ANGPTL4 is secreted by cells that can cleave it into two subtypes. Native full-length ANGPTL4 (flANGPTL4) can produce the COOH-terminal fibrinogen-like fragment (cANGPTL4) and the N-terminal coiled-coil domain (nANGPTL4) via proteolytic processing (19). To determine whether ANGPTL4 overexpression correlates with the prognosis of TNBC, we analyzed the level of flANGPTL4 in cancer cells by IHC. We confirmed that high flANGPTL4 expression was associated with lower relapse and vascular invasion rates than weak expression. Next, we observed that flANGPTL4 overexpression inhibits cell adhesion and attachment, which leads to inhibition of cell invasion and migration. Various studies have also shown that ANGPTL4 expression prevents metastasis and angiogenesis by reducing vascular leakiness, cell motility and invasiveness in different neoplasm types, including melanoma, gastric, lung and colorectal tumors, as well as metastases (20–22). Strong ANGPTL4 expression in nude mouse xenografts also inhibited metastasis through suppression of tumor cell migration and invasiveness (21). In the present study, we demonstrated that ANGPTL4 overexpression decreased the vascular invasion and relapse rate in patients, which are factors related to aggressiveness and invasion. These results were consistent with the phenomena observed in vitro.
However, many studies have reported that ANGPTL4 expression increases cancer cell aggressiveness and migration (9, 23–27). For instance, Kim and his colleagues demonstrated that ANGPTL4 induction by hypoxia facilitated the growth of colorectal cancer (25), and Li et al. announced that HIF-1α-activated ANGPTL4 overexpression contributes to tumor metastasis in hepatocellular carcinoma (HCC) (9). Notably, previous studies have shown conflicting results in breast cancer research. One team discovered that the expression of ANGPTL4 could be induced by TGFβ, which could facilitate lung metastasis (23). Others have shown that adipocyte-derived ANGPTL4 drives disease progression under obese conditions (27). Zhang et al. revealed that the downregulation of HIF-1α expression in breast cancer cells suppressed primary tumor progression and inhibited the metastasis of tumor cells to the lungs by reducing ANGPTL4 expression (8). In addition, previous studies showed that the copy number of ANGPTL4 increased in the circulating tumor cells of patients and was related to increased aggressiveness in breast cancer (28). Additionally, ANGPTL4 overexpression was related to a short DFS in a basal breast cancer type commonly found in young women (29).
These conflicting phenomena might be given rise to the following possibilities: First, different ANGPTL4 fragments may have distinct biological roles in human cancers. Native flANGPTL4 can suppress tubule formation and endothelial cell migration (22). nANGPTL4 binds to LPLs to inhibit their activities (12, 16). cANGPTL4 may have various effects, including regulating cancer progression (16, 30, 31). The investigators of the present study demonstrated that flANGPTL4, and not nANGPTL4 or cANGPTL4, was responsible for inhibition of TNBC progression in vitro and favorable prognosis in vivo. Second, despite discrepancies in these results, early studies have used various cancer cell samples, suggesting that the disparate influences of ANGPTL4 in cancer progression may be determined by cancer types. Third, the primary source and tumor microenvironment of ANGPTL4 may affect biological behaviors. For example, Ryan Kolb et al. hypothesized that the main source of cANGPTL4 could be adipose cells in the breast cancer microenvironment. Moreover, a reduction in cancer progression was observed when ANGPTL4 was maintained in the tumor cells but reduced in the microenvironment (27). Another study found that circulating ANGPTL4 in the tumor microenvironment might be excreted by other cell types, such as adipocytes, which could accelerate cell proliferation and metastasis (31). Although ANGPTL4 was highly expressed in adipocytes and epithelial cells, we only focused on the role of flANGPTL4 from cancer cells, not stromal cells. These hypotheses suggest that the expression level and effects of ANGPTL4 in cancer may be context- and tumor-type-dependent, which may explain the diversity of previous studies.
We further explored the potential mechanisms by which ANGPTL4 regulates TNBC progression, and we performed next-generation RNA sequencing to identify the receptors of ANGPTL4. The results revealed that genes included in the ECM were most affected by ANGPTL4 overexpression. Notably, ANGPTL4 is a specific matricellular protein that is considered to interact with specific integrins and ECM proteins to affect cell migration (32, 33). The downstream receptors that regulate the functions of ANGPTL4 are still unclear. A study showed that the tumor-facilitating effect of ANGPTL4 is strongly associated with PGE2 and hypoxia (25). Additionally, ANGPTL4 is believed to interact with other molecules such as reactive oxygen species (ROS) to regulate anoikis resistance and antiapoptotic effects (25, 34, 35). A study found that modification of ANGPTL4 might inhibit the MEK/ERK pathway in endotheliocytes, suppressing angiogenesis induced by VEGF (36). Moreover, the VCAM-1/integrin b1 (9) and Rac/PAK signaling pathways (24) were activated by increasing the ANGPTL4 interaction with specific factors. Based on these and our results, it is likely that ANGPTL4 inhibits TNBC adhesion and migration via ECM-related biological signals. Thus, further studies are needed to illuminate the potential mechanisms by which ANGPTL4 regulates cancer development.