TAMs, comprising microglia and macrophages, are the dominant infiltrating immune cells in GBM and account for 30-50% of the tumor mass (27, 28). Microglia are yolk sac–derived and have limited self-renewal capacity, while macrophages are monocyte-derived from the bone marrow and peripheral circulation and constituted approximately 85% of the total TAM population (29, 30). Despite different origins, they both play a vital role in tumor progression. The activated TAMs in GBM can be simply divided into tumor-suppressing M1-like phenotype and tumor-promoting M2-like phenotype with great plasticity and heterogeneity. The main TAMs in GBM present possess an M2-like phenotype, promoting tumor invasion, proliferation, angiogenesis, and immune evasion through the expression and secretion of matrix-degrading enzymes, angiogenic factors, and immunosuppressive cytokines/chemokines (28, 31). However, it should be noted that dichotomously classified M1 and M2 phenotypes were fitted well in vitro under optimal conditions, as it does not fully reflect the complexity of TAMs activation. Additional states (such as M2a, M2b, M2c, and M2d states) have also been identified, suggesting that TAMs in vivo likely have more functions along the M1/M2 spectrum. Several studies have shown that EGFR alterations associated with TAMs infiltration in GBM, and inhibiting EGFR by pharmacy strongly decreased microglia-stimulated invasion in GL261 GBM cells (32). Another study using GBM cell lines U87 and A172 in vitro and in vivo shows that EGFR cooperates with EGFRvIII to induce macrophage infiltration by upregulation of chemokine C-C motif ligand 2 (CCL2) through the KRAS pathway, one of the major downstream pathways of the EGFR (33). In addition, dual targeting of EGFR and mTOR pathways has also been demonstrated to inhibit tumor growth and macrophage infiltration on GBM xenografts by downregulation of CCL2 (34), an immunosuppressive cytokine that shapes the macrophage polarization toward a tumor-promoting, immunosuppressive phenotype, and significantly shortened the survival of GBM-bearing mice (30, 35). Furthermore, a recent single-cell RNA sequencing study focused on the immune landscape during GBM progression found that subsets of pro-inflammatory microglia in developing GBMs, while anti-inflammatory macrophages are observed in end-stage tumors. This evolution parallels the extensive growth of EGFR+ GBM cells (36). Another single-cell level study reveals that GBM samples with EGFR and cyclin-dependent kinase 4 (CDK4) co-amplifications in the same cell exhibit higher infiltration of CD163+ immunosuppressive macrophages (37).

MDSCs are a heterogeneous population of immature bone marrow cells consisting of two cell subsets: granulocytic or polymorphonuclear MDSCs (PMN-MDSCs) and monocytic MDSCs (M-MDSCs). MDSCs exert their immunosuppressive effects in GBM by inhibiting cytotoxic T cell activity, suppressing the function of NK cells, macrophages, and dendritic cells, and augmenting the effect of Tregs (38, 39). The density of MDSCs also correlates with tumor stages, chemotherapy response, and patient prognosis in GBM (39). According to two recent studies using GBM animal models, it has been observed that, similar to TAMs, MDSCs accumulation is more pronounced in EGFR (+) GBM, when compared to the EGFR-wild type (EGFR-WT) (36, 40). These studies also found that EGFRvIII GBM highly expressed chemokine C-X-C motif ligand 1/2/3 (CXCL1/2/3) and PMN-MDSCs-expressed chemokine C-X-C motif receptor 2 (CXCR2) constitute an axis that regulates the output of PMN-MDSCs from the bone marrow, leading to increased systemic levels of these cells. Interestingly, pharmacological inhibition of this axis benefitted for response to ICIs and prolonged survival in EGFRvIII-driven GBM mice (40). In summary, the immunosuppressive TME of EGFRvIII GBM may be due to the greater infiltration by MDSCs, targeting this cell is a potential therapeutic strategy for GBM, but further research is needed in this area.

