B7-H3 at the crossroads between tumor plasticity and colorectal cancer progression: a potential target for therapeutic intervention

Investigation into the expression of B7 family of proteins in colorectal tissue has revealed that B7-H3 is lowly expressed in normal colon tissue compared to CRC tissue. This feature makes B7-H3 a potential candidate biomarker for the early diagnosis of CRC [16]. Recent studies on CRC tissue samples showed a negative correlation between the tumor-infiltrating T-lymphocyte level and B7-H3 expression [17]. The contradictory nature of B7-H3 can be related to unidentified receptors. Studies comparing B7-H3 in the lesions of CRC at various stages, such as polyps (benign), adenomas (pre-cancerous), high-grade neoplasms (adenomas with higher risk of progressing into cancer), and cancerous tissues, reported high levels of B7H1 and B7-H3 in the early stage of CRC development. They continued to express in various stages of CRC, such as adenomas, high-grade neoplasms, and cancer [16]. However, the expression of B7-H4 was reported only in the advanced stage i.e., the CRC.

Interestingly, immunohistochemistry studies revealed differences in their subcellular localization of B7-H1 and B7-H3 depending on the stage of CRC development [16]. Peng Lu and co-workers conducted a bioinformatics study on the genes in CRC cells and normal colon cells that function together with B7-H3, and they found that the gene expression was altered according to the activity of B7-H3. They reported that B7-H3, which functioned at the plasma membrane, brought a critical activation to the lymphocyte, thus validating the findings by other groups on the immunological role of B7-H3 in T-cell response. In-depth studies into the biological pathways revealed that B7-H3 was involved in T-lymphocyte receptor signaling, leading to automatic immune resistance [18]. More details on T-cell regulation by B7-H3 in TME are described in Sect. 2.4. Investigations on B7-H3 are generating considerable interest in cancer research, as it is a promising diagnostic and prognostic marker and a viable target for anticancer treatment [19‐21]. Indeed, various clinical studies have well-established the association between B7-H3 and poor prognosis [10]. The development of immunotherapy targeting B7-H3 is rapidly evolving, with many ongoing clinical trials investigating the safety and efficacy of these therapeutic approaches in cancer patients. Details on various strategies targeting B7-H3 are given in Sect. 6. Overall, B7-H3 is emerging as a more promising prognostic and potential candidate for CRC treatment.

Apart from the well-studied immunomodulatory action of B7-H3 and its link to CRC, this multifunctional protein contributes significantly to changes in the TME and tumor plasticity, promoting CRC occurrence and progression (Table 1). Tumor plasticity refers to a non-mutational process [22] that is closely associated with processes such as epithelial-mesenchymal transition (EMT), cancer stem cell (CSC) formation, metabolic reprogramming, etc. [23]. Phenotypic plasticity underlies local invasion and distant metastasis in CRC [24, 25]. Furthermore, tumor heterogeneity, senescence, relapse, and treatment resistance are a consequence of tumor plasticity [26].

Tumor plasticity allows tumor cells to evade apoptosis, invade, and metastasize to distant places [32]. B7-H3 has enabled CRC cancer cells (SW620 and HCT8 with varying expression levels of B7-H3) to resist apoptosis and enhance cell survival [32]. This anti-apoptotic property (Table 1) is enabled via activating the Janus kinase (Jak)2/signal transducers and activators of transcription (STAT) 3 pathway that increases the expression and levels of anti-apoptotic proteins B-cell lymphoma 2 (Bcl-2) and B-cell lymphoma extra-large (Bcl-xL) while decreasing levels of pro-apoptotic Bax [32]. Thus, B7-H3 confers resistance to apoptosis induced by anticancer drugs. This observation also applies to pancreatic and gastric carcinoma, where B7-H3 has shown similar anti-apoptotic features [43, 44]. Sun et al. described an alternative mechanism associated with the anti-apoptotic effect of B7-H3. As reported in gastric cancer, B7-H3 interacts with fibronectin, which consequently activates the oncogenic signaling pathway phosphoinositide 3-kinase (PI3K)/protein kinase B (AKT), inhibiting apoptosis [44]. Two downstream targets in PI3K/AKT pathway related to apoptosis (Bcl-2 was upregulated) and cell cycle progression (p53 was downregulated) were dysregulated by the direct interaction of B7-H3 with fibronectin [44].

