IL6 plays a significant pro-inflammatory role under many physiological and pathological conditions in multiple cell types (88). Although many different cell types secrete IL6, macrophages are one of the major sources. IL-6 exerts its effects after binding to ligand-binding IL-6 receptor (IL6R) α chain (gp80, CD126) and the signal-transducing component gp130 (CD130) in an autocrine and paracrine manner. IL6 is a double-edged sword in the tumor microenvironment. Several studies demonstrated the role of IL6-mediated pro-proliferative, anti-apoptotic, angiogenic, metastatic, and immunosuppressive responses in tumor development and progression. While other studies demonstrated the role of IL6 in promoting anti-tumor immunity through the stimulation of proliferation, survival and trafficking of T cells to lymph nodes and tumor sites, where T cells effectively shift tumor-suppressive state to responsive state to inhibit tumor growth and progression (89, 90). An increased level of IL6 correlates with the poor prognosis and survival of lung cancer patients (54, 60). TAM-derived IL6 plays a role in progression, invasion, angiogenesis, EMT, immune cell infiltration, and cancer stem cell (CSC) development and maintenance, through multiple unexplored molecular mechanisms (91–93). The activation of signal transducer and activator of transcription (STAT) 3 by TAM-derived IL6 in the lung TME considered as the prime mechanism responsible for the development of mouse lung tumor model and crosstalk with small cell lung cancer (SCLC) cell lines (94, 95). Phosphatidylinositol-4,5-Bisphosphate 3-Kinase/AKT Serine/Threonine Kinase 1 (PI3K/AKT) signaling is another pathway engaged by TAM-derived IL6 to influence growth of lung cancer cell line, A549 (96). TAM-derived IL6-mediated STAT3 signaling pathway also found to increase the proliferation of human cancer stem cells (97). In different phases of lung cancer development and its therapeutic management, IL6 drives multiple molecular mechanisms responsible for the epithelial-mesenchymal transition (EMT) (98, 99) and therapy resistance, such as infiltration of pro-tumor macrophages after irradiation through the upregulation of CCL2/CCL5 in vitro human and in vivo mouse lung tumor models (100). Therefore, the blockade of IL6 reprograms the TME to restrict lung cancer development and progression in experimental lung tumorigenesis models (101). Many different approaches are used in various malignancies and other diseases to target IL-6 signaling pathways. For example–small molecules, blocking peptides, and antibodies against IL6, IL-6R, IL6–sIL6R complex, janus kinase (JAK) phosphorylation, and STAT3 activation (102, 103). The upregulation of systemic level of IL6 upon treatment of anti–PD1 antibody nivolumab leads to poor clinical outcome because inhibition of PD1–PDL1 promotes production of IL6 by PD1+ TAMs. Depletion of macrophages in vivo model of melanoma reduces the systemic level of IL6 and upregulates anti-tumor Th1 response, suggesting that the narrow therapeutic window of PD1–PDL1 blockade can be overcome by inhibition of IL6 (104).

As the name suggests, TNFα initially found to induce necrosis and cytotoxicity in certain tumors (105). It is also known as a pyrogenic cytokine because of its ability to establish an inflammatory environment in response to pathogens (106). To exert a molecular action on the target cell, TNFα binds to one of the two receptors, TNF receptor superfamily member (TNFR1) (TNFRSF1A, p55TNFR1, p60, or CD120a) and TNFR2 (TNFRSF1B, p75TNFR, p80, or CD120b). According to the molecular context, TNFα exerts an opposite effect on tumor progression. In lung cancer, TNFα found to induce cell proliferation, apoptosis resistance, angiogenesis, invasion, and metastasis in various in vitro and in vivo lung tumor models (107). On the other hand, doxorubicin treatment-induced TNFα triggers apoptosis of TP53-deficient lung tumor cells via downregulation of cyclin dependent kinase inhibitor 1A (CDKN1A) (108). In the TME, crosstalk of TAMs with tumor cells and other tumor-associated cells via TNFα not only activates survival and proliferation pathways through the transcriptional activation of nuclear factor kappa B subunit 1 (NFKB1), fos proto-oncogene (FOS), and jun proto-oncogene (JUN) but also activates apoptotic pathways via TNFR1. Considering anti-tumor effects of TNFα, number of attempts were made to administer TNFα either systemically or locally in various cancer types. Although administration of TNFα significantly decreased the tumor growth, but many side effects were observed in the studies. In order to augment endogenous TNFα activity, Immunicon Inc. developed a single chain TNFα based affinity column to remove soluble TNF receptors from the blood (109). The pretreatment of low dose of TNFα prior to administration of chemotherapeutic agents such as Cisplatin, Paclitaxel, and Gemcitabine improved the efficacy of the agents in the experimental cancer model (110). On the hand recent studies showed that instead of augmenting effect of TNFα in tumor, TNFα blockade increases effect of immune checkpoint inhibitors (111, 112). Therefore, therapeutic approaches manipulating TNFα in cancer should be interpreted with great caution. The recent studies demonstrated that the higher number of tumor islets with infiltration of TNFα⁺ TAMs (cytotoxic M1 phenotype) confers a survival advantage in non-small-cell lung cancer (NSCLC) and other malignancies (14, 65). In TAMs-tumor cells in vitro co-culture model, tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) reprograms TAMs to M1-like phenotype by inducing expression of proinflammatory cytokines like IL1B, IL6, TNFα (113). TAMs-specific TNFα or its receptors induce apoptosis in vitro and in vivo tumor model by activating CD8⁺ T cells (114). Therefore, current immunotherapeutics need to be directed toward the induction of TNFα⁺ expression in TAMs, thereby reactivating anti-tumor immunity in the TME.

