Cytokines, breast cancer stem cells (BCSCs) and chemoresistance

Interleukin-6 (IL-6) was initially identified as B cell stimulating factor 2, enhancing immunoglobulin synthesis through activating B cells and was a prototypical cytokine with pleiotropic and redundant activities of a wide range in immune regulation, hematopoiesis, inflammation and oncogenesis. It helps the host to defend against infection and tissue damage as an inflammatory and immunomodulatory cytokine. However, the persistent IL-6 synthesis leads to the development of various diseases, including cancers [26].

The IL-6 signaling is aberrantly hyper activated in many types of cancer and is generally associated with a poor clinical prognosis [27]. IL-6 was the most highly expressed cytokine in the human colorectal cancer-derived mesenchymal stem cells conditioned medium, and promoted the progression of colorectal cancer cells through IL-6/JAK2/STAT3 signaling, which activated PI3K/AKT signaling. Besides, anti-IL-6 antibody abolished the migration and invasion of colon cancer cells induced by IL-6-activated pathway [28]. Human liver cancer tissues contained high ratio of Tim-3-expressing hepatocytes and HBV involved in Tim-3 upregulation in malignant hepatocytes. The hepatocyte-Tim-3 receptor activates NF-kappa B phosphorylation, which in turn stimulates IL-6 secretion and STAT3 phosphorylation, resulting in tumor growth both in vitro and in vivo [29]. In head and neck cancer, IL-6 can induce its expression as upstream of OPN, and OPN promotes the growth, migration and invasion of cancer cells through activating integrin αvβ3-NF-kappa B axis [30].

IL-6 also participated in breast cancer chemoresistance. Local IL-6 paracrine loop act as exogenous IL-6 rich niche for chemo-sensitive breast cancer cells, leading to de novo acquired drug resistance [31]. As one of the principal oncogenic molecules, IL-6 treatment could induce upregulation of HIF-1 alpha via the activation of STAT3, which consequently contributed to its effect against chemotherapeutic drug-induced cytotoxicity and cell apoptosis [32]. In the established MDA-MB-231 metastatic breast cancer cell line, knockdown of endogenous VCAM-1 expression reduced cell proliferation and inhibited IL-6 mediated cell migration, and increased chemosensitivity [33]. Treatment with a genotoxic drug combination (5-fluorouracil, doxorubicin, and cyclophosphamide) activated an NF-kappaB-IL6-dependent inflammatory signaling that imparted stemness to nonstem cancer cells, induced multidrug resistance in breast cancer [34]. The role of JAK-STAT3 in mediating the promotion of IL-6 on drug resistance has been confirmed [26]. IL-6 mainly promotes the expression of multiple genes through STAT3, thus regulating breast cancer drug resistance (Fig. 1a).

Interleukin-8 (IL-8), also known as chemokine CXCL8, is a cytokine secreted by a wide range of cell populations. IL-8 has cellular chemotaxis to neutrophils to regulate the inflammatory response through combining with chemokine receptor interleukin-8 receptor alpha (IL8RA, also called CXCR1) and interleukin-8 receptor beta (IL8RB/CXCR2), and has multiple cell targets in addition to neutrophils. IL-8 involves in various human diseases, such as atherosclerosis, cancer, inflammatory bowel disease, infection, sepsis, chronic obstructive pulmonary disease, psoriasis and rheumatoid arthritis [35].