Another feature of tumor plasticity known as EMT is the reversible functional and phenotypic changes that enable the malignant cells to invade and disseminate to distant sites. Cancer cells with high metastatic potential exhibit increased B7-H3 expression in various cancers, including CRC [45]. Bo Jang and co-workers conducted a study on CRC, emphasizing the significance of B7-H3 in inducing malignant transformation [36]. To evaluate the metastatic potential associated with B7-H3 expression, they looked at the matrix metalloproteinases (MMPs), epithelial markers, and acquired mesenchymal markers in SW480 and Caco-2 CRC cell lines [36]. Epithelial markers β-catenin and E-cadherin were downregulated, while the mesenchymal marker vimentin and N-cadherin were upregulated in B7-H3 overexpression experiments [36]. Closer analysis revealed that Smad1, a transcription factor, is translocated to the nucleus to transcribe the downstream genes regulating EMT and was found to be regulated by B7-H3 via PI3K/AKT signaling [36]. This hypothesis proves that B7-H3 is a key regulator in B7-H3-induced EMT. Moreover, MMP2 and MMP9 were co-expressed in CRC tissues with B7-H3 and clinically correlated with CRC patient’s T-stage [36]. Mechanistically, MMP expression is regulated by the phosphorylation of STAT3 [38]. B7-H3-overexpressing cells activated the Jak2-STAT3 axis pathway, activating downstream MMPs, crucial modulators for cancer cell migration and invasion [38]. In the context of tumor plasticity, stemness is another feature that needs to be discussed along with EMT (Table 1). Cancer cells exhibiting EMT traits have shown characteristics of CSC [23, 46]. The metastatic spread of cancers correlates with the expression of stem cell biomarkers CD133, CD44, ALDH1, and OCT4 [2, 47‐50], which was significantly increased in CRC cells overexpressing B7-H3 (Fig. 2). Clinically, the expression of CSC markers in CRC correlated with liver metastasis [2]. An independent study by Zhou Bin and co-workers reported co-expression of CD133 and B7-H3 in 22 of the 104 CRC patient tumor samples [34]. The co-expression of these proteins is clinically correlated with tumor invasion, both lymphatic and distant metastasis, and Duke’s stage, thus proposing B7-H3 as a reliable prognostic marker [34]. CD133 has already been associated with CSC, and its presence is related to tumor initiation and poor prognosis in CRC [51]. Moreover, CD133 also aids in immune evasion. Nevertheless, the mechanism of interactions between the two molecules has not yet been elucidated as their receptors have not yet been identified or characterized [34]. Tumor angiogenesis is a critical step toward tumorigenesis, invasion, and metastasis with a proven role of B7-H3 participation (Table 1). Different components of the TME create a favorable environment for neovascularization mediated via cytokines and other growth factors collectively known as angiogenic factors. The latest findings provide insights into a novel mechanism of angiogenesis by cancer-secreted exosomes [29]. Exosomes are small vesicles containing proteins, DNA, and RNA secreted by different types of cells, including malignant cells, mediating intracellular communications. CRC-derived exosomes with overexpressed B7-H3 were found to be taken up by vascular endothelial cells [29]. This angiogenic program mediated by B7-H3-expressing exosomes was achieved through the AKT1/mTOR/VEGFA signaling pathway [29]. Other significant findings on angiogenesis in CRC demonstrated B7-H3/NF-κB/VEGFA axis in VEGFA expression. While examining the mRNA levels of key angiogenic cytokines VEGFA, VEGFC, bFGF, and PDGF-BB, a positive association was reported with the B7-H3 expression levels [27]. NF-κB activity was more closely involved in promoting angiogenesis than the AKT or STAT3 pathway, as indicated by B7-H3-dependent VEGFA expression [27].

