- Research article
- Open Access
Glucocorticoids promote the development of azoxymethane and dextran sulfate sodium-induced colorectal carcinoma in mice
BMC Cancer volume 19, Article number: 94 (2019)
Stress has been suggested as a promoter of tumor growth and development. Glucocorticoids (GCs) are the main stress hormones and widely prescribed as drugs. However, the effect of GCs on the development and progression of colorectal carcinoma (CRC) is unclear.
We evaluated the effect of corticosterone (CORT) on azoxymethane and dextran sulfate sodium (AOM/DSS)-induced carcinogenesis in the colorectum of C57BL/6 strain mice. Plasma level of CORT was detected by radioimmunoassay. The expression of proliferation markers (Ki-67 and PCNA), nuclear factor (NF)-κB p65 and phosphoto-p65 (P-p65), as well as cyclooxygenase (COX)-2 were determined by immunohistochemistry. Inflammation in colorectum was evaluated by histopathology.
CORT feeding in drinking water of mice not only significantly elevated plasma CORT concentration, but also significantly increased the incidence and neoplasms burden (number and size of neoplasms) in colorectum. CORT also significant enhanced the expression of cell proliferation marker (Ki-67 and PCNA), NF-κB p65 and P-p65 as well as COX-2 in colorectal neoplasm of AOM/DSS-treated mice.
In this study, we have found for the first time that CORT at stress level potentially promotes the growth and development of AOM/DSS-induced colorectal adenoma and carcinoma in mice. Up-regulation of NF-κB and COX-2 may be involved in the promoting effect of CORT.
Clinical studies have linked the experience of stressful events, such as pressure, cancer-related concerns and depression, to poor survival of cancer patients [1, 2]. Preclinical studies also support that chronic stress has an impact on cancer progression and survival [3,4,5]. Glucocorticoids (GCs) are main stress hormones which are secreted dramatically in a state of stress, and play a critical role in the process of immunosuppression, anti-inflammation and homeostasis sustaining . Synthetic GCs, such as dexamethasone, have been widely used as drugs to treat immune and inflammatory disorders. Moreover, GCs are clinically important as adjuvants in non-hematologic cancer therapy to reduce acute toxicity and alleviate side effects induced by chemotherapy or radiotherapy . GCs exert their biological effects by regulating the expression of genes and cross-talking with multiple trans-membrane signalling pathways . The effects of GCs are mediated by glucocorticoid receptor (GR), which is ubiquitously expressed in all cells. Since the activation of GR by GCs control a variety of physiological and cellular processes, such as immune response, metabolism, cell proliferation, apoptosis and survival , the relationship between GCs and solid tumors has been concerned. Although there are reports that GCs have the inhibitory effect on proliferation and progression in several tumors in vitro and in vivo [10,11,12,13], other and our studies have demonstrated that GCs induce resistance to chemotherapy in the majority of solid tumor cells [14,15,16], promote metastasis of pancreatic cancer  and melanoma cells , and increase risks of skin cancer and non-Hodgkin’s lymphoma . It still remains unclear whether these controversial phenomena are attributed to the dose and duration of GC treatment, as well as cell and tissue specific GC signal transduction. Therefore, it is vital to further evaluate the role of GCs in carcinogenesis and progression of different solid tumors, especially in vivo.
Colorectal carcinoma (CRC) is one of the top three diagnosed cancers worldwide. It can develop spontaneously or as a complication of inflammatory bowel diseases. It is believed that chronic inflammation increase the risk of CRC development . Limited studies about the effect of GCs on growth of CRC have been done in vitro and in vivo, and the results are not concordant. Inhibitory effect or promoting effect that GCs showed on growth of CRC depended on cell lines [21,22,23], tumor micro-environment [24, 25] and the delivery formulation and dosage of GCs . In addition, previous animal studies were done using the xenografts model mice which are featured by immunodeficiency, while the result from these mice is not equal to that of intact mice with induced carcinoma in colorectum spontaneously. A mouse CRC model induced by azoxymethane and dextran sulfate sodium (AOM/DSS) is a stable and reliable model of spontaneous tumor and has been used in CRC studies [27,28,29]. AOM is a chemical mutagen, which induces colonic tumor with clinical, histological and molecular features of human sporadic colon cancer, and the follow-up treatment with the non-genotoxic DSS strongly induces inflammation in the colon, thereby enhancing the colon carcinogenesis in rodents . In this study, we investigated whether corticosterone (CORT), a major form of GCs in mouse, influenced the development of CRC in such a mouse model of colorectal carcinogenesis induced by AOM/DSS.
