culture, the adherent cells were harvested for BMSCs culture. Osteogenesis was induced using 10 mM β-glycerophosphate, 10 nM dexamethasone, and 50 μg/mL ascorbic acid. Adipogenesis was induced using 10 mg/mL insulin, 500 mmol/L methyl isobutyl xanthine, and 1 μmol/L dexamethasone.
Mouse model for osteoporosis
All animal experiments were approved by the Animal Ethics Committee of Qilu Hospital of Shandong University. Female C57BL/6 mice (10 weeks old) were randomly divided into four groups (6 mice per group). Ovariectomies or sham operations were performed under general anesthesia. Bilateral ovaries were removed under sterile conditions. In the sham group, only part of the adipose tissue around the ovary was removed. The lentiviral intramedullary injection was administered 4 weeks after ovariectomy. As previously described [46], a 5-mm longitudinal incision was made along the medial side of the quadriceps femoris patella complex. Lateral dislocation of the patella was performed to expose the intercondylar sulcus. A fine Kirschner wire was drilled in, a 26-gauge needle was inserted, and 15 μL of WTAP overexpression lentivirus (5 × 107/mL) was injected into the medullary cavity. The quadriceps femoris patella complex was then resutured. In the same way, 15 μL of lentiviral vector (5 × 107/mL) was injected into the femurs of mice in the osteoporosis group. All mice were sacrificed two months later, and BMSCs were isolated from three random mice from each group. BMSCs undergo osteogenic and adipogenic differentiation under certain conditions. Micro-CT scanning and histological analysis were performed on all the mouse samples.
MicroRNA mimic, inhibitor, and lentivirus/siRNA transfection
The miRNA mimics, miRNA inhibitors, and siRNAs (GenePharma Co., China) were used for gene overexpression or knockdown. The siRNA sequences are shown in Supplementary Table 1. Before transfection, the BMSCs culture media was removed, and fresh serum-free media (Gibco) was added. For miRNA mimic, miRNA inhibitor, siRNA, or negative control transfection, Lipofectamine 2000 transfection agent (Invitrogen, USA) was used, following the manufacturer’s instructions. Lentivirus transfection [negative control (Vector), WTAP overexpression lentivirus (OE-WTAP), negative control (shNC), and WTAP-knockdown lentivirus (shWTAP)] was performed at a 30–50% cell density. The culture medium was replaced 6–12 h after transfection and every 3 days until the cells reached 80–90% confluency. After 72 h of transfection, stably transfected cell lines were selected using 2 μg/mL puromycin.
RNA extraction and real-time quantitative polymerase chain reaction
TRIzol (Invitrogen, USA) was used to extract RNA from the tissues or cells. cDNA was synthesized from the extracted mRNA using the Prime Script RT Reagent Kit (Takara Bio Inc., Japan) according to the standard procedure. SYBR Premix Ex Taq was used for quantitative real-time reverse transcription polymerase chain reaction (qRT-PCR). A Light Cycler 480 System (Roche Applied Science, Germany) was used for the qualitative analysis. The allele-specific primers used in this study are listed in Supplementary Table 1.
Western blotting (WB) and co-immunoprecipitation (co-IP)
Before protein extraction, the cells were washed twice with phosphate-buffered saline (PBS). Total proteins of specific samples were extracted on ice using a protein extraction kit (BestBio, China) following the manufacturer’s instructions. The protein concentration was determined using a BCA Protein Assay Kit (Beyotime, China). The proteins were mixed with 5× SDS–PAGE loading buffer (Beyotime, China) and boiled for 5–10 min. Proteins were resolved using the PAGE Gel Fast Preparation Kit (Epizyme, USA) and transferred to polyvinylidene fluoride (PVDF) membranes (Millipore Sigma, USA). The primary antibodies used for western blot (WB) analysis are listed in Supplementary Table 2. All antibodies were diluted according to the manufacturer’s instructions.
For co-IP, whole-cell extracts were prepared in a lysis buffer after specific treatment. The extracts were incubated with the corresponding antibodies overnight at 4 °C. Protein A&G beads (Invitrogen) were added and incubated for 4 h at 4 °C, followed by washing and elution with SDS-loading buffer at 95 °C for 5 min. The eluted proteins were then identified by WB.
Alkaline phosphatase (ALP) activity assay
Alkaline phosphatase activity was determined using the alkaline phosphatase detection kit (Beyotime, China) following the manufacturer’s protocol. Briefly, cells were lysed with cell lysis buffer (not containing phosphatase inhibitors), and the supernatant was centrifuged for alkaline phosphatase detection. The absorbance of the supernatant at 405 nm was measured using a spectrophotometer (Bio-Rad). The alkaline phosphatase activity of the samples was calculated based on the absorbance of the blank control, standard, and sample.
Alkaline phosphatase staining
A BCIP/NBT alkaline phosphatase color development kit (Beyotime, China) was used for alkaline phosphatase staining. The staining solution was prepared by adding BCIP, NBT, and working solutions according to the recommended procedures. The mixture was then incubated for 60 min at room temperature in the dark. The reaction was terminated by removing the staining solution and washing it with water 1–2 times.
Alizarin red staining (ARS)
An Alizarin red staining kit (Servicebio, China) was used to assess the amount of calcium salt deposits following the recommended procedures.
Micro-CT
Mice were anesthetized and sacrificed. Femurs were dissected and fixed with 4% paraformaldehyde. A high-resolution micro-CT scanner (PerkinElmer, Japan) was used to scan the tissue. The parameters were adjusted to a voltage of 90 kV, 88 μA, and a resolution of 7 μm per pixel. Skyscan NRecon software (PerkinElmer, Japan) was used to reconstruct the images, and CTVox software (PerkinElmer, Japan) was used to analyze the parameters of the samples.
