Introduction

Glioma, a common primary tumor in the central nervous system, mostly occurs at the neuroectoderm. The incidence of glioma accounts for about 45–50% of intracranial tumors.^1–3 Currently, glioma is mainly treated by surgery combined with multiple treatments, such as radiotherapy, chemotherapy, and tumor biological activation immune method,⁴ but the treatment outcome of glioma is far from satisfactory.⁵ Studies showed that many natural plants contain anti-tumor active ingredients with a variety of component capable of improving human immune functions and inhibiting the biological functions of tumor cells.^6–8

Safflower (Carthamus tinctorius L.) is a traditional Chinese medicine and has the effects of activating blood circulation, removing blood stasis, clearing menstruation, and relieving pain.⁹ Safflor yellow is a chalcone compound of safflower, and Hydroxysafflor Yellow A (HSYA) is the most important active ingredient in safflower yellow.¹⁰ The pharmacological effects of HSYA, such as improving myocardial ischemia and neurological deficits, resisting oxidative stress, and reducing inflammatory reactions, have been extensively studied.^10–15 Furthermore, research has proved that HSYA has an anticancer effect on different types of cancers, for instance, HSYA inhibits the angiogenesis of liver cancer by inactivating MAPK,¹⁶ and HSYA suppresses the proliferation and metastasis of lung cancer cells by regulating PI3K/AKT pathway.¹⁷ However, whether HSYA had an anticancer effect on glioma remained unclear.

MYC transcription factor is an oncogene with a regulatory effect on many cancers, including glioma.^18,19 In addition, researches have reported that MYC is involved in the drugs resistance of cancer cells, for example, MYC drives Nab-Paclitaxel resistance of pancreatic ductal carcinoma cells,²⁰ and modulates the drug resistance of leukemia stem cells through ERK/MSK pathway.²¹ Moreover, MYC also mediates the PARP inhibitor resistance of glioblastoma.²² Therefore, MYC becomes an important target in anticancer research. The expression of MYC can be regulated by HSYA in human HUVEC cells and human liver cancer cells.^23,24 However, whether HSYA has a regulatory effect on MYC in glioma should be further examined and studied.

Based on the above background, the present research attempted to determine the role of HSYA in glioma and to explore whether the role of HSYA in glioma was related to the function of MYC.

Methods Ethics Statement

Cancer tissues and adjacent tissues of glioma patients (n=50) were obtained from Fuwai Central China Cardiovascular Hospital. The use of the clinical tissues was approved by the Ethics Committee of Fuwai Central China Cardiovascular Hospital (F2020030510N), in accordance with the Declaration of Helsinki, and informed consent was provided by all the patients.

Bioinformatics Analysis

The expression of MYC in glioma tissues and normal tissues was analyzed through GEPIA2 (http://gepia2.cancer-pku.cn/#index). The correlation between MYC and NBS1 in glioma was analyzed through StarBase (http://starbase.sysu.edu.cn). The target relationship between MYC with NBS1 was predicted using CISTROME database (http://cistrome.org/db/) and Cister database (zlab.bu.edu).

Cell Culture

Normal human astrocytes cell lines including HEB (BNCC283657, BNBIO, Beijing, China) and NHA (BFN60808805, BLUEFBIO, Shanghai, China), glioma cell lines including A172 (BNCC317373, BNBIO), LN-229 (BNCC306188, BNBIO), T98G (BNCC302929, BNBIO), and U-251MG (Tongpai Biotechnology, Shanghai, China, http://www.shtpbio.com/tongpai-Products-10947704/), and human HEK293T cells (CL-0005, PROCELL, Wuhan, China) were grown in complete medium, which consists of DMEM medium (30-2002, ATCC, Manassas, Virginia, USA) with 10% FBS (10437010, Gibco, Waltham, Massachusetts, USA) and 1% Penicillin-Streptomycin (15140163, Gibco). All the cells were cultured in a 37°C environment with 5% CO₂.

Drugs Treatment

For HSYA treatment, the cells were cultured in a medium containing 25, 50, or 100 μM of HSYA (N1526, APExBIO, Houston, Texas, USA) for 24, 48, or 72 h (Figure S1A and B). Then, the cells were collected for later use. For 10058-F4 (inhibitor of MYC) treatment, the cells were in a medium containing 25 μM of 10058-F4 (A1169, APExBIO) for 48 h. Then, the cells were collected for later use.