All animal experiments were approved by the Animal Ethics Committee of Second Military Medical University (Shanghai, China) and performed in compliance with the University’s Guidelines for the Care and Use of Laboratory Animals. Six to 8-week-old male mice of C57BL/6 strain (body weight 20 ± 2 g) were purchased from Model Animals Research Centre of Nanjing University (Nanjing, China) and housed under a 12-h light/dark cycle in a specific-pathogen-free (SPF) condition with free access to laboratory chow and water in Experimental Animals Centre of Second Military Medical University. Every cage housed no more than 5 mice. All the mice were fed under the above condition for 2 weeks before the experiment to make the mice adapt to the new environment.
Induction of colorectal carcinogenesis (AOM/DSS treatments)
We followed an outlined protocol  and made some modification. Mice (number = 10) were injected intraperitoneally with 12.5 mg/kg body weight of AOM (Sigma) dissolved in normal saline (NS) and maintained on a regular chow and water. After 7 days, the mice were fed with 2.5% DSS (MW 36000–50,000 kDa, Biomedicals) in the drinking water for 5 days, followed by 14 days of regular drinking water for recovery. This cycle was repeated 3 times, after that, mice were fed with regular chow and water till the end (Day 78). Control mice (number = 4) were injected intraperitoneally with NS on the first day and given with free access to laboratory chow and water till the end that the mice were killed by cervical dislocation (Fig. 1a). Two mouse in AOM/DSS treatment group and no mice in control group died before the end of experiment.
CORT (Sigma) was dissolved in ethanol to obtain the working solution (10 mg/mL), which was then diluted with water to get the feeding solution (50 mg/L) according to the literature [31,32,33]. As the overall experiment schedule showed in Fig. 2a, model mice recovered for 7 days after the last cycle of DSS treatment and then fed with vehicle (0.5% ethanol, number = 10) or CORT (number = 11) randomly for 31 days till killed by cervical dislocation for further analysis. Two mice in vehicle group and 3 mice in CORT group died before the end of experiment. Figure 2b outlines the methodology workflow of the study.
Quantification of CORT in vivo
At the end of the experiment, all mice were anesthetized with 5% ethyl urethane (30 μL/g body weight) for blood collection from the ciliary venous plexus at dusk to avoid the influence of physiological GC fluctuation in vivo as far as possible. Collected blood samples were placed at 4 °C for 20 min and then centrifuged at 4 °C for 1 min at 10000 rpm, and the liquid supernatants were used for CORT detection by radioimmunoassay and expressed as pg/mL plasma.
Mice were weighed weekly during the whole experiment. At the end of the experiment, all mice were killed by cervical dislocation and then dissected. Colorectum was removed, opened longitudinally and rinsed with ice-cold phosphate buffer solution for macroscopic inspection, and then fixed overnight with 4% formalin for histological analysis. Every entire colorectum was measured in length and photographed. Grossly visible neoplasms were counted and measured in diameter with an electronic vernier caliper. The sums of area load and volume load per colorectum were calculated with the formula, area = [(length + width)*0.5]2 and volume = length*width2*0.52. Evaluation was performed without any knowledge of the treatment type.
Histopathology, inflammation score analysis and immunohistochemistry analysis
Colorectal tissues were processed by routine histological methods: fixed, sampled, dehydrated, embedded in paraffin, sectioned and stained with hematoxylin and eosin (H&E) for histopathological evaluation, which were preformed independently by two trained pathologists in a blinded manner. According to histopathology, adenoma with low grade dysplasia was defined as adenomatous changes with simple glandular architecture and low grade nuclei form. Adenoma with high grade dysplasia was defined as adenomatous changes with architectural complexities and high grade nuclei form. Intramucosal carcinoma was defined as high-grade dysplasia with invasion of neoplastic cells into the lamina propria but not through the muscularis mucosa. Adenocarcinoma (ACA) was defined as invasion of neoplastic cells into or even through the submucosa [34, 35].