In addition, microRNAs may play an essential role in regulating CRC growth and progression. miR-29a inhibits colon cancer progression, invasion, and migration via downregulation of B7-H3 expression [52]. These data point to miR-29a and B7-H3 as novel molecular targets for advanced CRC chemotherapy. Wang et al. found the suppression of CRC growth, migration, invasion, and cell apoptosis induction through miR-187 overexpression. However, the activation of B7-H3 showed opposite effects on CRC cells. This study documented the essential role of miR-187 in suppressing CRC progression by directly affecting B7-H3 [53]. Besides that, in vitro and in vivo evaluations documented that TGF-β1 supports CRC immune escape by overexpressing B7-H3 and B7-H4 through the miR-155/miR-143 signaling [54]. Another study elucidated a miR-34a-modulated cancer immune evasion mechanism via overexpressed B7-H3 in CRC in vitro and xenograft models. More specifically, miR-34a downregulated SIRT1 and activation in NF-κB/B7-H3/TNF-α signaling pathway [55].

The development of CRC is a progressive process with an accumulation of changes at the genetic, epigenetic, cellular, morphological, molecular, and metabolic levels. Altered cellular metabolism, now considered a hallmark in CRC progression, is known to modify the landscape of the tumor environment. The abnormal metabolic program provides tumors with alternative energy resources supporting the continuous existence of CRC cells. Glucose, the primary energy source, is catabolized in a normal cell through multiple steps via the glycolysis-oxidative decarboxylation-Krebs cycle-oxidative phosphorylation mechanism that occurs in the presence of oxygen. Alternatively, in the absence of oxygen, pyruvate is converted to lactate. Otto Warburg was the pioneer to report metabolically different phenotypes in cancer where, even in the presence of oxygen, he observed a shift in glucose metabolism towards glycolysis with increased lactate production and reduced oxidative phosphorylation (this mechanism is famously known as the “Warburg effect”). This shift in tumor metabolism can significantly influence the TME by remodeling the immune and neoplastic cells that comprise the TME [5]. B7-H3 compliment CRC progression by regulating glucose metabolism (Fig. 3 and Table 1), and the abnormal level of metabolites secreted influence the type and function of the immune cells in the TME, further promoting chemoresistance. B7-H3 has been documented as a critical immune-independent contributor to cancer glucose metabolism reprogramming via ROS-mediated stabilization of HIF-1α [56].

Shi et al. illustrated the direct link of B7-H3 in promoting aerobic glycolysis by regulating one of the key enzymes hexokinase type 2 (HK2) [42]. The study reported elevated B7-H3 expression followed by a significant increase in glucose consumption and lactate production, while depletion of B7-H3 exhibited the opposite effects in HCT-116 and RKO cells [42]. They further explored the molecular pathway by which B7-H3 mediates the HK2 expression, where they found that STAT3 signaling regulates the expression of HK2 and STAT3 as a downstream target of B7-H3 in CRC cells (Fig. 3) [42]. Shi et al. also verified a positive correlation between the expression of B7-H3 and HK2 in tissue samples from CRC patients, thus further emphasizing the role of B7-H3 in CRC cancer progression [42]. Consistent with this observation, a positive correlation between tumor glycolysis and immune signature in TME was recorded across 14 cancers [57]. A computational analysis of glycolysis-related genes (e.g., hexokinase and phosphoglucose isomerase in the glycolytic pathway) was upregulated in highly glycolytic cancers [57].

The role of B7-H3 in the TME and its immunoregulatory function is an active area of research. TME is a unique ecosystem that emerges due to interaction with several host cell components. Additionally, the TME is a continually evolving system composed of neoplastic cancer cells and multiple stromal cells, including angiogenic endothelial cells, pericytes, infiltrating immune cells, and cancer-associated fibroblasts (CAFs) releasing mitogenic factors capable of promoting cancer cell proliferation [58]. Tumor immune evasion and metastatic tendency in CRC are achieved through intrinsic plasticity and adaptability orchestrated by cancer cells, immune cells, and stromal cells via cytokines, growth factors, and other signaling molecules [37, 59, 60]. Cancer cells can invoke an immune response that could either drive a cytotoxic immune reaction or an antagonistic response with a proliferative effect. The innate and adaptive immune systems participate in the immune recognition and elimination of neoplastic cells. An innate immune system comprising macrophages, natural killer cells, neutrophil granulocytes, and monocytes is the first line of defense against invading pathogens and drives the host recognition of cancer-associated antigens [61]. Host recognition of cancer cells initiates active recruitment of T-lymphocytes into the tumor area, and other immune cells of the innate immune system, along with T-lymphocytes, orchestrate the antitumor action. However, cancer cells escape immune surveillance through immune evasion. As discussed in the previous chapter, metabolic reprogramming in the tumor niche prevents the tumor cells from being recognized by the immune system. Cancer cells employ various cell survival signaling pathways to escape antigen recognition by the release of immunosuppressive mediators, creating an acidic environment, recruiting tumor-promoting immune cells (macrophages with an M2-phenotype), expansion of tumor-promoting T-lymphocyte signature under the influence of chemokine and cytokine secreted by tumor cells [59]. The human Vγ9Vδ2 T cells represent a specific cell type that shows great potential in immunotherapy cancer research. In this regard, the suppression of the B7-H3 activity significantly elevated the IFN-γ-dependent cytotoxicity of Vγ9Vδ2-T cells against colon cancer cells in the mouse HCT116 xenograft model [62].