Cell Transfection

The siRNA1 targeting MYC (Figure S1C; siMYC-1; target sequence: 5ʹ-CCGGTTTTCGGGGCTTTATCTAA-3ʹ), siRNA2 targeting MYC (siMYC-2; target sequence: 5ʹ-CTGCTTAGACGCTGGATTTTTTT-3ʹ), siRNA3 targeting MYC (siMYC-3; target sequence: 5ʹ-GAGCAAAAGCTCATTTCTGAAGA-3ʹ), siRNA negative control (siNC; 5ʹ-AATTCTCCGAACGTGTCACGT-3ʹ), plasmids overexpressing NBS1 were cloned into pcDNA3.1 vector (Genepharma, Shanghai, China). Before cell transfection, LN-229 and U-251MG cells were, respectively, cultured in a 6-well plate to 80% confluence. Then, the siRNA or plasmids were transfected into the cells using 3 μL lipofectamine 3000 (L3000015, Invitrogen, Waltham, Massachusetts, USA). After 48-h transfection, the cells were harvested for drug treatment or later use.

Dual-Luciferase Reporter Assay

After the promoter of NBS1 was predicted to be targeted by MYC, the dual-luciferase reporter assay was performed to verify the prediction following a previous report.²⁵ To examine the binding of MYC to the promoter region of NBS1, NBS1 promoter wild-type sequence (wt-NBS1) and mutant-type sequence containing MYC binding site A and/or B (mut-NBS1) were respectively cloned into the promoter region of the pGL3-Basic vector (VT1554, YouBio, Hunan, China). Then, the HEK293 cells were transfected with the vectors and MYC for 48 h. After the cells were administrated with the Dual-Luciferase Reporter Assay System Kit (E1960, Promega, Shanghai, China), the luciferase activity was determined using a SpectraMax reader (Molecular Devices, Shanghai, China).

MTT Assay

The LN-229 and U-251MG cells in 96-well plates were treated with different concentrations of HSYA or 10058-F4 for indicated times. Then, the cultured media were replaced with 100 μL MTT solution (C0037, Beyotime, Shanghai, China), and the cells were further cultured for 4 h. Then, the MTT solution was discarded, and 100 μL of DMSO (ST038, Beyotime) was added into the wells to dissolve formazan. Finally, the absorbance under 570 nm was determined using an Imark microplate reader (Bio-Rad, CA, USA).

Colony Formation Assay

After being transfected with siRNA targeting MYC or further treated with HSYA, 1 × 10³ LN-229 and U-251MG cells were resuspended in a 2-mL culture medium and placed into a 6-well plate to grow for 14 days. Then, the cell colonies in the 6-well plate were incubated with fixative (P885233, MREDA, Beijing, China) for 10 min and dyed with purple crystal buffer (C0121, Beyotime) for 10 min. After washing with PBS (C0221A, Beyotime) for three times, the stained colonies were recorded using a camera (D-LUX7, Leica, Wetzlar, Germany) and the colony numbers were quantified using the Image J 1.8.0 software.

Transwell Assays

After being transfected with siRNA targeting MYC or further treated with HSYA, 1 × 10⁵ LN-229 and U-251MG cells were resuspended in 200 μL medium without FBS and, respectively, placed into a transwell chamber (354234, Corning, NY, USA), which were inserted into the 24-well plate. Each well of the 24-well plate contained a 700-μL complete medium. After cell incubation for 48 h, the invaded cells were fixed with fixative and dyed with purple crystal buffer for 15 min. Finally, the stained cells were recorded using a DM4M optical microscope (Leica, Solms, Germany) and analyzed using the Image J 1.8.0 software.

Wound Healing Assays

After cell transfection with siRNA targeting MYC or further treatment with HSYA, 1 × 10⁵ LN-229 and U-251MG cells were resuspended in 2 mL of complete medium and added into each well of a 6-well plate. The cells were cultured for 16 h (100% confluence), a straight wound was created in each well, and then the cells were cultured in a medium without FBS for 24 h. The picture of each wound at 0 and 24 h was recorded by a DMLA optical microscope. Image J 1.8.0 software was applied to analyze the data.

