Osteosarcoma and corresponding normal tissues (n = 8) were respectively collected from the First Affiliated Hospital of Dalian Medical University, and the research strategy was formulated in accordance with the Declaration of Helsinki and was authorized by the First Affiliated Hospital of Dalian Medical University ethics committee. Signed informed consent was obtained from the patients.

Osteosarcoma cell lines U2OS and KHOS, and human osteoblast cell line hFOB1.19 were obtained from ATCC (American Type Culture Collection, USA). Based on ATCC's instructions, these cell lines were incubated for further investigation.

The pcDNA-ZFAS1, si-ZFAS1-1, si-ZFAS1-2, miR-520b mimics, miR-520e mimics and pcDNA-RHOC were provided by Gene Chem (Shanghai, China). U2OS and KHOS cells were conducted transfection according to lipofectamine's (11668-019, Invitrogen, USA) protocols.

To evaluate the colony formation ability, a 6-well plate was utilized for the incubation of U2OS and KHOS cells. After 10 days of culture, the transfected cells were respectively conducted fixation and stained by paraformaldehyde and crystal violet. The colonies were counted using a microscope.

For the EdU assay, U2OS and KHOS cells were mixed with EdU reagent in accordance with instructions of An Edu assay kit (KeyGen Biotech, Nanjing), followed by counterstaining using Hoechst 33342. A light microscope was utilized for the visualization and measurement.

For the migration and invasion estimation, the upper chamber was employed for a culture of U2OS and KHOS cells, while the lower chamber was replenished with 10% FBS. After incubation, cells were removed from the upper chamber and the migratory or invasive cells were counted.

To establish scratched cells, U2OS and KHOS cells were maintained in 6-well plates for 24h, followed by forming the wound using pipette tips, and then these cells were incubated for 24h. The width of the scratch was detected. The images were photographed using a microscope.

To verify the interaction between miR-520b and miR-520e with Lnc-ZFAS1 and RHOC, a luciferase reporter assay was performed in KHOS cells. In brief, the Wild-Type (WT) and Mutant (Mut) binding sites of the 3′-untranslated regions of Lnc-ZFAS1 and RHOC for miR-520b and miR-520e were amplified using PCR. The WT and Mut 3′-UTRs were introduced into the pmirGLO luciferase expression vector (Promega Corporation) to construct the following plasmids, Lnc-ZFAS1-WT, Lnc-ZFAS1-MUT, RHOC-WT and RHOC-MUT. KHOS cells were co-transfected with 2.5 µg pmirGLO-Lnc-ZFAS1-WT, pmirGLO-Lnc-ZFAS1-MUT, pmirGLO-RHOC-WT or RHOC-MUT and 50 nM miR-520b mimics, miR-520e mimics, or NC-mimics using Lipofectamine 3000 at 37°C. At 48h post-transfection, luciferase activities were measured using the dual-luciferase reporter assay system (Promega Corporation) according to the manufacturer's protocol. Firefly luciferase activities were normalized to Renilla luciferase activities.

Sense or antisense Lnc-ZFAS1 sequences were marked with biotin and then were cultured with protein lysis extracted from KHOS cells lysate, followed by incubating with agarose beads (Invitrogen) coupled with streptavidin. The q-PCR was employed to detect the amounts of Lnc-ZFAS1, miR-520b, miR-520e, and miR-934.

For the detection of F-actin, transfected KHOS cells were incubated in the coverslips of six-well plates overnight, followed by mixing with 100 µg/mL PCFE and 1000 µg/mL dacarbazine for 24h. After fixing with methanol, cells were cultured with primary anti-F-actin antibody (ab205, abcam, UK) for 1h, and then incubated with secondary antibodies. A fluorescence microscope (Leica DM4000 B, Germany) was utilized for the visualization.

To verify the location of Lnc-ZFAS1, KHOS cells were performed the isolation of cytoplasmic and nuclear RNA in accordance with the protocol of PARIS Kit (Life Technologies, USA). qRT-PCR was employed to examine the total RNA extracted from the cytoplasm and nucleus.

fluorescein amidite-labeled Lnc-ZFAS1 probes were designed and synthesized by RiboBio. A FISH Kit (RiboBio) was used to detect probe signals according to the manufacturer's instructions. Nuclei were stained with DAPI. All images were acquired on a confocal microscope system.

