This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction
Gastric cancer (GC), the cells of which compose one of the most common malignant tumors, ranks fifth in incidence and fourth in mortality worldwide [1]. The current primary therapy for GC consists of surgical resection, chemotherapy, radiotherapy, and targeted therapy. Since GC often develops asymptomatically, most diagnoses are advanced [2]. Chemotherapy is considered a routine treatment for advanced GC [3]. Unfortunately, its clinical efficacy is limited due to severe side effects and chemoresistance [4]. Glimelius et al. confirmed a median overall survival of 8 months with conventional chemotherapy for advanced-stage GC [5].
The development of tumors involves a complex series of processes, including interactions between cancer cells and the host immune system. Immunotherapy, defined as targeting the immune system to treat disease, has emerged as a promising therapy with fewer adverse reactions and drug resistance than current chemotherapies [6]. The immune checkpoint (IC), which is represented by a group of inhibitory pathways of immune cells, including cytotoxic T lymphocyte-associated antigen-4 (CTLA-4) and programmed death-1 (PD-1), can control the persistence of the immune response while maintaining the body’s self-tolerance [7]. ICs are highly correlated with the initiation of immune cell signalling pathways, through which tumor cells can evade immune surveillance, thus forming a microenvironment conducive to tumor development [8]. Evidence suggests that tumor cells evade antigen-specific T cell immune responses by upregulating IC ligands, such as PD-L1 and PD-L2, on their surfaces [9]. Immune checkpoint inhibitors (ICIs), which block the IC pathway to reinvigorate the antitumor immune response, have become an indispensable part of cancer immunotherapy [7, 10, 11]. PD-1/PD-L1 inhibitors have been shown to rehabilitate T cell activity, strengthen the body’s immune response, and effectively recognize and kill tumor cells, thereby achieving long-term remission of tumor patients [12, 13]. As a classic PD-1 inhibitor, nivolumab has been applied clinically in an increasing number of diseases since it was first approved for treating unresectable or metastatic melanoma in December 2014 [14]. Encouragingly, several clinical studies have shown that nivolumab has achieved lasting efficacy and significant clinical benefits in patients with advanced GC [15–17].
ATXN2, an evolutionarily conserved RNA-binding protein in eukaryotes, is physiologically located in the endoplasmic reticulum and Golgi apparatus, regulates mRNA translation and protein synthesis, and participates in the stress response [18, 19]. However, when cells are subjected to pathological conditions such as damage and energy loss, ATXN2 transcription is enhanced, and ATXN2 mRNAs are translocated to a site referred to as the stress particle, where mRNAs are protected from translation and degradation [20, 21]. Given that ATXN2 can regulate nerve excitability and even circadian rhythm, modulate the endocytosis of trophic receptors and growth pathways, and exert strong effects on mitochondrial precursor proteins and metabolic enzymes, most of the related reports on ATXN2 have been focused on neuro-related and metabolism-related diseases [22–27]. Overexpression of ATXN2 correlated with the proliferation and metastasis of pancreatic cancer [28]. However, to date, the roles and potential mechanisms of ATXN2 in the progression of GC and chemoresistance remain poorly understood.
In this work, we show that ATXN2 is strongly expressed in GC and induces chemoresistance by activating the PI3K/AKT signalling pathway. In addition, ATXN2 can facilitate PD-L1 expression, and silencing ATXN2 results in improved effectiveness of immunotherapy. Our study reveals the dual role of the ATXN2-PI3K/AKT pathway in chemoresistance and immunotherapy, which will contribute to a better understanding of the interaction between chemoresistance and immunotherapy. Our study suggests that targeting SP1 and ATXN2 can alleviate chemoresistance and promote immune drug efficacy. Our study provides new ideas and strategies for clinical chemoresistance and immunotherapy resistance.