IL10 is an anti-inflammatory cytokine mainly produced by activated macrophages, B cells, and T cells (115). IL10 binds to the receptor IL10R. IL10R is a heterotetramer complex consisting of two IL10Rα and two IL10Rβ molecules (116). The main anti-inflammatory functions of IL10 are suppression of classical macrophage activation, suppression of the production of proinflammatory cytokines TNFα, IL1β, IL6, IL8, IL12, and granulocyte-macrophage colony-stimulating factor (GM-CSF) (51, 117), inhibition of antigen presentation by suppressing major histocompatibility complex (MHC) II expression in activated macrophages (118), and inhibition of IFNγ production by Th1 and natural killer (NK) cells (119). Tumor cells often secrete a high amount of IL10, and increased serum concentration of IL10 found to be associated with simultaneous immunostimulation and immunosuppression in different types of cancer (120). The prognostic significance of IL10 in serum or whole tissue homogenate is controversial because a study by De vita et al. suggested that serum IL10 level was a prognostic indicator of advanced NSCLC (66) while studies by Soria et al. demonstrated that patients lacking IL10 expression in early-stage NSCLC have a worse prognosis than those with IL10 expression (67). On the other hand, TAMs-derived IL10 level showed consistent prognostic significance in lung cancer patients (121, 122). TAMs-derived IL10 perform several tasks in lung cancer progression and development (123). Similar to IL6, crosstalk within different cells of the TME via TAMs-derived IL10 leads to the activation of STAT3 (124, 125). Additionally, TAM-derived IL10 promotes the stemness of lung cancer via JAK1/STAT1/NFKB/NOTCH1 signaling pathways in vivo tumorigenesis mouse models (126). IL10 also drives in vivo lung cancer growth and metastasis by upregulating the CCL2/C-C motif chemokine receptor 2 (CCR2) and C-X-C motif chemokine ligand (CXC3CL1)/C-X3-C motif chemokine receptor 1 (CX3CR1) axis in macrophage-tumor cell crosstalk (20). IL10 signaling pathway is a complex molecular network comprising a minimum of 37 molecules and 76 reactions to support cancer development (127). The blockade of IL10 signaling pathways in human diseases is under critical investigation. Various strategies, such as blocking peptides and monoclonal antibodies against IL10, receptor-blocking strategies for IL10R, and small molecule inhibitors targeting JAK/STAT3 signaling, are under clinical evaluation (128, 129).