Flow Cytometry

After cell transfection or further treatment with drugs, the LN-229 and U-251MG cells were collected and washed with PBS twice. Then, the cells were stained with Annexin V-FITC (D17360, OKA) and Propidium iodide (D17360, OKA) for 15 min. Finally, the cell apoptosis signal was analyzed by the FACS-LSR II flow cytometer system (Becton-Dickinson, NJ, USA).

Immunofluorescence

After cell transfection with siRNA targeting MYC or treatment with HSYA, the LN-229 and U-251MG cells were fixed by fixative and permeabilized by 0.5% Triton X-100 (T8787, Merck, St. Louis, Missouri, USA). Then, the cells were incubated with the γH2AX antibody (ab195188, Abcam, Cambridge, UK) overnight at 4°C. After washing with PBS, the cells were further dyed with DAPI (C1002, Beyotime) for 20 min. Finally, the cell images were observed and recorded under a BSF-40 fluorescence microscope (Batuo Instrument, Shanghai, China) at the magnification × 100.

RT-qPCR

The mRNA in the clinical tissues and cultured cells were extracted. Briefly, the tissue and cell samples were mixed with Trizol (R21086, OKA, Beijing, China) and chloroform (A23482, OKA) for 30-min centrifugation (14,000 × g) to collect the supernatant. Then, the supernatant was mixed with isopropanol (E15794, OKA) and further centrifuged (14,000 × g) for 15 min. After the mRNA was collected from the precipitations, it was synthesized into cDNA using BeyoRT III cDNA synthesis regent (D7178L, Beyotime). Finally, the cDNA amplification was performed by mixing the cDNA with the Supermix (AQ601-01, TransGen, Beijing, China) and primers of target genes in the QuantStudio6 system (Applied Biosystems, CA, USA). After the amplifying reaction, the target gene expressions were quantified using the 2^−ΔΔCt method. The primers used in the experiments were as follows: MYC-F: 5ʹ-GGCTCCTGGCAAAAGGTCA-3ʹ, MYC-R: 5ʹ-CTGCGTAGTTGTGCTGATGT-3ʹ; NBS1-F: 5ʹ-GACTGGCGTTGAGTACGTTGT-3ʹ, NBS1-R: 5ʹ-TGATTTCGGCTGATCGACTGA-3ʹ; MRE11-F: 5ʹ-TCCGTGAGGCTATGACCAGG-3ʹ, MRE11-R: 5ʹ-TTGGTTGCTGCTGAGATGCTAT-3ʹ; β-actin-F: 5ʹ-CCACGAAACTACCTTCAACTCC-3ʹ, β-actin-R: 5ʹ-GTGATCTCCTTCTGCATCCTGT-3ʹ.

Western Blot Assays

Total proteins from the cultured cells were extracted using NP-40 (P0013F, Beyotime) and nucleus proteins in the cells were extracted using Nucleus Protein Extraction Kit (P0027, Beyotime). The protein concentration was determined by the BCA kit (P0009, Beyotime). Then, 25 μg of proteins was separated by the SDS-PAGE gel (P0052A, Beyotime) and transferred to the surface of PVDF membranes (FFP39, Beyotime). After membrane block with 5% milk without FBS, the membranes were soaked in 5 μL relative primary antibodies at 4°C for 16 h. The next day, the membrane was incubated with rabbit second-antibody (1:10,000, ab205718, Abcam) or mouse second-antibody (1:10,000, ab205719, Abcam) for 2 h at room temperature. Finally, after the membrane was covered with 200 μL of detection solution (P0019, Beyotime), and the image signal was detected using the Image Lab 3.0 Software (Bio-Rad, CA, USA). The relative primary antibodies were as follows: MYC (1:1000, ab32072, Abcam), E-Cadherin (1:2000, ab231303, Abcam), N-Cadherin (1:1500, ab18203, Abcam), Bcl-2 (1:800, ab59348, Abcam), Bax (1:3000, ab32503, Abcam), Cleaved PARP1 (1:1500, ab32064, Abcam), PARP1 (1:5000, ab32138, Abcam), NBS1 (1:1000, ab181729, Abcam), p-NBS1 (1:1000, ab109453, Abcam), MRE11 (1:800, ab208020, Abcam), p-MRE11 (1:1000, #4859, CST, Boston, Massachusetts, USA), RAD50 (1:3000, ab124682, Abcam), p-RAD50 (1:1000, #14223, CST), ATM (1:2000, ab199726, Abcam), p-ATM (1:10,000, ab81292, Abcam), γH2AX (1:1500, ab81299, Abcam), Histone H3 (1:2500, ab1791, Abcam), β-actin (1:5000, ab8226, Abcam), and GAPDH (1:5000, ab8245, Abcam).