TILs are a group of tumor-infiltrating and antigenic cell populations that exist in TME, and their amount and subtypes determine the clinical outcomes and treatment responses in glioma patients (41, 42). CD4+ helper T cells stimulate an anti-tumor response by activating CD8+ cytotoxic T cells and promoting B cell proliferation and differentiation. CD8+ cytotoxic T cells induce tumor apoptosis through T cell receptor activation or lyse tumor cells by releasing interferon-γ, perforin, and granzyme (43). However, T cells are rare in the GBM TME, accounting for less than 0.25% of total isolated cells from GBM biopsies. The majority of samples exhibit a “lymphocyte depletion” phenotype with few CD8+ cytotoxic T cells but increased infiltration of Tregs, particularly in cases with EGFR amplification (44, 45). On the other hand, dysfunction of T cells (such as senescence, tolerance, anergy, exhaustion, and ignorance) is a hallmark of GBM, leading to ineffective anti-tumor immune responses (28, 43, 46). It has been suggested that the efficacy of EGFR-TKIs depends mainly on the presence of CD4+ and CD8+ T cells, as treatment significantly enhances the immune responses against the tumor (47). In contrast to conventional CD4+ and CD8+ T cells, the FOXP3+Tregs, a subset of CD4+ T cells, play an opposite role in the GBM microenvironment. Tregs inhibit the activation of effective T cells through the interactions with cytotoxic T lymphocyte antigen-4 (CTLA-4) and CD80/86 on antigen-presenting cells (APCs). They also secrete immunosuppressive cytokines that promote tumor progression and polarization of macrophages toward an M2-like phenotype (48). How the aberrant EGFR signaling pathway regulates these T cells in the GBM microenvironment may be related to the expression of some immunosuppressive molecules or cytokines, such as programmed death-ligand 1 (PD-L1) (23), extracellular-5’-nucleotidase (CD73) (49), and transforming growth factor (TGF)-β (50), which will be discussed in detail in the next section.

NK cells are innate lymphoid cells that account for a small proportion of tumor-infiltrating cells, which exert anti-tumor effects through lytic granules secretion and recruiting other immune cells (51). However, some GBM patients show reduced NK cell activation due to decreased levels of the natural killer group 2 member D (NKG2D) receptor on the NK cell surface (28). Additionally, NKG2D ligands in cancer cells correlated positively with the activation of EGFR and its downstream MEK pathway, which is commonly hyperactivated in those tumors and reduced by EGFR inhibitors (52). However, different NKG2D ligands can function as target molecules for NK cell-mediated immunosurveillance or tumor immune escape. NKG2D ligands expressed on the cell surface of tumor cells can be recognized by NK cells through NKG2D and promote a cytotoxic response that leads to tumor cell elimination (53). However, soluble NKG2D ligands generated by a disintegrin and metalloproteinase 10 (ADAM10), ADAM17, and matrix metalloproteinase 14 (MMP14), can promote NKG2D down-regulation, impairing NK cell-effector functions and facilitating tumor immune escape (54, 55). Therefore, to determine the mechanism of EGFR signaling pathway regulation of NK cells in GBM, further studies are needed to focus on whether GBM with EGFR alterations express higher levels of NKG2D ligands or which form of the ligands are expressed in EGFR-altered GBM.

Tumor infiltrating B cells also play a role in shaping tumor development. Activated B cells display antitumor activity by producing immunoglobulins, promoting T cell responses, and killing tumor cells directly. Other B cells with tumor-promoting effects are defined as Bregs, upregulate PD-L1, CTLA-4 and secrete immunosuppressive cytokines such as IL-10 and TGF-β, attenuating the response of T and NK cells while facilitating the activation of Tregs, MDSCs, and TAMs (56). However, no relevant studies have yet shown the association between altered EGFR signaling pathways in tumor cells and the infiltration and activation of Bregs, especially in GBM. Further investigations are needed to explore this field.