Bone histomorphometry and immunohistochemistry
Mice were anesthetized and sacrificed. Tissues were fixed in 4% paraformaldehyde for 24 h and decalcified with EDTA for 2 weeks. H&E staining was performed according to recommended procedures. After deparaffinization and hydration, the sections were stained with hematoxylin for 5 min and 1% eosin Y for 10 min. Masson’s trichrome staining kit was used following the procedures to stain collagen fibers. Fluorochrome double labeling was performed as previously described. A double calcein (25 mg/kg) label was injected subcutaneously 10 and 3 days before the necropsy. Non-decalcified bone specimens of femurs were prepared, and the double calcein label was visualized using a microscope (Olympus, Japan) equipped with a digital camera (Olympus, Japan).
For IHC analysis, the deparaffinized sections were incubated with 3% H2O2 for 15 min and then treated with 5% BSA for 10 min. The sections were then incubated with primary antibodies overnight at 4 °C. This was followed by incubation with biotin-conjugated secondary antibodies and visualization with the streptavidin–biotin staining technique. Nuclei were stained with hematoxylin, and the slides were photographed using a microscope (ZEISS, AXIO). For all stains, samples with inadequate staining due to technical problems were excluded.
Dual-luciferase reporter assay
A dual-luciferase reporter assay was used to verify the interaction between pri-miR-181a, pri-miR-181c, and WTAP. A luciferase vector was constructed containing either the wild-type pri-miR-181a, pri-miR-181c, or a mutant sequence. BMSCs were co-transfected with the luciferase vector with or without WTAP overexpression or knockdown. To verify the interaction between miRNA and SFRP1 mRNA, a luciferase vector containing either the wild-type 3’ untranslated region or a mutant sequence was used. BMSCs were co-transfected with the luciferase vector and miRNA mimics or their control using Lipofectamine 2000 (Invitrogen, USA). After 24 h, firefly (Fluc) and Renilla (Rluc) luciferase activities were analyzed using the Luciferase Reporter Assay System (Promega, USA). Relative luciferase activity was calculated by dividing Fluc by Rluc and normalized to the individual control for each assay.
RNA m6A quantification
Total RNA was extracted using the TRIzol reagent (Invitrogen, Carlsbad, CA, USA). The EpiQuik m6A RNA Methylation Quantification kit (colorimetric) (EpiGentek, USA) was used to measure the relative m6A content following the recommended procedures. Absorbance was measured at 450 nm using a microplate reader.
RNA immunoprecipitation (RIP) assay
The RIP kit (BersinBio, Guangzhou, China) was used according to recommended procedures. BMSCs were collected and lysed in radioimmunoprecipitation (RIPA) lysis buffer. Magnetic beads were then incubated with 10 μg antibodies and normal IgG (Millipore, MA, USA) overnight at 4 °C. Immunoprecipitated RNAs were extracted using TRIzol, and RNA enrichment was analyzed using qRT-PCR.
RNA pull-down
Fragments of pri-miR-181a, pri-miR-181c, pri-miR-181a-AS, and pri-miR-181c-AS were amplified using primers containing T7 and SP6 promoter sequences(BioSune, Shanghai, China). The templates were transcribed using a MAXIscript™ SP6/T7 Transcription Kit in vitro (Thermo Fisher Scientific, MA, USA). N6-methyl-ATP (m6A) (Biorbit, orb65363) was used instead of ATP in the in vitro transcription reaction to achieve pri-miR-181a-m6A and pri-miR-181c-m6A. BMSCs (1.5 × 107 cells) were collected and lysed. A Pierce™ Magnetic RNA-Protein Pull-Down Kit was used to complete the RNA pull-down experiment. RNA was first labeled with the end of the desulfurizing biotin. The labeled RNA was captured onto microbeads for 60 min at room temperature to prepare them for protein binding. The RNA-bound beads were equilibrated in protein RNA-binding buffer, and then the protein lysates were added to incubate together overnight at 4 °C. After washing with ice-cold PBS three times, the samples were eluted using sodium dodecyl sulfate–polyacrylamide gel electrophoresis loading buffer. Eluted samples were prepared for WB.
Statistical analysis
All data are shown as mean ± standard deviation (SD). All experiments were repeated at least three times. The Student’s t-test was used for comparisons between two independent groups, and one-way analysis of variance (ANOVA) was used for comparisons between multiple groups. Statistical significance was set at P < 0.05.
Data availability
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
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Acknowledgements
This work was supported by the National Natural Science Foundation of China (NSFC) (81602361, 81702261), China Postdoctoral Science Foundation (2018M642668), Natural Science Foundation of Shandong Province (ZR2021MH293, ZR2020QH080), and Clinical Medical Science and Technology Innovation Plan of Jinan Science and Technology Bureau (201805042). We thank the Translational Medicine Core Facility of Shandong University, Laboratory of Basic Medical Sciences of Qilu Hospital of Shandong University, Center for Experimental Nuclear Medicine & Electron Microscope, School of Basic Medical Sciences, Shandong University for consultation and instrument availability that supported this work.
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YY contributed to the conceptualization, methodology, and original draft writing. JL carried out the data analysis and review, editing, and writing of the manuscript. LZ and XL participated in the formal analysis and software. ZS contributed to the visualization and the investigation. ZD and JM contributed to the resources and validation. YC contributed to the supervision. GJ was responsible for the project administration and funding acquisition. All authors read and approved the final manuscript.
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You, Y., Liu, J., Zhang, L. et al. WTAP-mediated m6A modification modulates bone marrow mesenchymal stem cells differentiation potential and osteoporosis. Cell Death Dis 14, 33 (2023). https://doi.org/10.1038/s41419-023-05565-x
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DOI: https://doi.org/10.1038/s41419-023-05565-x
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