Statistical Analysis

The expressions of MYC and NBS1 in the clinical cancer tissues and adjacent tissues were analyzed by pared-samples t-test. Comparison between multiple groups was conducted using one-way ANOVA. IC₅₀ was analyzed using Probit regression analysis based on the data of MTT assays. All statistical analyses were implemented using Graphpad 8.0 software. Mean ± SD was used to present the statistical data. P < 0.05 was regarded as statistically significant.

Results MYC Was High-Expressed in Glioma Tissues and Cells

The analysis in GEPIA2 showed that the expression of MYC in glioma tissues was higher than that in normal tissues (P < 0.05, Figure 1A). For further verification, the expression of MYC in clinical glioma tissues and adjacent normal tissues were determined again, as shown in Figure 1B, the expression of MYC was high-expressed in glioma tissues (P < 0.001). Meanwhile, the high expression of MYC was also discovered in the cultured glioma cell lines as compared with the normal cells (P < 0.01), indicating that MYC might have a regulatory effect on the development of glioma.

HSYA and siRNA Targeting MYC Regulated the Cell Viability, Proliferation, Migration, Invasion, and Apoptosis, and siRNA Targeting MYC Enhanced the Sensitivity of Glioma Cells to HSYA

Then, we observed that the viabilities of LN-229 and U-251MG cells were reduced (Figure 2A) by HSYA after treatment with different doses of HSYA for 24 h (P < 0.001) and further reduced by siRNA targeting MYC as compared with the siNC (P < 0.01). Meanwhile, the IC₅₀ of HSYA in the two cells was calculated, and it was found that siRNA targeting MYC decreased the IC50 of HSYA in the two cells (P < 0.001, Figure 2B). As shown in Figure 2C, the proliferation of the LN-229 and U-251MG cells was inhibited by HSYA and further reduced by siRNA targeting MYC as compared with the siNC (P < 0.05). Subsequently, the abilities of the LN-229 and U-251MG cells to migrate and invade after silencing MYC or treatment with HYSA were evaluated. As presented in Figure 3, the invasion (Figure 3A) and the migration (Figure 3B) of LN-229 and U-251MG cells were inhibited by HYSA (P < 0.05), and MYC silence further reduced the invasion and migration of HYSA-treated cells (P < 0.01).

We used 25 μM HSYA in the apoptosis detection and later experiments. As illustrated in Figure 4A, the apoptosis of the two cells was induced by both HSYA and siRNA targeting MYC (P < 0.001). After co-treatment with siRNA targeting MYC and HSYA, the effect of HSYA on promoting cell apoptosis was enhanced by siRNA targeting MYC (P < 0.001). To further verify these above discoveries, the expressions of EMT markers and apoptosis markers were determined. The results (Figure 4B) exhibited that HSYA and siRNA targeting MYC upregulated the expressions of E-Cadherin, Bax, and Cleaved PARP1 (P < 0.001), but downregulated the expressions of N-Cadherin and Bcl2 (P < 0.05). Furthermore, the effect of HSYA on these factors was promoted by siRNA targeting MYC (P < 0.001). These results indicated that the effect of HSYA on glioma cells might be realized by regulating MYC. All these results indicated that HSYA and siRNA targeting MYC inhibited cell viability and proliferation, and that siRNA targeting MYC enhanced the sensitivity of glioma cells to HSYA by inhibiting cell viability and proliferation.

HSYA and siRNA Targeting MYC Promoted the DNA Damage of Expressions of Glioma Cells and siRNA Targeting MYC Further Enhanced the Effect of HSYA on DNA Damage

As the apoptosis of the cells was induced by HSYA and γH2AX is a biomarker of DNA Double-strand breaks (DSBs),²⁶ thus, the γH2AX expression was determined in the LN-229 and U-251MG cells after silencing MYC or treatment with HYSA. As depicted in Figure 5, the expression of γH2AX in the LN-229 and U-251MG cells was promoted by siRNA targeting MYC and HSYA, moreover, the effect of HSYA on enhancing γH2AX expression was further promoted by siRNA targeting MYC. This result suggested that the effect of HSYA on glioma cells was involved in DNA damage and repair.