The chemokine IL-8 is overexpressed in multiple cancer types, including triple-negative breast cancer (TNBC), where it promotes the acquisition of mesenchymal features, stemness, and chemoresistance. The current research explores the utility of a clinical-stage monoclonal antibody that neutralizes IL-8 as a potential therapeutic option for TNBC [36]. IL-8 showed increased expressions in paclitaxel-treated advanced breast cancer and this over-production effect was inhibited in TLR4-silenced cells. The acquired TLR4-mediated paclitaxel resistance in advanced breast cancer is explained partly by the paracrine effect of IL-8 release [37]. Cytokines produced by breast cancer cells after chemotherapy withdrawal activate both Wnt/beta-catenin and NF-kappa-B pathways, which in turn further promote breast cancer cells to produce and secrete cytokines, forming an autocrine inflammatory forward-feedback loop to facilitate the enrichment of drug-resistant breast cancer cells [38]. Moreover, such an autocrine forward-feedback loop can also be diminished by IL-8 neutralizing antibody or blockade of IL-8 receptors CXCR1/2 with reparixin, and, in a human xenograft model, administration of reparixin after chemotherapy withdrawal effectively attenuates tumor masses [38]. Breast cancer patients treated with chemotherapeutic drugs exhibited poor survival rate and shorter disease-free survival time if their tumor samples expressed high level of IL-8, or its receptor, CXCR1, CXCR2 [38].

The downstream signals activated by IL-8-CXCR1/2 are context-specific, and the effector proteins that mediate IL-8 signals are also pleiotropic, and these effectors may also affect each other. The activation of GPCR (CXCR1 and CXCR2) activated by IL-8 promotes the activation of a variety of downstream pathways, including but may not be limited to PLC-PKC, PI3K-AKT, Rho-GTPase family, FAK/Src of non-receptor tyrosine kinases and MAPK cascade signals (Fig. 1b), which ultimately affect the progression of cancer, angiogenesis, metastasis, and cancer stem cell activation [39]. Although Src and NF-κB have been found to be drug-resistant causes in prostate and colon cancer respectively, the specific mechanism in chemoresistance and critical downstream pathways of IL-8 signal in breast cancer are still not well described, and more research is needed to clarify this point.

In addition to the essential roles in germ-layer specification and patterning during embryonic development, transforming growth factor-β (TGF-β) signaling is also involved in human diseases including fibrosis, cardiovascular, cancer, reproductive or wound-healing disorders through control of cellular functions in proliferation, adhesion, invasion, differentiation, apoptosis, and cellular microenvironment [40, 41].

Through analyzing RNA expression in matched pairs of primary breast cancer biopsies before and after chemotherapy, researchers found that biopsies after chemotherapy displayed increased RNA transcripts of TGF-β signaling. And also, in TNBC cell lines and mouse xenografts, the chemotherapeutic drug paclitaxel upregulated autocrine TGF-β signaling [42]. In addition, treatment of TNBC xenografts with LY2157299, the TGF-β type I receptor kinase inhibitor, prevented relapse of tumors after paclitaxel treatment, suggesting that chemotherapy-induced TGF-β signaling enhances tumor recurrence and that TGF-β pathway inhibitors prevent the development of drug-resistant breast cancer cells [42]. Vinorelbine is one of the most active cytotoxic agents in breast cancer, especially metastatic breast cancer and bioinformatics analysis indicated that TGF-β signaling pathway may associate with drug resistance of breast cancer cells to vinorelbine [43].

The strong implication of TGF-β in mammary epithelial-to-mesenchymal transition (EMT) promotion is becoming increasingly accepted. PARP3 was upregulated in the course of TGF-β-induced EMT and PARP3 responded to TGF-β-induced signaling to enhance the TG2-Snail-E-cadherin axis during EMT, which demonstrates the critical role of PARP3 in mediating the promotion of TGF-β to EMT [44]. The phenotype switch is now indicated as an important contributor to the acquisition of drug resistance, a clinically relevant issue involved in the preservation of high mortality rates among breast cancer cases [45]. As the regulators of TGF-β, numerous miRNAs are involved in TGF-β signaling [46]. They can intervene in the progression of drug resistance in breast cancer and function as enhancers or inhibitors for chemotherapeutic agents. On the contrary, TGF-β can also regulate the micro-RNA signaling to affect the drug resistance of breast cancer (Fig. 2). TGF-β can induce miR-21 expression, which targeted the 3’ untranslated region of MSH2 mRNA and downregulated its expression. Furthermore, by downregulating MSH2, TGF-β contributed to resistance to DNA-damaging chemotherapy agents (cisplatin, methyl methanesulfonate, and doxorubicin) in breast cancer cells [47].