Histological evaluation of inflammation in the colorectum was performed using a semi-quantitative scoring system by two pathologists. In brief, scores were given for percent ulceration (0–3), percent reepithelialization (0–4), active inflammation (0–3), chronic inflammation (0–3), and transmural inflammation (0–3) . Inflammation was scored as follows: 0, no inflammation; 1, modest numbers of infiltrating leukocytes (neutrophile granulocyte for acute inflammation and lymphocyte for chronic inflammation) in the lamina propria; 2, infiltration of leukocytes leading to separation of crypts and mild mucosal hyperplasia; 3, massive infiltration of inflammatory cells accompanied by disrupted mucosal architecture and complete loss of goblet cells. Then sum the scores up for analysis. The tissues embedded in paraffin were cut serially into 4-μm-thick sections for immunohistochemistry (IHC) analysis. IHC staining with rabbit anti-mouse proliferating cell nuclear antigen (PCNA) polyclonal antibody (dilution 1:200, Santa cruz, #sc-7907), rabbit anti-mouse Ki-67 monoclonal antibody (dilution 1:200, abcam, #ab16667), rabbit anti-mouse NF-κB p65 monoclonal antibody (dilution 1:100, CST, #4764), rabbit anti-mouse NF-κB P-p65 monoclonal antibody (dilution 1:100, Ser536, CST, #3033) and rabbit anti-mouse COX-2 monoclonal antibody (dilution 1:100, cayman chemical, #160112) were performed using EnVision™ systems (Dako, Demark) according to the manufacturer’s instructions.
Statistical analysis was performed using GraphPad Prism (version 5.0) software or SPSS (version 18.0) software. Data were expressed as the means ± SD. The unpaired t-test (Student’s t-test) was used to compare with two groups, and the one-way or two-way ANOVA was used to compare with more than two groups. A Pearson’s χ2 test was used to test the significance of association between different treatment and pathological diagnosed types. Differences were considered significant at P < 0.05.
Establishment of colorectal carcinoma murine model
Firstly, we established the mice CRC model according to a modified protocol for the AOM/DSS-induced colorectal cancer (Fig. 1a). At the end of the experiment, mice were sacrificed for further analysis. Macroscopic observation of colorectum showed that the length of colorectum of model mouse was much shorter than that of the control one. Neoplasms were observed in the colons and recta of the model mice, but not in the control ones (Fig. 1b). Pathological examination confirmed the most of neoplasms as adenocarcinoma (ACA) (Fig. 1c). Meanwhile, we tested the plasma CORT of mice by radioimmunoassay and the results showed that the plasma levels of CORT in the model mice were higher than those of the control ones (1.68-fold, P < 0.01, Fig. 1d), which may be due to tumor-related stress induced by AOM/DSS.
CORT treatment significantly increased the plasma CORT concentration
Furthermore, we administrated the model mice with CORT treatment (CT) or vehicle treatment (VT). CORT administration can be performed in different ways, such as implanting extended-release agents subcutaneously, intraperitoneal injection or feeding in drinking water, at different stages of CRC model induced by AOM/DSS. We firstly fed CORT (50 mg/L) in drinking water or implanted extended-release CORT (7.5 mg-60 days) subcutaneously at the early stage (after the first cycle of DSS) of model mice. However, both ways of CORT administration led to high mortality of model mice, which may ascribe to high metabolism rate and immunosuppression of CORT. So we fumbled experimental condition and put off the time of CORT administration to a week after the third cycle of DSS treatment. Compared with implanting extended-release CORT agents which may cause stress in the implanting surgery, we chose CORT administration in drinking water (Fig. 2a). Treating mice with CORT for 31 days in this way did not significantly affect the death rate (3/11 of CT versus 2/10 of VT) of mice (Fig. 2c). At the end of experiment, we found that plasma CORT level of CT mice further increased about 1.74-fold compared with that of VT ones (P < 0.01, Fig. 2d). We also observed more rich of omental fat in the CT mice compared with that of VT ones and it indicated that CORT slightly increased the body weight of mice, which may be due to the fat storage effect of CORT (data not shown).