Histopathological analysis of CRC tissue showed strong evidence of tumor-infiltrating lymphocytes (TILs) and tumor-associated macrophages (TAMs) in tumor tissue, indicating their role in adaptive and innate immunity. TAMs are seen predominantly in two functional phenotypes, M1 and M2 (Fig. 4). The former is anti-tumorigenic. It induces both direct cytotoxic effect and antibody-dependent cell-mediated cytotoxicity, while the latter is pro-tumorigenic and pro-angiogenic with the expression of interleukin (IL)-10, IL-1β, VEGF, and MMP [63]. M1 and M2 phenotypes have high plasticity depending on the TME [63, 64]. An increased presence of tumor-infiltrating macrophages has been associated with cancer cells with more B7-H3. Clinically, a high expression of B7-H3 and the TAM density in CRC tissue were associated with reduced overall survival of patients [65]. Studies examining the immune cells infiltrating the TME revealed that the M2 phenotype was predominantly present in the TME and indicated the presence of pro-tumor growth factors and cytokines released by M2 macrophage [10, 65]. The JAK2-STAT3 pathway could probably mediate the polarization of macrophages [66]. Closer analysis showed the presence of CD68⁺ macrophages in both tumor nest and stroma, and it positively correlated with B7-H3 expression on cancer cells. Concerning T-lymphocyte infiltration, flow cytometry analysis for the expression of B7-H3 on CD3⁺ T-lymphocytes showed significant differences with the adjacent normal tissue [16]. As the receptor for B7-H3 is not characterized yet, explaining the mechanism of its immunoregulatory role is challenging. However, putative receptors for B7-H3 have been identified on activated T-lymphocytes and TAMs [65]. A study by Mielcarska et al. provides an exemplary observation of B7-H3 expression in the context of the immune landscape in CRC [10] investigating the CRC tissue’s tumor status, TIL, and cytokine composition [10]. The immune infiltration cell analysis showed a clear shift in the density of immune cells in the tumor correlated with B7-H3 expression [10]. Tumors with elevated B7-H3 expression showed reduced levels of CD4⁺ quiescent memory T-lymphocytes and CD4⁺ activated memory T-lymphocytes [10].

On the other hand, increased levels of regulatory T-cells (Tregs), macrophages M0, monocytes, and neutrophils were associated with tumors with increased B7-H3 expression [10]. Increased IFN-γ and tumor growth factor (TGF)-β responses were also elevated [10]. Additionally, the shift in the macrophage polarization from M1 to M2, as indicated by the CD163 marker, further confirmed the immunoregulatory role of B7-H3 in shaping TME. To determine the functional role of B7-H3 in cell signaling, Mielcarska et al. performed gene set enrichment analysis (GSEA). The study revealed the upregulation of critical metabolic pathways corresponding to oxidative phosphorylation, fatty acid metabolism, and heme metabolism [10]. On the contrary, high expression of B7-H3 showed downregulation of metabolic pathways associated with hypoxia, glycolysis, mTOR C1 signaling, and G2M checkpoint [10]. Nevertheless, the observation of the downregulation of hypoxia and glycolysis-related pathways in this study conflicts with the observations by other research groups [42, 67].