In addition to IL-6, IL-8 and TGF-β, cytokines which can directly determine the effect of chemotherapy for breast cancer, also includes other factors such as M-CSF, TNFα, IL-1β and so on [18]. They lead to breast cancer resistance to various chemotherapeutic agents including paclitaxel, cisplatin, anthracycline and doxorubicin through differential signaling pathways.

These cytokines, closely related to chemotherapeutic resistance, have also attracted the interest of pharmacologists and clinicians, who are trying to develop monoclonal antibodies or small molecular inhibitors targeting these factors to improve the effectiveness of chemotherapies. Therapy through targeting IL-6 signals has been widely applied in inflammatory diseases such as Rheumatoid arthritis [48]. Although no dose-related or cumulative toxicity was apparent in the phase I, open-label study of Siltuximab, an anti-IL-6 monoclonal antibody, in patients of B-cell Non-Hodgkin’s Lymphoma or multiple myeloma (NCT00412321), no responses were seen in patients with relapsed or refractory multiple myeloma treated with single-agent Siltuximab (Table 1). And combining Siltuximab with the bortezomib–melphalan–prednisone (VMP) regimen did not improve complete response (CR), progression free survival, or overall survival but gained very good partial response in multiple myeloma (NCT00911859). In addition, no objective responses were seen in the phase 1/2, multiple-dose, dose-escalation study of siltuximab, suggesting that IL-6 inhibition alone is insufficient in treating advanced or refractory solid tumors including ovarian, pancreatic, colorectal, head & neck cancer and non-small-cell lung carcinoma (NSCLC) (Table 1).

CXCR1 is thought to be a receptor selectively expressed in breast cancer stem cells (BCSCs). Reparixin is an allosteric inhibitor of IL-8 (CXCL8) receptor CXCR1/2 has the activity against BCSCs in xenografts of breast cancer [53]. CXCR1 is thought to be a receptor selectively expressed in breast cancer stem cells. Reparixin is an allosteric inhibitor of IL-8 (CXCL8) receptor CXCR1/2 and has the activity against BCSCs in xenografts of breast cancer. It was confirmed that reparixin monotherapy or paclitaxel plus reparixin were appeared to be safe and tolerable in early or metastatic breast cancer (MBC), respectively (NCT01861054, NCT02001974) (Table 1). However, further studies in the clinical trial to observe the action of reparixin on cancer therapy is still needed.

Small molecule inhibitor, LY215799 monohydrate also known as galunisertib, blocks TGF-beta signaling through inhibiting TGFβ receptor I and reduce tumor progression in preclinical models [55]. Besides, Galunisertib has acceptable tolerability and safety in advanced cancer patients (NCT01722825). In advanced hepatocellular carcinoma (HCC), patients treated with Galunisertib showed improvement in overall survival in a phase 2 study (NCT01246986). However, the mono-antibody of ALK1 [a member of transforming growth factor-beta (TGF-β) receptor I], PF-03446962, had no activities as a single drug in refractory urothelial cancer (NCT01620970). The combination of galunisertib and gemcitabine showed improvement of OS and PFS in patients with unresectable pancreatic cancer (PC) compared to gemcitabine + placebo (NCT01373164). Unfortunately, in patients with recurrent glioblastoma, Galunisertib plus lomustine failed to demonstrate improved OS relative to placebo plus lomustine (NCT01582269) (Table 1). In general, it is still very promising to improve the therapeutic effect of cancers via blockade of TGF-β signaling, which requires more clinical studies to confirm.

Tumor-associated macrophages (TAM) are the prominent components of TME in breast cancers. Macrophages exhibit a high plasticity in response to various external signals and participate in innate and adoptive immune responses to control numerous factors of TME [74]. Depending on the microenvironmental signal present, macrophages undergo different types of activation, including the “classic” pro-inflammatory phenotype (also called M1) and the “alternative” anti-inflammatory phenotype (also called M2) or even in the transitional state between these two kinds of macrophages. TAMs closely resemble the M2-polarized. Clinicopathological studies have suggested that TAM accumulation in tumors correlates with a poor clinical outcome [74]. However, the characteristics of tumor-infiltrated macrophages are complex. TAMs show pleiotropic effects on tumor behavior due to be stimulated by differential cytokines. Some chemokines may increase the infiltration of TAM and form suitable conditions for tumor outgrowth. Once infiltrated, macrophages may also be regulated by cytokines, changing the gene expression, releasing factors that are beneficial to the progression of tumor and the factors associated with immunosuppression. Finally, multiple behaviors of macrophages affected by cytokines can remodel the tumor microenvironment and promote breast cancer chemotherapy resistance.