CORT promoted development of AOM/DSS-induced colorectal carcinoma in mice
Then we investigated the effects of CORT on the development of AOM/DSS-induced CRC in mice. Macroscopic views of the colorectum from each treatment mice are shown in Fig. 3a. A higher neoplasm burden was observed especially in the distal colon and rectum areas of the CT mouse as compared with that of the VT one. Further analysis showed that administration of CORT resulted in significantly increased number (1.7-fold, P < 0.01), area (2.1-fold, P < 0.01) and volume(2.2-fold, P < 0.05) of neoplasms in colorectum (Fig. 3b, c and d). The size distribution of neoplasms in CT mice was obviously larger than that of the VT ones, especially in diameter more than 3 mm (Fig. 3e). Pathological examination showed that main histological alteration of colorectum was adenoma with low grade dysplasia (62.5%) and adenoma with high grade dysplasia (25%) in the VT mice, whereas intramucosal carcinoma or ACA (75%) in the CT mice (Table 1). These results indicated that the administration of CORT significantly increased the total incidence of colorectal neoplasms and promoted the shift of pathological types (from adenoma with low grade dysplasia to intramucosal carcinoma or ACA) in model mice.
Elevated expression of cell proliferation marker in CORT-treated mice
We further examined the expression of cell proliferation marker, Ki-67 and PCNA in the neoplasms of both CT and VT mice as well as normal colorectal epithelia with IHC analysis. The results showed that administration of CORT significantly elevated Ki-67 and PCNA expression in colonic epitheliums of neoplasms, including pathological type adenoma with low grade dysplasia, adenoma with high grade dysplasia and ACA. Whereas in normal epithelia, Ki-67 is mainly expressed in basal cells, but hardly expressed in glandular epithelial cells, and the staining of PCNA are rarely seen (Fig. 4a and b). Figure 4c showed the statistical results of positive staining percent, which were consistent with the macroscopic observation results, indicating that CORT promoted the growth and development of AOM/DSS-induced colorectal adenoma and carcinoma in mice.
CORT promoted expression of NF-κB and COX-2 in colorectal neoplasms
Nuclear factor (NF)-κB, which consists of a number of closely related protein dimers (mainly the p50 and p65) is an important transcription factor and a key mediator of immune and inflammatory responses. Phosphorylation of p65(P-p65) by several kinase leads to optimal NF-κB activation. There is growing evidence that NF-κB is essential for promoting inflammation-associated cancer, including CRC, by enhancing cell proliferation and angiogenesis, inhibiting apoptosis, and promoting cell invasion and metastasis [37, 38]. To elucidate the mechanisms of CORT promoting growth in AOM/DSS-induced CRC, we detected the expression of p65 and P-p65 in the colorectal neoplasms, including pathological type adenoma with low grade dysplasia, adenoma with high grade dysplasia and ACA, in VT and CT mice as well as normal colorectal epithelia with IHC analysis. The results showed that p65 and P-p65 expressed in both epithelium cells and stromal cells of neoplasms, but rarely in normal colorectal epithelia (Fig. 5a and b). More P-p65 was observed in the nuclei than cytoplasm. The expression of p65 and P-p65 in the colorectal cells of the CT mice significantly increased by 94.8 and 52.2% respectively compared with that of the VT ones (Fig. 5c). When activated NF-κB translocates to the nucleus, it can regulate the expression of multiple target genes, including COX-2. It is widely accepted that the deregulation of the COX-2 signalling pathway took a vital effect in the progression of CRC . Therefore, we investigated the expression of COX-2 by IHC analysis. The result showed that COX-2 mainly expressed in stromal cells, which mainly may be lymphocyte featured as round shape and fibroblast featured as fusiformis shape, of colorectal neoplasms, which were consistent with previous reports . Administration of CORT also resulted in increased expression of COX-2 in stromal cells of the neoplasms compared with those of the VT mice (Fig. 5d).
CORT inhibit the inflammation of neoplasms in AOM/DSS-treated mice
In this study we used a mouse model of colorectal carcinogenesis induced by AOM/DSS. DSS strongly induces inflammation in the colon, thereby enhancing the colon carcinogenesis in mice . While GC has an anti-inflammatory effect, therefore, we histologically evaluated inflammation in the stromal tissue of neoplasms (Fig. 6a) of both treatment mice at the end of the experiment. The inflammation scores (including ulceration, reepithelialization, infiltration of inflammatory cells and transmural inflammation) were evaluated using a semi-quantitative scoring system by two pathologists. As shown in Fig. 6b, the inflammation score of the CT mice was significantly lower than that of the VT ones (P = 0.0288), indicating that CORT treatment alleviates inflammation in the colon of AOM/DSS induced model mice.