MYC Targeted High-Expressed NBS1 and the Two Genes Were Positively Correlated in Glioma Tissues

Considering that NBS1 and MRE11 were closely associated with the DSBs,²⁷ the expressions of NBS1 and MRE11 in the LN-229 and U-251MG cells were detected (Figure 6A). The transfection of siRNA targeting MYC downregulated the levels of MYC and NBS1 (P < 0.001), and the expression of MRE11 did not change. Meanwhile, the up-regulated expression of NBS1 was found in glioma tissues (P < 0.001, Figure 6B), and we also found a positive correlation between NBSI with MYC in glioma tissues by RT-qPCR detection (Figure 6C) and starBase prediction (Figure 6D). In addition, it was predicted that the promoter region of NBS1 was targeted by MYC (Figure 6E). Furthermore, a dual-luciferase reporter assay was performed to confirm the prediction. As shown in Figure 6F, the luciferase activity was increased after the co-transfection of MYC and wt-NBS1 and the co-transfection of MYC and mut-NBS1 (site A and/or B), as compared with the Control (P < 0.001). However, as compared with the cells co-transfected with MYC and wt-NBS1, the luciferase activity of the cells co-transfected with MYC and mut-NBS1 (site A and/or B) was reduced (P < 0.001). These findings indicated that MYC targeted NBS1 and was positively correlated with NBS1 in glioma.

siRNA Targeting MYC Caused DNA Repair Deficiency in HSYA-Treated Glioma Cells by Inhibiting the Transduction of Signaling Related to DNA Repair

Then, we further detected the signaling related to DNA damage response in the LN-229 and U-251MG cells after transfection with siRNA targeting MYC or further treatment with HSYA. As shown in Figure 7, the expression of MYC was upregulated by HSYA and downregulated by siRNA targeting MYC (P < 0.001), and the expressions of γH2AX was upregulated by HSYA and siRNA targeting MYC (P < 0.001). In addition, the ratios of p-NBS1/NBS1, p-MRE11/MRE11, p-RAD50/RAD50, and p-ATM/ATM were increased by HSYA (P < 0.001), but the ratios of p-NBS1/NBS1 and p-ATM/ATM were decreased by siRNA targeting MYC (P < 0.001), moreover, siRNA targeting MYC had no effect on the ratios of p-MRE11/MRE11 or p-RAD50/RAD50. Also, the effect of HSYA on these factors was counteracted by siRNA targeting MYC (P < 0.05). The results indicated that the DNA damage response (DNA repair signaling) in the HSYA-damages cells was normally regulated, but siRNA targeting MYC caused DNA repair deficiency.

NBS1 Overexpression Induced the HSYA Resistance in MYC-Silenced Glioma Cells

To further determined whether NBS1 s was responsible for the increased sensitivity to HSYA in MYC silenced cell, the LN-229 and U-251MG were overexpressed with NBS1 (Figure 8A) and the inhibitor of MYC (10058-F4) was used to silence MYC. Then, the viability of the cells was determined (Figure 8B), and we found that the viabilities of both LN-229 and U-251MG were promoted by NBS1 overexpression (P < 0.05) but inhibited by 10058-F4 (P < 0.001). However, after co-treatment with NBS1 overexpression plasmids and 10058-F4, the effects of 10058-F4 on cell viability were reversed by NBS1 overexpression. Furthermore, the sensitivity of MYC-silenced cells to HSYA was found to be reduced by NBS1 overexpression, because as shown in Figure 8C, IC₅₀ of HSYA in MYC-silenced glioma cells was increased by NBS1 overexpression (P < 0.001). Moreover, the apoptosis induced by HSYA in MYC silenced cells was reduced by NBS1 overexpression (Figure 9A). Then, the expressions of factors related to DNA damage and repair were determined (Figure 9B), and the results showed that the expressions of NBS1, p-NBS1, and p-ATM, which were downregulated by MYC silencing, were upregulated by NBS1 overexpression (P < 0.05). Moreover, NBS1 overexpression also downregulated the expression of γH2AX. All these results proved that NBS1 overexpressing induced HSYA resistance in MYC-silenced glioma cells, indicating NBS1 signaling was involved in the MYC and glioma chemosensitivity.