The expression of PD-L1 in GBM correlates with the patient prognosis (57, 58). However, the PD-L1 positivity rate in GBM specimens ranges from 61.0% to 88% in different studies (59). Such inconsistent results might be associated with different PD-L1 detection techniques, tumor heterogeneity, and different specimen sources. PD-L1 binding to PD-1 on T cells restrains the anti-tumor response, inducing apoptosis or anergy in activated T cells and promoting the infiltration of Tregs, leading to tumor immune escape (23). Recent studies have found that PD-L1 expression in GBM cells is associated with EGFR and its downstream signaling pathways (23). Among them, EGFR-dependent PI3K activation, phosphatase and tensin homolog deleted on chromosome ten (PTEN) loss, and AKT activation induce the β-catenin binding to the CD274 gene (encode PD-L1) promoter region, resulting in increased PD-L1 expression (60, 61). Another study found that the activated EGFR-ERK signaling pathway in GBM upregulates COP9 signalosome subunit 6 (CSN6) and PD-L1 protein expression, stabilizing PD-L1 and inhibiting its degradation (62). Radiotherapy has also been shown to increase PD-L1 expression in glioma cells. In a vitro study, irradiated human GBM cell lines U87 and U251 show significant upregulation of PD-L1 expression at the protein and mRNA levels via phosphorylation of EGFR and its downstream signaling molecule JAK2 (63). A single-center retrospective study has found that GBM patients with EGFR amplification exhibit shorter median OS after receiving ICIs (16). Therefore, targeting EGFR and its downstream signaling, in combination with PD-1/PD-L1 ICIs, may hold the potential in restoring the T-lymphocyte killing capacity and improving the sensitivity to immunotherapy and targeted therapy in tumor patients (47, 64, 65).

CD73 is anchored to cell membrane lipid rafts and highly expressed in various tumors including GBM and plays a role in immune regulation by generating adenosine in the TME. Adenosine is a component of adenine nucleotides that regulates immune cell function by the ectonucleoside triphosphate diphosphohydrolase (NTPDase1, CD39)-CD73 synergic effect in glioma TME (66). ATP and adenosine diphosphate (ADP) released from tumor cells are hydrolyzed by CD39 to adenosine monophosphate (AMP), which is then further dephosphorylated to adenosine by CD73 (67, 68). In cancer patients, alterations in adenosine deaminase (ADA) activity can lead to increased levels of adenosine as ADA normally deactivates adenosine by converting it to inosine (68). Adenosine mediates its regulatory functions by binding to adenosine receptors (A2AR and A2BR) on the tumor-infiltrating immune cells, triggering the accumulation of intracellular cyclic adenosine monophosphate (cAMP). This signaling molecule is associated with the establishment of an immunosuppressive TME characterized by the polarization of TAMs into a tumor-promoting M2-like phenotype, increased infiltration and immunosuppressive activity of Tregs and MDSCs, and suppressed activity of dendritic cells, CD8+ T cells, and NK cells (67–69). Overexpression of CD73 promotes immunosuppression and is associated with poor prognosis in multiple cancers (66, 70). A Recent in vivo study has revealed that blocking CD73 expression in the tumor cells can potentially regulate the GBM immune microenvironment and inhibit tumor growth by inducing apoptosis (71). Another study based on single-cell RNA sequencing found a correlation between high CD73 expression and EFGR amplification as well as hypoxia in GBM (49). These findings suggest that EGFR alterations signaling shape an immunosuppressive TME in GBM by promoting CD73 expression. Targeting the CD73-adenosine axis may hold promise as a therapeutic strategy in combination with EGFR-TKIs.

TGF-β is a pro-tumorigenic cytokine overexpressed and produced by various cells in GBM, contributes to tumor growth, angiogenesis, maintenance of glioma stem cell stemness, and the establishment of an immunosuppressive TME (72, 73). TGF-β exerts its antitumor immune response on immune cells within the TME. For innate immunity, TGF-β promotes TAMs recruitment and M2-like polarization, monocyte differentiation into MDSCs, and attenuating the tumor killing efficiency of NK cells. For adaptive immunity, it facilitates Tregs persistence, inhibiting the function of effector T cells and antigen-presenting dendritic cells (12, 50, 74). In addition, high-level TGF-β also contributes to poor response to PD-L1 immune therapy (75). Recent studies have revealed that the activation of TGF-β may be related to EGFR singling and its downstream molecules. The activation PLCγ-PKC pathway leads to intragin-αvβ activation and contributes to local TGF-β activate from its latent to its bioactive form (12, 76). Although it is well known that the correlation between EGFR signaling and TGF-β expression in many cancers. Further studies specific to GBM are needed to verify this finding.

Overall, EGFR and its downstream signaling pathways modulate immune-related molecules and cytokines in GBM, influencing the immune cell landscape and establishing an immunosuppressive TME. Targeting these interactions may hold promise for improving the effectiveness of immunotherapy and targeted therapy in GBM treatment.