GCs are main stress hormones and commonly prescribed in clinical practice. Although it is well known that they control a variety of physiological and cellular processes, such as immune response, metabolism, cell proliferation, cell apoptosis and cell survival , the effect of GCs on the development and progression of CRC is unclear. Therefore, in this study we examined the association between CORT at stress level and development of CRC with an AOM/DSS-induced mice model. We showed that the plasma levels of CORT in model mice were significantly higher than that of control mice, which may be due to tumor-related stress caused by AOM/DSS. CORT feeding in drinking water after the third cycle of DSS treatment further elevated the plasma levels of CORT. Increased CORT not only significantly enhanced the neoplasms burden (number and size), but also increased incidence of adenoma with high grade dysplasia and ACA in pathological type. Furthermore, CORT obviously enhanced the expression of two proliferation marker, Ki-67 and PCNA. These results indicated that CORT promoted the growth and development of colorectal adenoma and carcinoma in an induced mice CRC model by AOM/DSS spontaneously.
It is well known that as a transcription factors, activated NF-κB migrates into the nucleus to regulate the expression of multiple target genes involved in the development and progression of cancer . In CRC, NF-κB has a key role in cancer-related processes, including enhancing cell proliferation and angiogenesis, inhibiting apoptosis and promoting cell invasion and metastasis. Although it is known that GR exerts anti-inflammatory action in part by antagonizing NF-κB, there is also report that stress-related pathophysiological concentrations of GCs increase DNA binding activity of NF-κB (p65 and p50) and production of proinflammatory cytokines, such as IL-6, therefore promoting growth of some type of cancer cells [41,42,43]. In order to elucidate the mechanism of the above finding, we detected the expression of NF-κB p65 and its active form P-p65, and found that CORT significantly increased NF-κB expression, including the activated form, in the colorectal neoplasms. Moreover, CORT also increased the expression of COX-2, a target gene of NF-κB, in stromal cells of colorectal neoplasms. COX enzymes produce a number of substances, including prostaglandins, which function as major effectors of cancer initiation and progression . Previous study reported that increased COX-2 expression in the tumor environment is associated with poor prognosis in CRC patients . So we suggested that NF-κB-COX-2 pathway may be contributed to growth and development of CRC.
In this study we used a mouse model of colorectal carcinogenesis induced by AOM/DSS. DSS can strongly induce inflammation in the colon, thereby enhancing the colon carcinogenesis in mice . While GC actions typically are described as anti-inflammatory effect, therefore we histologically evaluated the inflammation of neoplasms in the colorectum of mouse. The result showed that the inflammation score of neoplasms in CORT-treated mice were decreased as compared with those of vehicle-treated mice. Why CORT inhibits inflammation but promotes the growth and development of CRC is not known yet. The reason may be that the effect of GC on tumor in vivo is very complex. Besides effects of immunosuppression and anti-inflammation, GC also affects tumor micro-environment and biology of tumor cell. Recently other and our studies demonstrated that GC can directly promote tumor cell survival, proliferation and metastasis by regulating gene expression and activating multiple trans-membrane signalling pathways, such as PI-3 K-AKT pathway [15, 18], TGFβ pathway , NF-κB-IL-6 pathway and JNK/AP-1 pathway . Whereas, these effects of GC are not related to inflammation. Another reason may be due to duration of COTR treatment. A significant body of evidence indicates that enhancing inflammation especially in the early stage of colitis promoted colonic tumorigenesis in AOM/DSS-induced mice . Whereas in this study we treated mice with CORT at the late stage (a week after the last cycle of DSS treatment). Perhaps in the late stage the promoting effect of GCs on tumor is more obvious than the effect of inflammation on tumor. The second question is why CORT activates NF-κB and up-regulates the expression of COX-2, but decreases the inflammation score. Although NF-κB and COX-2 are important inflammatory factors, researches in the past years have unveiled that GCs/GR play anti-inflammatory role through complex mechanisms , including inhibiting activities of various transcription factors, such as AP-1, cAMP response element-binding protein (CREB) besides NF-κB, inducing several anti-inflammatory protein, such as annexin 1 and MAP kinase phosphatase 1 (MKP1 or DUSP1), also inducing apoptosis of inflammatory cells. So we suggested that anti-inflammatory effect of CORT in our study may through other anti-inflammatory mechanism than NF-κB -COX-2 pathway, which may have a role in promoting development of AOM/DSS induced colorectal carcinoma. GC actions in vivo are more complex than previously anticipated. It is unclear how CORT promotes the development of CRC in this mice model now. Further studies need to be done to clarify the mechanism of GC effect on CRC.