2. Results
2.1. ATXN2 Is Associated with Chemoresistance and Prognosis of GC
We screened differentially expressed genes from the high-throughput sequencing data of SGC7901 cells and three lines of chemoresistant GC cells (Figure 1(a)). In total, 889 and 1114 genes were upregulated and downregulated, respectively, in the chemoresistant GC cells (Figures 1(b) and 1(c)). KEGG pathway enrichment analysis revealed significant changes in signalling pathways such as “cell cycle” and “apoptosis” (Figures 1(d) and 1(e)). Furthermore, protein–protein interaction (PPI) network analysis based on the sequencing data consisted of 277 nodes and 603 edges (Figure S1). Fifteen of the central nodes were screened from 277 nodes according to betweenness centrality, eccentricity, and stress algorithms (Figure 1(f)). We then examined the expression and prognosis of the 15 hub genes in GC with the GEPIA database and Kaplan–Meier Plotter database and discovered upregulated ATXN2 expression in GC with the highest hazard ratio (
[figure(s) omitted; refer to PDF]
2.2. High ATXN2 Expression Promotes Chemoresistance in GC
The effects of ATXN2 on GC chemoresistance were examined using gain/loss-of-function models in vitro (Figures 2(a) and 2(b)). The results of the cell apoptosis assay indicated that upregulation of ATXN2 reduced apoptosis induced by 5-FU in SGC7901 cells, while downregulation of ATXN2 promoted apoptosis (Figure 2(c)). Moreover, when ATXN2 was upregulated, the IC50 (for 5-FU) of SGC7901 cells increased; when ATXN2 was downregulated, the IC50 (for 5-FU) of drug-resistant GC cells decreased (Figure 2(d)). The results of animal models showed that knocking down ATXN2 decreased the tumor weight and volume of nude mice treated with 5-FU (Figure 2(e)). Immunohistochemical staining of nude mouse tumor tissues showed that knockdown of ATXN2 inhibited ki67 expression and promoted cleaved caspase-3 expression (Figure 2(f)). In summary, these results suggest that ATXN2 exhibits remarkable antiapoptotic and chemoresistance abilities.
[figure(s) omitted; refer to PDF]
2.3. ATXN2 Promotes Drug Resistance through Activation of the PI3K/AKT/BCL2L1 Pathway
High-throughput sequencing was performed on SGC7901/5-FU and downregulated ATXN2 cells, and differentially expressed genes were identified (Figure 3(a)). ATXN2-silenced SGC7901/5-FU cells showed pathway expression profiles that differed from those of the control cells, in which the PI3K-AKT pathway was among the strongly downregulated pathways (Figure 3(b)). Next, we verified that the phosphorylation of PI3K and AKT significantly increased when ATXN2 was upregulated and decreased when ATXN2 was downregulated (Figure 3(c)). We then found that an AKT inhibitor (AKT-IN-1) was capable of counteracting the reduced cell apoptosis induced by 5-FU resulting from upregulation of ATXN2 (Figures 3(d) and 3(e)). Furthermore, we analysed the genes enriched in the PI3K/AKT signalling pathway and identified BCL2L1 as the gene with the greatest variation (Figure 3(f)). The protein encoded by BCL2L1 belongs to the BCL-2 family, of which the family members form dimers and are involved in various cellular activities as antiapoptotic regulators. ATXN2 regulated the expression of BCL2L1 (Figure 3(g)), and downregulation of BCL2L1 blocked the increase in cell apoptosis caused by ATXN elevation (Figures 3(h) and 3(i)). Finally, analysis of the contents of the TCIA and GEPIA databases showed that ATXN2 expression positively correlated with BCL2L1 and AKT in GC (Figure 3(j)).
[figure(s) omitted; refer to PDF]
2.4. ATXN2 Increases PD-L1 Expression in GC Cells
By analysing the TIMER database, we found that ATXN2 was closely associated with the infiltration of immune cells in GC (Figure 4(a)). Since PD-L1 is a well-known IC and PD-L1 is regulated by PI3K/AKT [29], we explored the interaction between ATXN2 and PD-L1. ATXN2 overexpression promoted PD-L1 expression, and ATXN2 knockdown inhibited PD-L1 expression (Figures 4(b) and 4(c)). Application of an AKT inhibitor largely offsets the increase in PD-L1 expression caused by ATXN2 overexpression (Figures 4(d) and 4(e)). We then cocultured CD8+ T cells with GC cells and added an AKT inhibitor and nivolumab as treatments (Figure 4(f)). Upregulation of ATXN2 reduced CD8+ T cell killing capacity, which was reversed by supplementation with an AKT inhibitor (Figure 4(g)). Moreover, in CD8+ T cells, both AKT inhibitors and nivolumab enhanced the killing capacity, and the drug combination enabled the strongest killing capacity (Figure 4(h)). In summary, the above findings indicated that ATXN2 leads to PD-L1 elevation by activating the PI3K/AKT pathway, subsequently modulating immunotherapy efficacy.
