IL-34 is a human protein that was discovered in 2008 by Lin and his colleagues (1). It is a hypothetical protein that may be accessed in a public database (C16orf77) and was reported as a selective protein that binds CD14⁺ monocytes and enhances their survival (1–3). Several reports have shown that incubating IL-34 with the extracellular domain protein of the macrophage colony-stimulating factor 1 receptor (MCSF-1R) inhibited the interaction between pure IL-34 and the monocyte in vitro. Additionally, the increase in monocyte vitality brought by IL-34 does not rely on colony-stimulating factor 1 (CSF-1), a second ligand of the CSF-1R (1, 2, 4). Although IL-34 and MCSF-1 exhibit comparable biological activity, myeloid cells respond differently to stimulation by IL-34 or MCSF-1, as evidenced by proinflammatory chemokines production and cytokines (5, 6). The interaction of MCSF-1R with IL-34 has been hypothesized to trigger the activation of autophagy and caspase signaling pathways in monocytes. This activation results in macrophage differentiation and polarization driven by IL-34 rather than CSF-1 (5). Differences in the signaling of CSF-1 and IL-34 have been attributed to differences in the affinity of MCSF-1R binding, hydrophobic/hydrophilic binding character, and differences in the binding pockets (5, 7). However, the molecular processes underlying these disparities must be investigated further in future research.

In 2010, Baudhuin et al. and colleagues published the first research on IL-34’s pathogenic role in malignant giant cell tumors (GCT) (8). GCT is a benign (noncancerous) bone tumor that is rich in osteoclasts, a cell type with a macrophage origin. Previous research suggested that CSF-1 stimulation via CSF-1R was necessary for osteoclast formation. Afterward, IL-34 was found to be abundantly expressed inside GCT and can promote mouse and human osteoclastogenesis via activating CSF-1R independently of CSF-1 (8, 9). Analysis of tumor-infiltrating immune cells also found a relation between IL-34 expression and type-2 immunosuppressive macrophages in different cancer types (4, 10–12). In patients with large B-cell lymphoma, IL-34 recruits monocytes, resulting in an increased macrophage ratio in the tissues and a poor prognosis (13) In the context of treatment failure, evidence that the TME plays a critical role in progression, metastasis, and therapeutic resistance via its interactions with cancer cells is increasing (11, 14). The tumor location of cancer cells that are resistant to treatment has a considerable number of immunosuppressive M2, which inhibits the immunological response against cancer cells (9, 15).

Blockade of immune checkpoints is an intriguing strategy that might potentially stimulate therapeutic anticancer activity. However, malignancies often develop immunological resistance to tumor antigen-specific T cells; hence, treatment outcomes in the clinic are frequently limited. Substantial evidence has shown that IL-34, a cytokine first discovered to control the function and survival of monocytes/macrophages (1, 4), is overexpressed in a wide variety of cancers, where it controls various tumor cell functions (16–18). Recent findings about understanding the activities against ICIs have shown that IL-34 helps malignancies evade the immune system, boosts immunosuppression, and reduces the efficacy of ICIs. In this review, we provide an overview of the current knowledge of the function and role of IL-34 in mediating tumor immunological resistance to ICIs in cancer.

The groundbreaking discovery of ICIs was a significant step forward in the field of immuno-oncology. Cancer cells can circumvent immunosurveillance and advance by various methods, one of which is the activation of immune checkpoint pathways, which inhibit antitumor immune responses. ICIs increase the immune-mediated clearance of tumor cells, revitalize anticancer immune responses by breaking inhibiting signaling pathways, and result in the eradication of cancer cells (19, 20).

Immune checkpoint molecules are inhibitory pathways that the immune system adopts to prevent undesirable self-immune responses (21). T lymphocytes, the main players in cell-mediated immunity, target tumor cells that express tumor-specific antigens in the TME (22). These antigens are displayed on the cell surface by major histocompatibility complex molecules, allowing T lymphocytes to recognize them (23). On the surface of activated T cells, immune inhibitory receptors are expressed including PD-1 and CTLA-4 (21). The checkpoint molecules block T-cell activation by sending a “STOP” signal to their host T cells after binding to their specific ligands. By expressing ligands, such as PD-L1, which are identified by the PD-1 T cell receptor, numerous tumor cells can evade T cell-mediated death. Blocking antibodies that interfere with these receptor–ligand interactions between tumor cells (or antigen-presenting cells) and T cells might alleviate the patch on T cells, hence releasing T cell-mediated anticancer effects. Undoubtedly, antibodies that inhibit checkpoints have been shown to be particularly effective against a wide range of cancers. In 2011, the USFDA has approved the first ICI therapy (Ipilimumab) specifically for metastatic melanoma treatment (24), leading to potential response rate regardless of surgery or targeted therapy (25). In the past few years, various studies for immune blockage mainly in renal cell carcinoma, lung cancer, pancreatic cancer (PC) and prostate cancer have yielded promising results, indicating the considerable potential for such a therapy strategy (14, 26, 27) ( Figure 1 ). Although PD-L1 is predominantly expressed on tumor cells, it may also be expressed on antigen-presenting cells; hence, the PD-1/PD-L1 T cell inhibitory mechanism operates throughout several stages of an immune response. PD-L1 and PD-L2 are members of the B7-H1 and B7-DC subfamilies, respectively. Therefore, enhancing the anticancer efficacy of ICIs in patients with cancer and reversing the immunosuppressive phenotype are crucial.