In conclusion, the present findings show that CORT at stress level dramatically promotes the growth and development of AOM/DSS-induced colorectal adenoma and carcinoma in mice for the first time. The increased expression of NF-κB and its target COX-2 may be involved in CORT effect of promoting development of CRC. These new data provide a potential explanation that chronic stress may exert an important impact on CRC progression by the increasing of GCs level, and remind us to pay attention to the disadvantage of GCs for CRC patients.
Dextran sodium sulphate
Hematoxylin and eosin
Phosphate buffer solution
Proliferating cell nuclear antigen
Neeman E, Ben-Eliyahu S. Surgery and stress promote cancer metastasis: new outlooks on perioperative mediating mechanisms and immune involvement. Brain Behav Immun. 2013;30(Suppl):32–40.
Moreno-Smith M, Lutgendorf SK, Sood AK. Impact of stress on cancer metastasis. Future Oncol. 2010;6(12):1863–81.
Gundisch S, Boeckeler E, Behrends U, Amtmann E, Ehrhardt H, Jeremias I. Glucocorticoids augment survival and proliferation of tumor cells. Anticancer Res. 2012;32(10):4251–61.
Volden PA, Conzen SD. The influence of glucocorticoid signaling on tumor progression. Brain Behav Immun. 2013;30(Suppl):26–31.
Reiche EM, Nunes SO, Morimoto HK. Stress, depression, the immune system, and cancer. Lancet Oncol. 2004;5(10):617–25.
Powell ND, Tarr AJ, Sheridan JF. Psychosocial stress and inflammation in cancer. Brain Behav Immun. 2013;30(Suppl):41–7.
Chu CC, Hsing CH, Shieh JP, Chien CC, Ho CM, Wang JJ. The cellular mechanisms of the antiemetic action of dexamethasone and related glucocorticoids against vomiting. Eur J Pharmacol. 2014;722:48–54.
Kadmiel M, Cidlowski JA. Glucocorticoid receptor signaling in health and disease. Trends Pharmacol Sci. 2013;34(9):518–30.
Petta I, Dejager L, Ballegeer M, Lievens S, Tavernier J, De Bosscher K, et al. The Interactome of the glucocorticoid receptor and its influence on the actions of glucocorticoids in combatting inflammatory and infectious diseases. Microbiol Mol Biol Rev. 2016;80(2):495–522.
Chen YX, Li ZB, Diao F, Cao DM, Fu CC, Lu J. Up-regulation of RhoB by glucocorticoids and its effects on the cell proliferation and NF-kappaB transcriptional activity. J Steroid Biochem Mol Biol. 2006;101(4–5):179–87.
Li Z, Chen Y, Cao D, Wang Y, Chen G, Zhang S, et al. Glucocorticoid up-regulates transforming growth factor-beta (TGF-beta) type II receptor and enhances TGF-beta signaling in human prostate cancer PC-3 cells. Endocrinology. 2006;147(11):5259–67.
Kluza E, Heisen M, Schmid S, van der Schaft DWJ, Schiffelers RM, Storm G, et al. Multi-parametric assessment of the anti-angiogenic effects of liposomal glucocorticoids. Angiogenesis. 2011;14(2):143–53.
Deshantri AK, Kooijmans SA, Kuijpers SA, Coimbra M, Hoeppener A, Storm G, et al. Liposomal prednisolone inhibits tumor growth in a spontaneous mouse mammary carcinoma model. J Control Release. 2016;243:243–9.
Chen YX, Wang Y, Fu CC, Diao F, Song LN, Li ZB, et al. Dexamethasone enhances cell resistance to chemotherapy by increasing adhesion to extracellular matrix in human ovarian cancer cells. Endocr Relat Cancer. 2010;17(1):39–50.