By using a Magna RNA-binding protein immunoprecipitation kit (Millipore, USA), RIP was performed to evaluate the correlation between Lnc-ZFAS1 and miR-520e/miR-520b. KHOS cells were centrifuged and washed prior to mixing with RIP lysis buffer. The lysates were harvested to incubated with RNAs magnetic beads that conjugated Anti-AGO2 antibody (ab186733,1:50, Abcam, UK) or anti-IgG (ab172730, 1:100, Abcam, UK). After treating samples with Proteinase K for 30 min with gentle agitation, immunoprecipitated RNA was isolated using TRIzol. Finally, co-precipitated RNAs were identified and analyzed via qRT-PCR.

Protein samples extracted by RIPA buffer were isolated using SDS-PAGE, and were transferred into PVDF membranes, followed by incubating with primary antibodies. Anti-rabbit antibody coupled with peroxidase was determined as the secondary antibody. ECL reagent (Millipore) was utilized for the visualization of antigen-antibody reaction. The primary antibodies caspase-3 (ab32351, 1:5000), cleaved caspase-3 (ab32042, 1:500), caspase-9 (ab32539, 1:1000), cleaved caspase-9 (ab2324, 1 µg/mL), bax (ab32503,1:2000), Bcl-2 (ab32124, 1:1000), Cyclin D1 (ab16663, 1:50), E-cadherin (ab76055, 1:200), N-cadherin (ab76011, 1:5000), Vimentin (ab92547, 1:2000), MMP-9 (ab76003, 1:10000) were purchased from Abcam (UK). GAPDH (ab8245, 1:1000, abcam, UK) was considered as the normalization.

Total RNA samples extracted by TRIzol reagent were transcribed to cDNA following the protocols of PrimeScript RT Reagent Kit (Takara, Dalian, China). Then SYBR Premix Ex Taq (Takara) system was employed for the analysis of real-time PCR. The relative expression was performed normalization with GAPDH and U6. The corresponding primer sequences are listed in Supplementary Table 1.

In this research, SPSS 20.0 (Chicago, USA) and GraphPad Prism 7 (GraphPad Software, USA) were utilized for all data-related collation. The data were represented as the mean ± SD. The differences between internal groups were analyzed by Student's t-test and ANOVA; p < 0.05 indicates statistical significance.

To explore the role of Lnc-ZFAS1 in osteosarcoma, we first analyzed the expression level of Lnc-ZFAS1 in osteosarcoma tissues and normal tissues in TCGA database. Lnc-ZFAS1 was upregulated in osteosarcoma tissues (Fig. 1A), which was further confirmed in clinic samples by q-PCR analysis (n = 8, Fig. 1B). In addition, we detected the expression level of Lnc-ZFAS1 in osteosarcoma cell lines U2OS and KHOS, as well as the human osteoblast cell line hFOB1.19 and found the expression of Lnc-ZFAS1 was significantly higher in U2OS and KHOS cells than in hFOB1.19 cell (Fig. 1C). Collectively, these results suggest that Lnc-ZFAS1 is highly expressed in osteosarcoma.

Figure 1.

Lnc-ZFAS1 is upregulated in osteosarcoma. (A) TCGA database was used to evaluate the expression of Lnc-ZFAS1 in osteosarcoma tissues and normal tissues. (B) qRT-PCR was employed to detect the expression of Lnc-ZFAS1 in osteosarcoma tissues and normal tissues (n = 8). (C) qRT-PCR was utilized to measure the Lnc-ZFAS1 expression in osteosarcoma cell lines (U2OS and KHOS), and the human osteoblast cell line hFOB1.19 (*p < 0.05, **p < 0.01).

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To uncover the functional influence of Lnc-ZFAS1 upon osteosarcoma progression, we established Lnc-ZFAS1-upregulated U2OS cells and Lnc-ZFAS1-downregulated KHOS cells (Fig. 2A). Lnc-ZFAS1 overexpression resulted in an obvious rise in (Fig. 2B) the cell proliferation of U2OS cells, as confirmed by colony formation assay (Fig. 2B) and EdU assay (Fig. 2C), while Lnc-ZFAS1 depletion caused reverse effect on KHOS cells proliferation (Fig. 2D‒E). In addition, upregulated Lnc-ZFAS1 enhanced the expression of anti-apoptosis proteins Bcl-2 and Cyclin D1 in U2OS cells, and exerted repressive effect upon pro-apoptosis proteins, including Bax, cleaved caspase-3 and cleaved caspase-9 (Fig. 2F). In contrast, depleted Lnc-ZFAS1 efficiently suppressed anti-apoptosis proteins and promoted pro-apoptosis proteins in KHOS cells. Overall, these findings suggested that Lnc-ZFAS1 facilitates osteosarcoma cell proliferation and restrains its apoptosis.

Figure 2.