[figure(s) omitted; refer to PDF]
2.5. SP1 Transcriptionally Activates ATXN2 in GC
To explore the cause of elevated ATXN2 expression, we analysed the contents of the JASPAR database and PROMO database and identified three transcription factors, namely, SP1, GATA3, and TCF4 (Figure 5(a)). We then conducted a correlation analysis and found that the strongest correlation occurred between SP1 and ATXN2 in both the TCIA database (Figure 5(b)) and the GEPIA database (Figure 5(c)). The elevated SP1 of GC was shown in the GEPIA database and was related to a poor GC prognosis (Figures 5(d) and 5(e)). The results from SGC7901 cells showed that upregulating SP1 promoted ATXN2 expression. Furthermore, SP1 silencing inhibited ATXN2 expression in SGC7901/5FU cells (Figures 5(f) and 5(g)). In addition, a dual-luciferase reporter assay demonstrated the binding of SP1 to the ATXN2 promoter region (Figures 5(h) and 5(i)). Furthermore, we analysed the correlation between SP1, BCL2L1, and PD-L1 in the GEPIA and TCIA databases and found that SP1 was positively related to BCL2L1 and PD-L1 (Figure 6(a)). We cotransfected SP1-expressing plasmids and ATXN2-targeting siRNA into SGC7901 cells and discovered that SP1 overexpression increased BLC2L1 and PD-L1 expression, which could be blocked by ATXN2 silencing (Figure 6(b)). In addition, we cotransfected SP1-targeting siRNA and ATXN2-expressing plasmids into SGC7901/5-FU cells and found that SP1 silencing decreased BLC2L1 and PD-L1 expression, which could be offset by ATXN2 overexpression (Figure 6(c)). The apoptosis assay showed that SP1 upregulation reduced the cell apoptosis rate in response to 5-FU, which was reversed by ATXN2 silencing or BCL2L1 silencing (Figure 6(d)). Finally, we transfected SP1-expressing plasmids and added an AKT inhibitor or nivolumab into SGC7901 cells, which were then cocultured with CD8+ T cells. The cell survival assay indicated that overexpression of SP1 decreased the response towards CD8+ T cell killing, whereas an AKT inhibitor and nivolumab increased the response (Figure 6(e)). The combination of an AKT inhibitor and nivolumab showed the strongest response to CD8+ T cell killing. In conclusion, these results suggest that SP1 transcriptionally regulates ATXN2 expression, which activates the PI3K-AKT/BCL2L1 and PI3K-AKT/PD-L1 pathways to influence chemoresistance and immunotherapy (Figure 6(f)).
[figure(s) omitted; refer to PDF]
3. Materials and Methods
3.1. Cell Culture
The GC cell line SGC7901 was purchased from the American Type Culture Collection (ATCC). SGC7901/5-FU, SGC7901/ADR, and SGC7901/VCR cells were obtained through stepwise screening with VCR, ADR, and 5-FU in our laboratory. All cells were cultured in Dulbecco’s modified Eagle’s medium (Gibco, USA) containing 10% foetal bovine serum (Gibco, USA).
3.2. Reagents
5-Fluorouracil was obtained from MicroCode Engineering (MCE, USA). The AKT inhibitor (AKT-IN-1) and nivolumab were purchased from MCE (USA). All reagents were added according to the manufacturer’s recommendation.
3.3. RNA Extraction and qPCR
RNA extraction was performed in accordance with the recommendation from Qiagen (Germany). The PCR primers were as follows: ATXN2, forward 5
3.4. Protein Extraction and Western Blots
Protein extraction from cells was performed using RIPA lysis buffer. The protein concentration was determined, and protein denaturation was conducted by boiling for 10 minutes. Thirty micrograms of protein was used for electrophoresis. After blocking with 10% skim milk, the protein membranes were immersed in primary antibody (4°C, overnight) followed by incubation with secondary antibody for 1 hour. The protein membranes were subjected to chemiluminescence. The antibodies used were as follows: anti-ATXN2 from Santa Cruz (USA) and anti-β-actin, anti-PI3K, anti-p-PI3K, anti-AKT, anti-p-AKT, anti-BCL2L1, and anti-PD-L1 from CST (USA).
3.5. Immunohistochemistry (IHC)
Immunohistochemical staining was performed using anti-Ki67 and anti-Cleaved caspase 3(CST, USA) antibodies according to the manufacturer’s recommendation. The ratio (positive cell number to total cell number) was calculated to indicate the expression score.
3.6. Dual-Luciferase Reporter Assays
Bioinformatics methods were used to predict and analyse the possible transcription factor-binding sites of ATXN2. Then, the DNA fragment containing the ATXN2 promoter in the human genome was amplified according to the primer sequence and plugged into the reporter vector. The reporter gene plasmid and SP1-expression plasmid were cotransfected into SGC7901 cells. Finally, the luciferase activity was determined, and the relative fluorescence intensity was calculated.