Yin L, Fang F, Song X, Wang Y, Huang G, Su J, et al. The pro-adhesive and pro-survival effects of glucocorticoid in human ovarian cancer cells. J Mol Endocrinol. 2016;57(1):61–72.
Zhang C, Wenger T, Mattern J, Ilea S, Frey C, Gutwein P, et al. Clinical and mechanistic aspects of glucocorticoid-induced chemotherapy resistance in the majority of solid tumors. Cancer Biol Ther. 2007;6(2):278–87.
Liu L, Aleksandrowicz E, Schonsiegel F, Groner D, Bauer N, Nwaeburu CC, et al. Dexamethasone mediates pancreatic cancer progression by glucocorticoid receptor, TGFβ and JNK/AP-1. Cell Death Dis. 2017;8(10):e3064.
Huang GX, Wang Y, Su J, Zhou P, Li B, Yin LJ, et al. Up-regulation of rho-associated kinase 1/2 by glucocorticoids promotes migration, invasion and metastasis of melanoma. Cancer Lett. 2017;410:1–11.
Sorensen HT, Mellemkjaer L, Nielsen GL, Baron JA, Olsen JH, Karagas MR. Skin cancers and non-hodgkin lymphoma among users of systemic glucocorticoids: a population-based cohort study. J Natl Cancer Inst. 2004;96(9):709–11.
Lasry A, Zinger A, Ben-Neriah Y. Inflammatory networks underlying colorectal cancer. Nat Immunol. 2016;17(3):230–40.
Wang H, Li M, Rinehart JJ, Zhang R. Pretreatment with dexamethasone increases antitumor activity of carboplatin and gemcitabine in mice bearing human cancer xenografts: in vivo activity, pharmacokinetics, and clinical implications for cancer chemotherapy. Clin Cancer Res. 2004;10(5):1633–44.
Keith BD. Systematic review of the clinical effect of glucocorticoids on nonhematologic malignancy. BMC Cancer. 2008;8:84.
Zhang C, Kolb A, Mattern J, Gassler N, Wenger T, Herzer K, et al. Dexamethasone desensitizes hepatocellular and colorectal tumours toward cytotoxic therapy. Cancer Lett. 2006;242(1):104–11.
Kim JH, Hwang YJ, Han SH, Lee YE, Kim S, Kim YJ, et al. Dexamethasone inhibits hypoxia-induced epithelial-mesenchymal transition in colon cancer. World J Gastroenterol. 2015;21(34):9887–99.
Sidler D, Renzulli P, Schnoz C, Berger B, Schneider-Jakob S, Fluck C, et al. Colon cancer cells produce immunoregulatory glucocorticoids. Oncoimmunology. 2012;1(4):529–30.
Schiffelers RM, Metselaar JM, Fens MH, Janssen AP, Molema G, Storm G. Liposome-encapsulated prednisolone phosphate inhibits growth of established tumors in mice. Neoplasia. 2005;7(2):118–27.
Thaker AI, Shaker A, Rao MS, Ciorba MA. Modeling colitis-associated cancer with azoxymethane (AOM) and dextran sulfate sodium (DSS). J Vis Exp. 2012. https://doi.org/10.3791/4100.
Im SA, Kim JW, Kim HS, Park CS, Shin E, Do SG, et al. Prevention of azoxymethane/dextran sodium sulfate-induced mouse colon carcinogenesis by processed Aloe vera gel. Int Immunopharmacol. 2016;40:428–35.
Tanaka T, Kohno H, Suzuki R, Yamada Y, Sugie S, Mori H. A novel inflammation-related mouse colon carcinogenesis model induced by azoxymethane and dextran sodium sulfate. Cancer Sci. 2003;94(11):965–73.
Neufert C, Becker C, Neurath MF. An inducible mouse model of colon carcinogenesis for the analysis of sporadic and inflammation-driven tumor progression. Nat Protoc. 2007;2(8):1998–2004.
Lee RS, Tamashiro KLK, Yang X, Purcell RH, Harvey A, Willour VL, et al. Chronic corticosterone exposure increases expression and decreases deoxyribonucleic acid methylation of Fkbp5 in mice. Endocrinology. 2010;151(9):4332–43.
Cassano AE, White JR, Penraat KA, Wilson CD, Rasmussen S, Karatsoreos IN. Anatomic, hematologic, and biochemical features of C57BL/6NCrl mice maintained on chronic oral corticosterone. Comp Med. 2012;62(5):348–60.
