Abstract
Background
Colorectal cancer (CRC) commonly exhibits tolerance to cisplatin treatment, but the underlying mechanisms remain unclear. Within the tumor microenvironment, macrophages play a role in resisting the cytotoxic effects of chemotherapy by engaging in efferocytosis to clear apoptotic cells induced by chemotherapeutic agents. The involvement of extracellular vesicles (EVs), an intercellular communicator within the tumor microenvironment, in regulating the efferocytosis for the promotion of drug resistance has not been thoroughly investigated.
Methods
We constructed GFP fluorescent-expressing CRC cell lines (including GFP-CT26 and GFP-MC38) to detect macrophage efferocytosis through flow cytometric analysis. We isolated and purified CRC-secreted EVs using a multi-step ultracentrifugation method and identified them through electron microscopy and nanoflow cytometry. Proteomic analysis was conducted to identify the protein molecules carried by CRC-EVs. MFGE8 knockout CRC cell lines were constructed using CRISPR-Cas9, and their effects were validated through in vitro and in vivo experiments using Western blotting, immunofluorescence, and flow cytometric analysis, confirming that these EVs activate the macrophage αvβ3-Src-FAK-STAT3 signaling pathway, thereby promoting efferocytosis.
Results
In this study, we found that CRC-derived EVs (CRC-EVs) enhanced macrophage efferocytosis of cisplatin-induced apoptotic CRC cells. Analysis of The Cancer Genome Atlas (TCGA) database revealed a high expression of the efferocytosis-associated gene MFGE8 in CRC patients, suggesting a poorer prognosis. Additionally, mass spectrometry-based proteomic analysis identified a high abundance of MFGE8 protein in CRC-EVs. Utilizing CRISPR-Cas9 gene edition system, we generated MFGE8-knockout CRC cells, demonstrating that their EVs fail to upregulate macrophage efferocytosis in vitro and in vivo. Furthermore, we demonstrated that MFGE8 in CRC-EVs stimulated macrophage efferocytosis by increasing the expression of αvβ3 on the cell surface, thereby activating the intracellular Src-FAK-STAT3 signaling pathway.
Conclusions
Therefore, this study highlighted a mechanism in CRC-EVs carrying MFGE8 activated the macrophage efferocytosis. This activation promoted the clearance of cisplatin-induced apoptotic CRC cells, contributing to CRC resistance against cisplatin. These findings provide novel insights into the potential synergistic application of chemotherapy drugs, EVs inhibitors, and efferocytosis antagonists for CRC treatment.
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Background
According to recent cancer statistics, colorectal cancer (CRC) is the third most prevalent and second most lethal cancer in the world [1]. Despite the advancements in surgical procedures and the widespread use of adjuvant chemotherapy, the 5-year survival rate of CRC patients stands at 65% on average [2]. However, the outlook remains grim for patients with distant metastases or inoperable tumors, who have a 5-year survival rate of just 15% [2]. Cisplatin is a chemotherapy drug used to treat various types of cancer, such as bladder, ovarian, and testicular cancers [3]. However, its therapeutic efficacy in CRC is not pronounced, as many CRC patients exhibit the resistance to cisplatin. Therefore, the combination of cisplatin with other drugs proves effective in the treatment of CRC. For example, the combined application of curcumin with cisplatin effectively inhibits CRC through MicroRNA-137-Glutaminase axis [4]; Arctigenin increased the sensitivity of CRC resistant to cisplatin through the activation of autophagy [5]; And metformin up-regulated the sensitivity of CRC to cisplatin by activating PI3K/Akt pathway [6]. However, it remains unknown how CRC regulates macrophage clearance of cisplatin-induced apoptotic cells within the tumor microenvironment, consequently promoting its progression.