3.7. IC50 Assay
After the plating and attachment of 3000 cells, PBS or 5-FU was added to every well of 96-well plates. CCK-8 (Abcam, USA) was diluted and added to 96-well plates for 2 h of incubation. The absorbance value was measured with a Multimode Reader (Bio-Rad, USA). The IC50 value was then calculated according to the number of viable cells in the PBS or 5-FU groups.
3.8. Apoptosis Detection
Cells were trypsinized, aspirated, centrifuged, and then evenly mixed in PBS. Cells (100 μL) were transferred into a flow tube with Annexin V and 7-AAD reagents, and incubation was maintained for 30 minutes under dark conditions. The cell suspension was examined via flow cytometry after being washed with PBS.
3.9. In Vivo Tumorigenicity
Subcutaneous transplantation of target cells (
3.10. CD8+ T Cell Activation and Coculture
CD8+ T cells from STEMCELL (USA) were activated using a specialized T cell activator (Catalogue # 10971) as recommended, collected, cocultured with GC cells for 24 h, and washed off. The survival rate of GC cells was measured with CCK-8.
3.11. Bioinformatics Analysis
Protein–protein interaction (PPI) network analysis was used to analyse the interaction between proteins. The GEPIA database, KM plotter database, UALCAN database, and TCIA database were used to analyse the expression and clinical prognosis of genes. The TIMER database was used to analyse the relationship between ATXN2 and immune cell infiltration. The JASPAR database and PROMO database were used to predict the transcription factors of ATXN2.
3.12. Statistical Analyses
The SPSS software (version 23.0) was employed for data analysis.
4. Discussion
With approximately 480,000 new cases in 2020, GC has become the third most prevalent malignancy in China [1]. As chemotherapy remains the primary treatment choice for progressive GC, chemoresistance has a more prominent impact on GC treatment compared with other cancers and is the most problematic issue in our clinical work, which greatly affects patient survival [3]. The Ataxin-2 protein encoded by ATXN2 is a protein involved in RNA metabolism and metabolic homeostasis [30]. In our study, we revealed that ATXN2 has proliferative and antiapoptotic effects and that a high ATXN2 level was related to an adverse prognosis. Elevated ATXN2 expression facilitated 5-FU resistance in GC cells, which was decreased by downregulating ATXN2. Additionally, ATXN2 enhanced BCL2L1 expression (an antiapoptotic factor) by activating PI3K/AKT signalling, ultimately resulting in 5-FU resistance.
Immune cells within the tumor microenvironment (TME) are involved in tumorigenesis development [31]. Immune cells, especially infiltrating T cells, can recognize tumor antigens and participate in killing tumor cells [32]. However, clinically detected cancers often evade the antitumor immune response of immune cells. The ability of immune evasion is emerging as a new hallmark of cancer, unexpectedly providing an opportunity for a new strategy in cancer therapy, namely, the use of immune cells against cancer cells. Recently, IC modulators have shown unexpected antitumor effects in a variety of cancers, opening a new era in cancer therapy. PD-L1 is critical in physiological immune homeostasis and tumor immune escape [33]. The PI3K/AKT signalling pathway regulates PD-L1 expression in tumor cells [29, 34, 35]. Our results confirmed a close connection between ATXN2 and immune cell infiltration in GC and proved that elevated ATXN2 promoted PD-L1 expression. Furthermore, our results revealed that ATXN2 promotes PD-L1 expression by activating the PI3K/AKT pathway and that ATXN2 knockdown promoted the efficacy of immunotherapy.
The abundance of SP1, an important transcription factor, is typically increased in most tumors, and SP1 participates in tumor cell proliferation, differentiation, DNA damage response, apoptosis, senescence, and angiogenesis [36, 37]. Our work confirmed the binding between SP1 and the ATXN2 promoter region and the promotion of ATXN2 mRNA and protein expression by SP1. We also found that SP1 transcriptionally activated ATXN2, allowing this protein to participate in chemoresistance and escape from immune surveillance in GC. In summary, our study revealed that the SP1/ATXN2/PI3K-AKT/BCL2L1 pathway promotes GC chemoresistance and that the SP1/ATXN2/PI3K-AKT/PD-L1 pathway promotes GC immune escape. The correlation between tumor chemoresistance and immunity is not very clear. Our study linked chemoresistance to tumor immunotherapy and found that the key hub is the PI3K-Akt pathway. Inhibition of the PI3K-Akt pathway can significantly reduce chemoresistance and enhance the efficacy of immunotherapy. Our study will provide a reference for inhibitors of the PI3K-AKT pathway to address chemoresistance and improve the efficacy of immunotherapy. Our findings provide a potential therapeutic approach to address GC chemoresistance, as well as a new theoretical and experimental basis for immunotherapy of GC.