Auvinen HE, Coomans CP, Boon MR, Romijn JA, Biermasz NR, Meijer OC, et al. Glucocorticoid excess induces long-lasting changes in body composition in male C57Bl/6J mice only with high-fat diet. Physiol Rep. 2013;1(5):e00103.
Cui X, Jin Y, Poudyal D, Chumanevich AA, Davis T, Windust A, et al. Mechanistic insight into the ability of American ginseng to suppress colon cancer associated with colitis. Carcinogenesis. 2010;31(10):1734–41.
Washington MK, Powell AE, Sullivan R, Sundberg JP, Wright N, Coffey RJ, et al. Pathology of rodent models of intestinal cancer: progress report and recommendations. Gastroenterology. 2013;144(4):705–17.
Jia LG, Bamias G, Arseneau KO, Burkly LC, Wang EC, Gruszka D, et al. A novel role for TL1A/DR3 in protection against intestinal injury and infection. J Immunol. 2016;197(1):377–86.
Hoesel B, Schmid JA. The complexity of NF-kappaB signaling in inflammation and cancer. Mol Cancer. 2013;12:86.
Patel M, Horgan PG, McMillan DC, Edwards J. NF-kappaB pathways in the development and progression of colorectal cancer. Transl Res. 2018. https://doi.org/10.1016/j.trsl.2018.02.002.
Jensen TSR, Mahmood B, Damm MB, Backe MB, Dahllöf MS, Poulsen SS, et al. Combined activity of COX-1 and COX-2 is increased in non-neoplastic colonic mucosa from colorectal neoplasia patients. BMC Gastroenterol. 2018;18:31.
TO I, Herschman HR. Tumor formation in a mouse model of colitis-associated colon cancer does not require COX-1 or COX-2 expression. Carcinogenesis. 2010;31(4):729.
Herr I, Pfitzenmaier J. Glucocorticoid use in prostate cancer and other solid tumours: implications for effectiveness of cytotoxic treatment and metastases. Lancet Oncol. 2006;7(5):425–30.
Bernabe DG, Tamae AC, Biasoli ER, Oliveira SH. Stress hormones increase cell proliferation and regulates interleukin-6 secretion in human oral squamous cell carcinoma cells. Brain Behav Immun. 2011;25(3):574–83.
Valles SL, Benlloch M, Rodriguez ML, Mena S, Pellicer JA, Asensi M, et al. Stress hormones promote growth of B16-F10 melanoma metastases: an interleukin 6- and glutathione-dependent mechanism. J Transl Med. 2013;11:72.
Lin PC, Lin YJ, Lee CT, Liu HS, Lee JC. Cyclooxygenase-2 expression in the tumor environment is associated with poor prognosis in colorectal cancer patients. Oncol Lett. 2013;6(3):733–9.
Shukla PK, Chaudhry KK, Mir H, Gangwar R, Yadav N, Manda B, et al. Chronic ethanol feeding promotes azoxymethane and dextran sulfate sodium-induced colonic tumorigenesis potentially by enhancing mucosal inflammation. BMC Cancer. 2016;16:189.
Cruz-Topete D, Cidlowski JA. One hormone, two actions: anti- and pro-inflammatory effects of glucocorticoids. Neuroimmunomodulation. 2015;22(1–2):20–32.
The authors thank for the Experiment Animal Center of Second Military Medical University for providing room with SPF condition.
This study was supported by grant from National Natural Science Foundation of China (No. 81472690 and No. 91029722). The funder had no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript.
Availability of data and materials
The datasets used and/or analyzed during the current study available from the corresponding author on reasonable request.
All animal experiments were approved by the Animal Care and Use Committee of Second Military Medical University (Shanghai, China) and performed in compliance with the University’s Guidelines for the Care and Use of Laboratory Animals (reference number: 20131015001).
Consent for publication
The authors declare that they have no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Li, B., Wang, Y., Yin, L. et al. Glucocorticoids promote the development of azoxymethane and dextran sulfate sodium-induced colorectal carcinoma in mice. BMC Cancer 19, 94 (2019). https://doi.org/10.1186/s12885-019-5299-8
- Azoxymethane/dextran sodium sulfate
- Colorectal carcinoma
- Tumor development
- Nuclear factor-κB