Lnc-ZFAS1 facilitates cell proliferation and represses apoptosis in osteosarcoma. For functional investigation, U2OS and KHOS cells were respectively infected with Lnc-ZFAS1 overexpression and Lnc-ZFAS1 shRNA plasmids, and qRT-PCR was performed for examination of transfected efficacy (A). Colony formation (B and D) and EdU (C and E) assays were utilized for proliferation analysis. (F) Western blotting was adopted to examine the expression of apoptosis-related proteins (**p < 0.01).

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We further investigated the effects of Lnc-ZFAS1 on osteosarcoma cell migration and invasion. Wound healing (Fig. 3A) and transwell (Fig. 3B‒C) assays demonstrated that Lnc-ZFAS1 depletion could shorten the wound gap and restrain the migratory and invasive capacities in KHOS cells, whereas Lnc-ZFAS1 overexpression induced promoted influence. Moreover, the up-regulation of MMP-9, Vimentin and N-cadherin and the downregulation of E-cadherin were observed in Lnc-ZFAS1 overexpressed U2OS cells, and the contrast results were induced by Lnc-ZFAS1 depletion, implying Lnc-ZFAS1’ promotion effect on EMT in osteosarcoma (Fig. 3D). In addition, Immunofluorescence staining assay exhibited the strong fluorescence intensity of F-actin in Lnc-ZFAS1-upregulated U2OS cells and the weak fluorescence intensity in Lnc-ZFAS1-downregulated KHOS cells (Fig. 3E). Taken together, our findings further confirmed the accelerated role of Lnc-ZFAS1 in osteosarcoma cells migration, invasion, and EMT.

Figure 3.

Lnc-ZFAS1 facilitates migration, invasion and EMT in osteosarcoma cells. Wound healing (A) and transwell (B and C) assays were adopted to examine the migratory and invasive capacities. (D) Western blotting was performed for the expression of EMT-related proteins. (E) F-actin was detected using Immunofluorescence staining (**p < 0.01).

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To expose the fundamental mechanism through which Lnc-ZFAS1 affects osteosarcoma progression, we first examined the subcellular location of Lnc-ZFAS1 in KHOS cells and found Lnc-ZFAS1 was evenly enriched in the and nucleus (Fig. 4A). Notably, this was corroborated by the result of the FISH assay (Fig. 4B) Subsequently, we referred to Starbase and GSE28423 databases to explore the intersected miRNAs, which could potentially interacted with Lnc-ZFAS1. Among miRNAs downregulated in osteosarcoma, hsa-miR-520b, hsa-miR-520e and hsa-miR-934 was identified as the potential target of Lnc-ZFAS1 (Fig. 4C).

Figure 4.

Lnc-ZFAS1 sponges miR-520b and miR-520e in osteosarcoma. (A) The subcellular location of Lnc-ZFAS1 was determined. GAPDH and U6 were respectively determined as the markers of cytoplasm and nucleus. (B) FISH results show Lnc-ZFAS1 (in green) cellular distribution in KHOS cells. (C) Starbase and GSE28423 databases were performed to obtain intersected hsa-miR-520b, hsa-miR-520e and hsa-miR-934. RNA pull-down (D), Luciferase reporter (E) and RIP (F) assays were utilized to explore the binding between Lnc-ZFAS1 with two miRNAs. (G) miR-520b and miR-520e were detected in Lnc-ZFAS1-upregulated U2OS cells and Lnc-ZFAS1-downregulated KHOS cells by qRT-PCR. (H) qRT-PCR was employed to detect the expression of miR-520b and miR-520e in osteosarcoma tissues and normal tissues (n = 8). (I) The correlation analysis between Lnc-ZFAS1 with two miRNAs (*p < 0.05, **p < 0.01).

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RNA pull-down results showed that biotin-labeled Lnc-ZFAS1 efficiently enriched miR-520b and miR-520e from KHOS cells lysate (Fig. 4D). Additionally, miR-520b mimics and miR-520e mimics respectively suppressed the luciferase activity of Lnc-ZFAS1 wild-type in KHOS cells, but not mutant Lnc-ZFAS1 3′-UTR (Fig. 4E). RIP assay further confirmed that anti-AGO2 complexes significantly enriched Lnc-ZFAS1 in miR-520b-upregulated and miR-520e-upregulated KHOS cells, respectively (Fig. 4F). To further validate the regulatory correlation between Lnc-ZFAS1 and miR-520b/miR-520e, we detected the expression of miR-520b and miR-520e in Lnc-ZFAS1-upregulated and downregulated cells and found that Lnc-ZFAS1 overexpression suppressed these two miRNAs expression, while Lnc-ZFAS1 depletion elevated them (Fig. 4G). Furthermore, we observed that both miR-520b and miR-520e were lowly expressed in osteosarcoma tissues compared with that in normal tissues (n = 8, Fig. 4H), and their expression levels were negatively associated with Lnc-ZFAS1 expression (Fig. 4I). Collectively, our data demonstrated that Lnc-ZFAS1 might function as a ceRNA to sponge miR-520b and miR-520e in osteosarcoma.