Ethical Approval
All animal research was approved by the Animal Care Committee of the Fourth Military Medical University and performed in accordance with the Association for Accreditation of Laboratory Animal Care and Institutional Animal Care and Use Committee guidelines.
Authors’ Contributions
Q.W. and S.H. were responsible for the conceptualization. T.C. and X.Z. were responsible for the methodology. T.C. was responsible for the software. Q.W., X.Z., C.W., and W.Z. were responsible for the validation. Q.W. was responsible for the formal analysis. Q.W. and J.H. were responsible for the writing—original draft preparation. T.C., P.W., and Y.Z. were responsible for the writing—review and editing. S.H. was responsible for the supervision. S.H. was responsible for the funding acquisition. All authors have read and agreed to the published version of the manuscript. Qi Wang, Tianyu Cao, and Xiaohui Zhang equally contributed to this article.
[1] H. Sung, J. Ferlay, R. L. Siegel, M. Laversanne, I. Soerjomataram, A. Jemal, F. Bray, "Global Cancer Statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries," CA: a Cancer Journal for Clinicians, vol. 71 no. 3, pp. 209-249, DOI: 10.3322/caac.21660, 2021.
[2] E. Van Cutsem, X. Sagaert, B. Topal, K. Haustermans, H. Prenen, "Gastric cancer," The Lancet, vol. 388 no. 10060, pp. 2654-2664, DOI: 10.1016/S0140-6736(16)30354-3, 2016.
[3] N. Charalampakis, P. Economopoulou, I. Kotsantis, M. Tolia, D. Schizas, T. Liakakos, E. Elimova, J. A. Ajani, A. Psyrri, "Medical management of gastric cancer: a 2017 update," Cancer Med-Us, vol. 7 no. 1, pp. 123-133, DOI: 10.1002/cam4.1274, 2018.
[4] A. D. Wagner, N. L. Syn, M. Moehler, W. Grothe, W. P. Yong, B. C. Tai, J. Ho, S. Unverzagt, Cochrane Upper GI and Pancreatic Diseases Group, "Chemotherapy for advanced gastric cancer," Cochrane Db Syst Rev, vol. 8,DOI: 10.1002/14651858.CD004064.pub4, 2017.
[5] B. Glimelius, K. Ekström, K. Hoffman, W. Graf, P. O. Sjödén, U. Haglund, C. Svensson, L. K. Enander, T. Linné, H. Sellsröm, R. Heuman, "Randomized comparison between chemotherapy plus best supportive care with best supportive care in advanced gastric cancer," Annals of Oncology, vol. 8 no. 2, pp. 163-168, DOI: 10.1023/A:1008243606668, 1997.
[6] L. Cui, X. Wang, D. Zhang, "TLRs as a promise target along with immune checkpoint against gastric cancer," Frontiers in Cell and Development Biology, vol. 8, article 611444,DOI: 10.3389/fcell.2020.611444, 2021.
[7] D. M. Pardoll, "The blockade of immune checkpoints in cancer immunotherapy," Nature Reviews. Cancer, vol. 12 no. 4, pp. 252-264, DOI: 10.1038/nrc3239, 2012.
[8] F. K. Dermani, P. Samadi, G. Rahmani, A. K. Kohlan, R. Najafi, "PD-1/PD-L1 immune checkpoint: potential target for cancer therapy," Journal of Cellular Physiology, vol. 234 no. 2, pp. 1313-1325, DOI: 10.1002/jcp.27172, 2019.
[9] L. Osmani, F. Askin, E. Gabrielson, Q. K. Li, "Current WHO guidelines and the critical role of immunohistochemical markers in the subclassification of non-small cell lung carcinoma (NSCLC): moving from targeted therapy to immunotherapy," Seminars in Cancer Biology, vol. 52, Part 1, pp. 103-109, DOI: 10.1016/j.semcancer.2017.11.019, 2018.
[10] K. Li, A. Zhang, X. Li, H. Zhang, L. Zhao, "Advances in clinical immunotherapy for gastric cancer," Biochimica Et Biophysica Acta. Reviews on Cancer, vol. 1876 no. 2, article 188615,DOI: 10.1016/j.bbcan.2021.188615, 2021.