During the genesis of cancer, the TME gains immunosuppression and resistance to cancer therapy. Recently, ICIs for cancer has gained popularity as a therapy following the three primary traditional tumor therapies (surgery, radiation, and chemotherapy) to combat the TME. Blocking antibodies, particularly PD-1 and CTLA-4, have shifted the paradigm of cancer therapy; however, many patients with cancer do not respond and develop resistance to ICIs. In addition to its vital function in tumors, IL-34 has been identified as a factor that biases macrophages toward immunosuppression, leading to increased tumor evasion and progression (28). ICIs alone are not sufficient for effective treatment. However, the combination of ICIs with other newly discovered targetable biomarkers can have the potential to reverse the immunosuppressive state in the TME and may represent a promising approach for future treatment strategies.

The immunotherapies that target ICI molecules, e.g., CTLA 4 (29, 30), and PD-1 (31, 32), have contributed to the achievement of persistent responses in the treatment of cancer. Nevertheless, 25% of patients with melanoma that showed objective responses to ICIs acquire resistance to the therapy and suffer from the development of their disease and death (33). Numerous studies have proposed several mechanisms for immune system resistance at the cellular and molecular levels. These mechanisms include weakened T cell infiltration and activation at the TME, epigenetic alterations in cancer cells that impair IFN‐γ signaling, and local TME immunosuppression (21, 34, 35). In this regard, important roles in acquired and innate resistance to ICIs have been attributed to the infiltration of the TME with immunosuppression cells, such as M2-biased TAMs, regulatory T cells (Tregs), and myeloid-derived suppressor cells (MDSCs), as well as numerous inflammatory and metabolic mediators such as arginase1 (ARG1), prostaglandin E2 (PGE2), and indoleamine 2,3-dioxygenase (IDO) (36–38). In many instances, the soluble molecules secreted by the tumor cells are responsible for the formation and maintenance of the immunosuppression TME (39). In light of this, focusing on these parameters would make it possible to alleviate immunosuppression and increase immunotherapeutic responses (40, 41).

Recently, IL-34 and its receptor, CSF-1R, has drawn strong interest as crucial proteins controlling the survival, function, and proliferation of M2-biased TAMs, which are distinguished by their immunosuppressive activities (42, 43). In several cancers, notably melanoma, PC, and hepatocellular carcinoma, the CSF-1/CSF-1R axis has been associated with the emergence of resistance to PD-1/PD-L1 suppression (44–48). In addition to being activated by CSF-1, the CSF-1R receptor can also be activated differently by binding IL-34 as the second ligand (1). Although CSF-1 and IL-34 have the same receptor and have a comparable effect in vitro on myeloid cells, the two cytokines bind to distinct pockets within the extracellular immunoglobulin (Ig)-like domains of CSF-1R, resulting in various activation pathways of CSF-1R (49). An important distinction between CSF-1 and IL-34 is that IL-34 is selectively expressed in the skin and brain, whereas CSF-1 is physiologically widely dispersed throughout the body (50). Even though it is selectively expressed, IL-34 may be released by tumor cells, and it plays a crucial role in the development of tumors (1, 12, 50–54) and their resistance to chemotherapy and molecularly targeted treatment (15, 55).

Consistent with its immunosuppressive properties, IL-34 expression in tumors is related to lower cellular frequencies (CD4⁺, CD8⁺ T cells, and M1-biased macrophage) and molecular (various chemokines and cytokines) effector frequencies in the TME (11, 56). Using a neutralizing antibody against IL-34 improved ICI’s therapeutic advantages in combinational therapy models involving a patient-derived xenograft model (57). Therefore, cancer therapy may gain a potentially game-changing new option if IL-34 inhibitors can be used to limit protumorigenic effects and ICI resistance ( Table 1 and Figure 2 ).

Widespread cancer types may benefit from the immunoregulatory activities of IL-34. An increase in tumorigenesis is associated with the overexpression of IL-34, which has been demonstrated to play a role in the resistance, progression, and overall survival of patients. Despite the many advantages of ICIs, several challenges about ICI resistance have not been addressed. IL-34 may be responsible for inhibiting the therapeutic benefits of ICIs, according to new findings. To assess ICIs effectively, having a comprehensive understanding of the potential benefits and risks of IL-34 dysregulation in the TME is vital. Therefore, clinical trials based on robust preclinical evidence, as well as extensive translational research to explain the optimal dose and administration, potential side effects with safety, and the mechanisms of IL-34’s effects in combination with ICIs, are essential to further treatment approaches for various types of cancer.

Since its discovery, IL-34 has been the subject of studies regarding how it affects immune responses. Furthermore, IL-34 and its functional receptors activate intracellular pathways that are involved in the development and progression of many different types of cancer. Here, studies suggesting that IL-34 may play a role in the development of therapeutic resistance to tumor-ICI therapies were summarized. IL-34 limits the effectiveness of ICIs not only by interfering with T-cell attraction but also by altering the inflammatory situation of the TME through polarization imbalances of the M1 and M2 macrophage populations. The combination of IL-34 inhibition with ICIs has raised its profile as a potentially essential treatment option for patients with cancer in the future.

The review was designed and revised by FA, MS, YAA, Al-Azab M, AA, MA and AR. FA and MS conducted the literature collection. FA and YAA draw the figures and CZ provided guidance and revised this manuscript. Correspondence MS and CZ. Funding and correspondence; CZ. All authors contributed to the article and approved the submitted version.