Discussion

Apart from the pharmacological effects such as anti-myocardial ischemia, anti-oxidation, and anti-inflammation,^10–15 HSYA also has an anti-cancer effect.^16,17 Similarly, the anticancer effect of HSYA on glioma was also confirmed in the present study, as we found that HSYA suppressed the viability, proliferation, migration, and invasion, induced the apoptosis of glioma cells.

We predicted and verified that MYC is high-expressed in glioma tissues and cell, and such a finding is consistent with a previous study.²⁸ In addition, MYC can be regulated by HSYA in human HUVEC cells and liver cancer cells.^23,24 To explore whether the effect of HSYA on glioma was associated with MYC, the expression of MYC in glioma cells was detected after treatment with HSYA. We discovered that HSYA stimulated the expression of MYC (Figure S1), which might be related to tumor adaptation and drug resistance and commonly caused in cancers. MYC is involved in the drugs resistance of cancer cells, for example, MYC drives Nab-Paclitaxel resistance in pancreatic ductal carcinoma cells²⁰ and modulates the drug resistance of leukemia stem cells through ERK/MSK pathway.²¹ Moreover, MYC also mediates the PARP inhibitor resistance in glioblastoma.²² We then speculated that MYC might be involved in the resistance of glioma cells to HSYA. Therefore, the biological activities of glioma cells after treatment with HSYA and silencing MYC were further evaluated, and the results showed that siRNA targeting MYC reduced the IC₅₀ of HSYA in glioma cells and enhanced the inhibitory effect of HSYA on glioma cells, revealing that siRNA targeting MYC increased the sensitivity of glioma cells to HSYA.

Meanwhile, γH2AX is a marker of DSBs and can initiate the DNA repair response.²⁶ The results showed that the effect of MYC on HSYA-induced glioma cells was associated with the DNA repair because we found that the level of γH2AX in glioma cells was upregulated. NBS1 is an important factor in DNA repair and can be directly targeted by MYC.^29,30 Consistently, in this study, the targeted relationship was verified by bioinformatics prediction and experiments confirmation. For the first time, NBS1 was verified to be high-expressed and shared a positive correlation with MYC in glioma. During the DNA repair after DSBs, NBS1 bindings with MRE11 and RAD50 in the nucleus then form the MRN (MRE11-RAD50-NBS1) complex, which directly binds to damaged DNA and initiates homologous recombination-dependent repair.^27,31,32 The MRN complex also recruits and activates ATM, which is a vital kinase in the DNA damage response signaling network.³³ The activation of ATM (p-ATM) modulates hundreds of substrates involved in the cell cycle, DNA repair, and apoptosis.^34–36 To further explore the regulation of HSYA and MYC on DNA repair in glioma cells, the expressions of these DNA repair factors were examined. We discovered that the activation of NBS1, MRE11, RAD50, and ATM was promoted by HSYA, and that siRNA targeting MYC reduced the activation of NBS1 and ATM without affecting MRE11 and RAD50. These phenomena indicated that the MYC silencing inhibited the MRN-ATM, resulting in DNA repair deficiency, and subsequently enhanced the sensitivity of glioma cells to HSYA.

To further verify whether NBS1 was responsible for the increased sensitivity to HSYA in MYC silencing glioma cells, NBS1 was overexpressed in the cells. Then, we detected that the NBS1 overexpression reversed the inhibitory effect on cell viability and the promoting effect on cell apoptosis, also, the sensitivity of MYC-silenced cells to HSYA was reduced by NBS1 overexpression. Mechanically, the inhibited MRN-ATM pathway was promoted by NBS1 overexpression, demonstrating that the effect of MYC silencing on promoting the sensitivity of glioma cells to HSYA was realized by regulating NBS1. Our research revealed that HSYA and MYC silencing had an inhibitory effect on glioma cells. HSYA could promote the expression of MYC in glioma cells and MYC silencing could enhance the sensitivity of glioma cells to HSYA, which could be explained by that both HSYA and MYC silencing could cause the DNA damage of glioma cells. In HSYA-treated glioma cells, the DNA repair response was normal, but MYC silencing could inhibit the MRN-ATM via regulating NBS1 to cause DNA repair deficiency, and subsequently enhanced the sensitivity of glioma cells to HSYA.

Funding

This work was supported by the Key Research and Development Plan of Shaanxi Province [2019SF-058].

Disclosure

The authors declare no conflicts of interest for this work.