[11] M. A. Postow, M. K. Callahan, J. D. Wolchok, "Immune checkpoint blockade in cancer therapy," Journal of Clinical Oncology, vol. 33 no. 17, pp. 1974-1982, DOI: 10.1200/JCO.2014.59.4358, 2015.
[12] J. Sun, Y. Zheng, M. Mamun, X. Li, X. Chen, Y. Gao, "Research progress of PD-1/PD-L1 immunotherapy in gastrointestinal tumors," Biomedicine & Pharmacotherapy, vol. 129, article 110504,DOI: 10.1016/j.biopha.2020.110504, 2020.
[13] M. E. Keir, M. J. Butte, G. J. Freeman, A. H. Sharpe, "PD-1 and its ligands in tolerance and immunity," Annual Review of Immunology, vol. 26 no. 1, pp. 677-704, DOI: 10.1146/annurev.immunol.26.021607.090331, 2008.
[14] J. Gong, A. Chehrazi-Raffle, S. Reddi, R. Salgia, "Development of PD-1 and PD-L1 inhibitors as a form of cancer immunotherapy: a comprehensive review of registration trials and future considerations," Journal for Immunotherapy of Cancer, vol. 6 no. 1,DOI: 10.1186/s40425-018-0316-z, 2018.
[15] Y. Kang, N. Boku, T. Satoh, M. H. Ryu, Y. Chao, K. Kato, H. C. Chung, J. S. Chen, K. Muro, W. K. Kang, K. H. Yeh, T. Yoshikawa, S. C. Oh, L. Y. Bai, T. Tamura, K. W. Lee, Y. Hamamoto, J. G. Kim, K. Chin, D. Y. Oh, K. Minashi, J. Y. Cho, M. Tsuda, L. T. Chen, "Nivolumab in patients with advanced gastric or gastro-oesophageal junction cancer refractory to, or intolerant of, at least two previous chemotherapy regimens (ONO-4538-12, ATTRACTION-2): a randomised, double-blind, placebo- controlled, phase 3 trial," The Lancet, vol. 390 no. 10111, pp. 2461-2471, DOI: 10.1016/S0140-6736(17)31827-5, 2017.
[16] N. Boku, T. Satoh, M. Ryu, Y. Chao, K. Kato, H. C. Chung, J. S. Chen, K. Muro, W. K. Kang, K. H. Yeh, T. Yoshikawa, S. C. Oh, L. Y. Bai, T. Tamura, K. W. Lee, Y. Hamamoto, J. G. Kim, K. Chin, D. Y. Oh, K. Minashi, J. Y. Cho, M. Tsuda, T. Nishiyama, L. T. Chen, Y. K. Kang, "Nivolumab in previously treated advanced gastric cancer (ATTRACTION-2): 3-year update and outcome of treatment beyond progression with nivolumab," Gastric Cancer, vol. 24 no. 4, pp. 946-958, DOI: 10.1007/s10120-021-01173-w, 2021.
[17] M. Nishino, A. Giobbie-Hurder, H. Hatabu, N. H. Ramaiya, F. S. Hodi, "Incidence of programmed cell death 1 inhibitor–related pneumonitis in patients with advanced cancer," JAMA Oncology, vol. 2 no. 12, pp. 1607-1616, DOI: 10.1001/jamaoncol.2016.2453, 2016.
[18] T. C. Fleischer, C. M. Weaver, K. J. McAfee, J. L. Jennings, A. J. Link, "Systematic identification and functional screens of uncharacterized proteins associated with eukaryotic ribosomal complexes," Gene Dev, vol. 20 no. 10, pp. 1294-1307, DOI: 10.1101/gad.1422006, 2006.
[19] S. van de Loo, F. Eich, D. Nonis, G. Auburger, J. Nowock, "Ataxin-2 associates with rough endoplasmic reticulum," Experimental Neurology, vol. 215 no. 1, pp. 110-118, DOI: 10.1016/j.expneurol.2008.09.020, 2009.
[20] N. Kedersha, P. Ivanov, P. Anderson, "Stress granules and cell signaling: more than just a passing phase?," Trends in Biochemical Sciences, vol. 38 no. 10, pp. 494-506, DOI: 10.1016/j.tibs.2013.07.004, 2013.
[21] U. Nonhoff, M. Ralser, F. Welzel, I. Piccini, D. Balzereit, M. L. Yaspo, H. Lehrach, S. Krobitsch, "Ataxin-2 interacts with the DEAD/H-box RNA helicase DDX6 and interferes with P-bodies and stress granules," Molecular Biology of the Cell, vol. 18 no. 4, pp. 1385-1396, DOI: 10.1091/mbc.e06-12-1120, 2007.