Concerning the potential therapeutic intervention point in various human diseases, CCL2 is one of the most studied chemokines. CCL2 is a potent monocyte chemotactic factor from the C-C chemokine family. It mainly produced by monocyte/macrophages either constitutively or upon induction by other soluble factors and oxidative stress. CCL2 binds to its receptor CCR2 to mediate its effect through an autocrine or paracrine manner (130). Expression of CCL2, CCR2 or in combination with IL6 and IL10 correlates with a worse prognosis in lung cancer patients (61, 78, 79). In various cancers, the crosstalk of TAMs with tumor cells via the CCL2/CCR2 axis play multiple roles in cancer development, such as monocyte/macrophage recruitment at the tumor site (131), tumor progression, EMT, invasion, and metastasis (132). Experimental lung tumor models, in vitro TAMs-tumor cells, co-culture models, and human lung cancer biopsies demonstrated that CCL2/CCR2 signaling is one of the central signaling pathways involved in lung cancer growth and metastasis (20, 133, 134). In the in vivo metastasis lung tumor model and human lung cancer biopsies, infiltration of TAMs was found to be increased by NFKB1-CCL2 signaling via an elevation in neddylation pathway (135). In the flank and orthotopic lung tumor model, blockade of CCL2 reduces lung tumor growth not only by reprogramming TAMs to M1-like phenotype but also by activating CD8⁺ T cells (136). Deficiency of CCL2 in stromal cells like macrophages reduces infiltration of macrophages, angiogenesis, early tumor necrosis and lung metastasis in the 4T1 breast tumor model (137). Targeting of the CCL2/CCR2 axis in TAMs is an emerging immunotherapeutic tool in various human diseases. Therefore, therapeutic strategies blocking CCL2, CCR2, and CCL2/CCR2 complexes in TAMs are under extensive evaluation (138, 139).

To date, CX3CL1 is the only known chemokine from the CX3C family. CXCL1 has received particular attention in chemokine biology because it is found in two forms, either bound to the cell membrane or in a soluble form. Therefore, it acts as both an adhesion molecule and chemoattractant (140). It plays a role in the activation and migration of monocytes, NK cells, T cells, and mast cells at the site of action in various physiological and pathological conditions. It also promotes the binding of leukocytes and the adhesion and activation of target cells. CX3CL1 mediates its cellular effects by interacting with CX3CR1 (141). A recent study by Liu et al. demonstrated that high CX3CL1 mRNA expression served as a positive prognostic indicator in patients with lung adenocarcinoma (80). Another study by Su et al. demonstrated that the CXC3CL1 level showed survival effects in lung adenocarcinoma but not in squamous cell carcinoma (81). The expression of CX3CL1 was found to be increased in lung cancer with higher pathological grades and metastatic lymph nodes (142). CX3CL1-induced M2 macrophage polarization increases invasiveness of human endometrial stromal cells (ESCs) by upregulating expression of MMP9, tissue inhibitor of metalloproteinases (TIMP)-1, -2 and by activating P38MAPK and integrinβ1 signaling (143). In the co-culture of peripheral blood mononuclear cells (PBMCs) and pancreatic cancer cell lines, TRAIL/NFKB1/CX3CL1 dependant bi-directional crosstalk leads to therapy resistance (144). In the mouse mammary tumor model, activation of fibroblast growth factor receptor 1 (FGFR1) leads to migration and recruitment of macrophages via secretion of CX3CL1 (145). In in vitro, in vivo, and ex vivo models of lung cancer, TAM-tumor cell crosstalk via the CX3CL1/CX3CR1 axis found to be crucial in lung tumor cell growth, and metastasis, suggesting a potential axis for therapeutic intervention in lung cancer (20).

IL8/CXCL8 is a proinflammatory chemokine (from the CXC family) mainly secreted by macrophages. It exerts its effect by binding to CXCR1 and CXCR2, which are heterotrimeric G-protein-coupled receptors. These receptors are expressed not only by neutrophils but also by monocytes, endothelial cells, tumor cells, and tumor-associated stromal cells (146). Therefore, IL-8 is responsible for the migration and activation of all these cells (87). IL-8 plays multiple roles in lung cancer development (147–151). IL8 serves as a potential biomarker to predict tumor burden, treatment response, and patient survival in lung cancer (152–154). The expression of IL8 mRNA in the lung TME induced by infiltrating macrophages via the NFKB pathway significantly correlates with increased tumor angiogenesis and shorter median survival of lung cancer (155). IL8 is known to activate major oncogenic signaling pathways through autocrine and paracrine functions in the TME [e.g., PI3K, RAS/mitogen-activated protein kinase (MAPK), and JAK/STAT] (156). Therefore, the precise molecular role of TAM-derived IL8 in TAMs-tumor cell crosstalk requires further investigation. To block IL8 dependent responses, IL8 neutralizing antibodies (ABX-IL8 and HuMax-IL8), small molecule inhibitor of CX3CR1/CX3CR2 (Reparixin, JMS-17-2) are in the different phases of preclinical and clinical development (157, 158).

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.