Breast cancer-associated macrophages express high levels of insulin-like growth factors 1 and 2 (IGFs) and are the main source of IGFs within both primary and metastatic tumors [73]. In total, 75% of breast cancer patients show activation of insulin/IGF-1 receptor signaling and this correlates with increased macrophage infiltration and advanced tumor stage. In addition, blockade of IGF in combination with paclitaxel showed a significant increase in chemosensitivity of tumor compared to paclitaxel monotherapy [73]. TAMs and its supernatants significantly prevent breast tumor cells from apoptosis caused by paclitaxel and the high level of IL-10 secreted by TAMs was responsible for drug resistance of breast cancer [75]. The possible TAMs-modulated drug resistance mechanism involved may be associated with elevation of bcl-2 gene expression and up-regulation of STAT3 signaling in tumor cells, forming IL-10/STAT3/bcl-2 signaling axis accounting for chemoresistance of breast cancer [75].

The presence of cancer-associated fibroblasts (CAFs) was found in almost all solid tumors. However, their abundance varies widely among different types of cancer. For example, breast, prostate and pancreatic cancer contain more CAFs, while CAFs in brain, kidney and ovarian tumors is rare. CAFs are markedly different from tumorigenic malignant cells [76]. They have undergone epithelial-to-mesenchymal transition and show fibroblast-like morphology. In addition, there is a great difference between cancer cells and CAF cells that the karyotype is relatively stable, and there are few genetic alterations in CAFs. They are defined as all the fibroblastic, nonneoplastic, nonvascular, nonepithelial, and noninflammatory cells found in a tumor [77].

CAFs may lead to the resistance of cancer cells to anti-tumor drugs by means of soluble factors. Chemokine- or cytokine-signaling pathway perhaps drive CAF to remodel the extracellular matrix (ECM) in the tumor microenvironment and the CAF-remodeled ECM can provide favorable soil for the change of EMT characteristics of tumor cells, conferring chemotherapeutic resistance [78, 79]. The EMT process usually promotes chemoresistance by inducing cell cycle arrest or altering the expression of transporters enabling chemotherapeutic drugs uptake of tumor cells [80‐82]. Stimuli from proinflammatory cytokine IL-6 expressed by tumor cells, is sufficient to induce the expression of Twist1 in normal fibroblasts and transdifferentiate them into CAFs through the activation of STAT3 pathway [83]. In the xenograft tumor model of breast cancer, ectopic expression of IL-6 can significantly increase the infiltration of Twist1-positive CAFs, and Twist1 is necessary and sufficient for the trans-differentiation formation of CAFs. In addition, CXCL12 is the target gene of Twist1 transcriptional regulation as the downstream signaling [83]. These studies elucidate that cytokine (IL-6) can promote the remodeling of tumor microenvironment by promoting CAFs formation, infiltration and promoting downstream cytokines expression.

The collagen type I secreted by CAFs was found to reduce the uptake of chemotherapeutic drugs in the tumor, and therefore plays a vital role in regulating the chemosensitivity of cancer to multiple forms of chemotherapy [84]. Accordingly, targeting CAFs can increase the drug absorption inside the tumor, inhibit growth and metastasis of primary tumor cells, and the growth of breast cancer that are resistant to multiple drugs in mice [84]. Taken together, cytokines affect the formation and infiltration of CAFs, and CAFs can reshape the characteristics of ECM in microenvironment and subsequently influence the drug resistance of breast cancer cells. On the other hand, CAFs can secrete specific cytokines to further reprogram the microenvironment.