[22] G. Auburger, N. Sen, D. Meierhofer, A. N. Başak, A. D. Gitler, "Efficient prevention of neurodegenerative diseases by depletion of starvation response factor Ataxin-2," Trends in Neurosciences, vol. 40 no. 8, pp. 507-516, DOI: 10.1016/j.tins.2017.06.004, 2017.
[23] I. Lastres-Becker, S. Brodesser, D. Lütjohann, M. Azizov, J. Buchmann, E. Hintermann, K. Sandhoff, A. Schürmann, J. Nowock, G. Auburger, "Insulin receptor and lipid metabolism pathology in ataxin-2 knock-out mice," Human Molecular Genetics, vol. 17 no. 10, pp. 1465-1481, DOI: 10.1093/hmg/ddn035, 2008.
[24] J. Drost, D. Nonis, F. Eich, O. Leske, E. Damrath, E. R. Brunt, I. Lastres-Becker, R. Heumann, J. Nowock, G. Auburger, "Ataxin-2 modulates the levels of Grb2 and SRC but not ras signaling," Journal of Molecular Neuroscience, vol. 51 no. 1, pp. 68-81, DOI: 10.1007/s12031-012-9949-4, 2013.
[25] J. Liu, T. S. Tang, H. Tu, O. Nelson, E. Herndon, D. P. Huynh, S. M. Pulst, I. Bezprozvanny, "Deranged calcium signaling and neurodegeneration in spinocerebellar ataxia type 2," The Journal of Neuroscience, vol. 29 no. 29, pp. 9148-9162, DOI: 10.1523/JNEUROSCI.0660-09.2009, 2009.
[26] I. P. Sudhakaran, J. Hillebrand, A. Dervan, S. das, E. E. Holohan, J. Hülsmeier, M. Sarov, R. Parker, K. VijayRaghavan, M. Ramaswami, "FMRP and Ataxin-2 function together in long-term olfactory habituation and neuronal translational control," Proceedings of the National Academy of Sciences, vol. 111 no. 1, pp. E99-E108, DOI: 10.1073/pnas.1309543111, 2014.
[27] M. Pfeffer, S. Gispert, G. Auburger, H. Wicht, H. W. Korf, "Impact of Ataxin-2 knock out on circadian locomotor behavior and PER immunoreaction in the SCN of mice," Chronobiology International, vol. 34 no. 1, pp. 129-137, DOI: 10.1080/07420528.2016.1245666, 2017.
[28] L. Fang, S. H. Wang, Y. G. Cui, L. Huang, "LINC00941 promotes proliferation and metastasis of pancreatic adenocarcinoma by competitively binding miR-873-3p and thus upregulates ATXN2," European Review for Medical and Pharmacological Sciences, vol. 25 no. 4, pp. 1861-1868, DOI: 10.26355/eurrev_202102_25081, 2021.
[29] E. A. Mittendorf, A. V. Philips, F. Meric-Bernstam, N. Qiao, Y. Wu, S. Harrington, X. Su, Y. Wang, A. M. Gonzalez-Angulo, A. Akcakanat, A. Chawla, M. Curran, P. Hwu, P. Sharma, J. K. Litton, J. J. Molldrem, G. Alatrash, "PD-L1 expression in triple-negative breast cancer," Cancer Immunology Research, vol. 2 no. 4, pp. 361-370, DOI: 10.1158/2326-6066.CIR-13-0127, 2014.
[30] R. Li, L. Zeng, H. Zhao, J. Deng, L. Pan, S. Zhang, G. Wu, Y. Ye, J. Zhang, J. Su, Y. Zheng, S. Deng, R. Bai, L. Zhuang, M. Li, Z. Zuo, D. Lin, J. Zheng, X. Huang, "ATXN2-mediated translation of TNFR1 promotes esophageal squamous cell carcinoma via m 6 A-dependent manner," Molecular Therapy, vol. 30 no. 3, pp. 1089-1103, DOI: 10.1016/j.ymthe.2022.01.006, 2022.
[31] X. Ren, L. Zhang, Y. Zhang, Z. Li, N. Siemers, Z. Zhang, "Insights gained from single-cell analysis of immune cells in the tumor microenvironment," Annual Review of Immunology, vol. 39 no. 1, pp. 583-609, DOI: 10.1146/annurev-immunol-110519-071134, 2021.