We aimed to reveal the specific mechanism of miR-520b and miR-520e in osteosarcoma progression. Bioinformatics databases including PITA, miRmap, microT, miRanda, PicTar and TargetScan were performed to predict the target genes of miR-520b and miR-520e (Fig. 5A). The predicted target genes of miR-520b and miR-520e and the differentially up-regulated genes in GSE16088 database were intersected15 intersection genes, including RHOC, BAMBI, UBE2J1, SPOP, TARDBP, SUCO, TLE4, MEF2C, TIPARP, UBE2B, ATAD2, NFIB, DPP8, ARID4B, APP (Fig. 5B) were finally identified. Among them, RHOC has been proven to involve in the progression of osteosarcoma,25 thus we determined RHOC as the target gene in further research.

Figure 5.

miR-520b and miR-520e negatively modulates RHOC in osteosarcoma. (A) PITA, miRmap, microT, miRanda, PicTar and TargetScan databases were performed to predict the target genes of miR-520b and miR-520e. (B) The intersection genes were obtained through intersecting predicted genes and GSE16088 database. (C) Target database was utilized to analyze the different expression of RHOC in osteosarcoma. Dual luciferase reporter (D), q-PCR (E), RIP (F) and RNA pull-down (G) assays were performed to validate the correlation between miR-520b or miR-520e and RHOC.

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To investigate the correlation between RHOC and two miRNAs, we first analyzed the expression of RHOC in osteosarcoma, based on the Target database, we observed RHOC was upregulated in osteosarcoma tissues (Fig. 5C). Next, dual luciferase reporter assay exhibited that miR-520b mimics and miR-520e mimics considerably restrained the luciferase activity in RHOC-WT plasmid transfected KHOS cells, compared to that in RHOC-MUT plasmid-transfected cells (Fig. 5D). Furthermore, Lnc-ZFAS1 overexpression efficiently facilitated the expression of RHOC in U2OS cells, while depleted Lnc-ZFAS1 exerted inhibited effect upon KHOS cells (Fig. 5E). Interestingly, we found that anti-AGO2 complexes could respectively enrich RHOC in miR-520b-upregulated and miR-520e-upregulated KHOS cells (Fig. 5F), and biotin-labeled RHOC could pull down miR-520b and miR-520e in an efficiently way (Fig. 5G). Together, these results indicate that miR-520b and miR-520e could negatively regulate RHOC in osteosarcoma.

To verify whether Lnc-ZFAS1 acts oncogenic driver in osteosarcoma progression in an RHOC-dependent manner, we co-transfected Lnc-ZFAS1 siRNA and RHOC overexpression plasmids into KHOS cells (Fig. 6A). EdU assay exhibited that Lnc-ZFAS1 depletion strikingly induced the drop of EdU positive cells, which could be rescued by RHOC overexpression (Fig. 6B). In addition, upregulated RHOC restored the expression levels of anti-apoptosis proteins bcl-2 and Cyclin D1, which were inhibited by Lnc-ZFAS1 (Fig. 6C). Moreover, upregulating RHOC partly abrogated the impairment of the migratory and invasive capacities of KHOS cells caused by Lnc-ZFAS1 silence (Fig. 6D‒E). RHOC also blocked the EMT induced by Lnc-ZFAS1, which could be specifically embodied in the restoration of MMP-9, Vimentin and N-cadherin (Fig. 6F). Additionally, the inhibited effect on the fluorescence intensity of F-actin also could be rescued by RHOC overexpression (Fig. 6G). Our findings indicate that Lnc-ZFAS1 acted a functional role in osteosarcoma progression through targeting RHOC.

Figure 6.

Lnc-ZFAS1 facilitates osteosarcoma progression via RHOC. To verify whether Lnc-ZFAS1 acts oncogenic driver in osteosarcoma progression in a RHOC-dependent manner, KHOS cells were transfected with Lnc-ZFAS1 siRNA and RHOC overexpression plasmids, qRT-PCR (A) was performed to detect the transfection efficacy. (B) EdU was performed for proliferation analysis. (C) Apoptosis-related proteins were detected by western blotting. Migration and invasion were evaluated by wound healing (D) and transwell (E). EMT-related proteins were measured by western blotting (F). (G) F-actin was examined using Immunofluorescence staining (*p < 0.05).

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