[32] C. Zheng, L. Zheng, J. Yoo, H. Guo, Y. Zhang, X. Guo, B. Kang, R. Hu, J. Y. Huang, Q. Zhang, Z. Liu, M. Dong, X. Hu, W. Ouyang, J. Peng, Z. Zhang, "Landscape of infiltrating T cells in liver cancer revealed by single-cell sequencing," Cell, vol. 169 no. 7, pp. 1342-1356.e16, DOI: 10.1016/j.cell.2017.05.035, 2017.
[33] X. Shen, B. Zhao, "Efficacy of PD-1 or PD-L1 inhibitors and PD-L1 expression status in cancer: meta-analysis," BMJ, vol. 362,DOI: 10.1136/bmj.k3529, 2018.
[34] R. Zhao, Y. Song, Y. Wang, Y. Huang, Z. Li, Y. Cui, M. Yi, L. Xia, W. Zhuang, X. Wu, Y. Zhou, "PD-1/PD-L1 blockade rescue exhausted CD8+ T cells in gastrointestinal stromal tumours via the PI3K/Akt/mTOR signalling pathway," Cell Proliferat, vol. 52 no. 3, article e12571,DOI: 10.1111/cpr.12571, 2019.
[35] Y. Gao, J. Yang, Y. Cai, S. Fu, N. Zhang, X. Fu, L. Li, "IFN- γ -mediated inhibition of lung cancer correlates with PD-L1 expression and is regulated by PI3K-AKT signaling," International Journal of Cancer, vol. 143 no. 4, pp. 931-943, DOI: 10.1002/ijc.31357, 2018.
[36] C. Vizcaíno, S. Mansilla, J. Portugal, "Sp1 transcription factor: a long-standing target in cancer chemotherapy," Pharmacology & Therapeutics, vol. 152, pp. 111-124, DOI: 10.1016/j.pharmthera.2015.05.008, 2015.
[37] K. Beishline, J. Azizkhan-Clifford, "Sp1 and the ‘hallmarks of cancer’," The FEBS Journal, vol. 282 no. 2, pp. 224-258, DOI: 10.1111/febs.13148, 2015.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Copyright © 2022 Qi Wang et al. This is an open access article distributed under the Creative Commons Attribution License (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. https://creativecommons.org/licenses/by/4.0/
Abstract
As one of the primary therapeutic choices, chemotherapy is widely adopted for progressive gastric cancer (GC), but the development of chemoresistance has limited chemotherapy efficacy and partly contributes to poor prognosis. Immunotherapy is increasingly being applied in the clinical treatment of GC and is also benefitting patients. To ascertain whether ATXN2 affects chemotherapy efficacy in GC cells and its role in GC immune escape, we performed high-throughput sequencing to clarify genes differentially expressed between 5-FU-resistant and 5-FU-sensitive GC cells and then conducted qRT–PCR to assess ATXN2 expression in GC tissues. Furthermore, the influence of ATXN2 on resistance was studied in vitro and in vivo, ATXN2 and other protein expression levels were detected using Western blotting and immunohistochemistry (IHC), and the direct association of SP1 and ATXN2 was confirmed through luciferase reporter gene analysis. We found elevated ATXN2 in GC tumors and a negative correlation between ATXN2 levels and the prognosis of GC. Furthermore, by activating the PI3K/AKT pathway, ATXN2 was found to promote chemoresistance in GC, facilitating BCL2L1 expression. In GC cells, ATXN2 further stimulated PD-L1 expression and provided better immunotherapy efficacy. Finally, we demonstrated that SP1 transcriptionally regulated the expression of ATXN2 and prompted GC chemoresistance and immune escape. In conclusion, our study reveals the important roles of the SP1/ATXN2/PI3K-AKT/BCL2L1 signalling pathway in GC chemoresistance and of the SP1/ATXN2/PI3K-AKT/PD-L1 signalling pathway in GC immunotherapy. Our findings provide new theories and experimental references for overcoming chemotherapy resistance in GC and enhancing the efficacy of immunotherapy for GC.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Details
1 Honghui Hospital, Xi’an Jiaotong University, Xi’an, Shaanxi 710049, China
2 The 928 Hospital of PLA Joint Logistics Support Forces, Haikou, Hainan 570206, China
3 State Key Laboratory of Cancer Biology, National Clinical Research Center for Digestive Diseases and Xijing Hospital of Digestive Diseases, Xijing Hospital, Fourth Military Medical University, Xi’an, Shannxi 710038, China
4 Department of Gastroenterology, Tangdu Hospital, Fourth Military Medical University, 710038 Xi’an, China
5 Department of Gastroenterology, Ningxia Medical University, Yinchuan, Ningxia 750004, China