Extracellular vesicles (EVs), which act as intercellular mediators between tumor and immune cells, are a type of nanoparticle with bilayer lipid membranes [7, 8]. These vesicles are classified into exosomes (50–150 nm), microvesicles (200–800 nm), and large EVs (≥ 1000 nm, such as apoptotic bodies) based on their diameter differences [9]. EVs contain a rich mixture of molecular components, including miRNAs, lncRNAs, proteins, and lipids [10]. Once EVs are taken up by target cells, these biologically active substances can trigger the activation of related signaling pathways [11]. Thus, EVs play a crucial role in intercellular communication. In the tumor microenvironment (TME), tumor-derived EVs (TDEVs) can induce changes in macrophages, such as M2 polarization, increased PD-L1 expression, and the release of inflammatory factors [12,13,14]. On the other hand, EVs derived from tumor-associated macrophages (TAMs) can enhance tumor cell metastasis, resistance to chemotherapy, and angiogenesis [15,16,17]. Overall, the biological effects of EVs between tumor cells and macrophages are mainly immunosuppressive and tumor-promoting.
It has been established that TAMs play an important role in the process of efferocytosis, which is the removal of apoptotic tumor cells. When chemotherapy, radiotherapy, or targeted therapy causes tumor cells to undergo apoptosis, a large number of chemokines are released, which attract macrophages to the site. Meanwhile, apoptotic tumor cells display “eat-me” signals such as phosphatidylserine and calreticulin, which are recognized by receptors in macrophages responsible for efferocytosis, such as milk fat globule-epidermal growth factor-factor 8 (MFGE8), MerTK, Axl, and Tyro3 [18,19,20,21]. The interaction between these ligands and receptors leads to the engulfment of the apoptotic cells. Efferocytosis helps to reduce the release of chemotactic factors, establish a tumor-tolerant immunosuppressive environment, and prevent secondary necrosis [22]. Previous studies have shown that efferocytosis is associated with resistance to chemotherapy and affects clinical outcomes in multiple cancers [23,24,25,26]. However, the impact of TDEVs on the regulation of macrophage efferocytosis remains unclear.
In this study, we demonstrated that EVs derived from colorectal cancer (CRC-EVs) have the ability to enhance the efferocytosis of apoptotic tumor cells by macrophages. Our findings showed that MFGE8, a component present in the CRC-EVs, was responsible for enhancing macrophage efferocytosis. MFGE8 is a glycoprotein known for its role in regulating immune tolerance, particularly through promoting the phagocytosis of apoptotic cells [27]. Its structure is comprised of a mucin-like domain, two repetitive discoidin-like structural domains (C domains), and two repetitive EGF-like structural domains. A specific integrin-binding motif in the EGF-like domain binds to MFGE8, enabling integrin-mediated signaling and enhancing cell adhesion of αvβ3 and αvβ5 integrin heterodimers [28]. MFGE8 binds phosphatidylserine present on apoptotic cells to the αvβ3 integrins on phagocytes, thus enhancing the clearance of these cells [29]. Besides efferocytosis, MFGE8 can also promote angiogenesis and intestinal mucosal repair [30, 31]. Previous studies indicated that high levels of MFGE8 have been linked to poor prognosis and overexpression of MFGE8 has been shown to drive CRC progression [32, 33]. Our findings revealed that MFGE8 in the CRC-EVs increased macrophage efferocytosis of cisplatin-induced apoptotic tumor cells through the αvβ3-Src-FAK-STAT3 signaling pathway. This study sheds light on a novel mechanism wherein CRC-EVs participate in macrophage efferocytosis, contributing to cisplatin-induced CRC apoptosis.
Methods
Cell lines and cell culture
CT26 mouse colorectal cancer cells were obtained from Procell Life & Technology Co., Ltd., while MC38 mouse colorectal cancer cells were sourced from the Chinese Academy of Sciences. The cells were cultured in a 5% CO2 incubator at 37 °C, in DMEM (Biochannel, BC-M-005) supplemented with 10% fetal bovine serum (Biochannel, BC-SE-FBS01) and 1% penicillin/streptomycin (Biosharp, BL505A).
Bone marrow-derived macrophage culture
The isolation and cultivation of bone marrow-derived macrophages (BMDMs) followed a previously described method [34]. Briefly, C57BL/6 mice (8–12 weeks) were euthanized, and the thigh muscle was removed to access the bone marrow in the femur and tibia, which was then flushed with DMEM. After centrifugation, the supernatant was discarded and the cells were lysed using red blood cell lysis buffer. The remaining cells were re-suspended in DMEM containing 10% FBS, 1% penicillin/streptomycin, and 20 ng/ml M-CSF (Sino Biological, 51,112-MNAH) and seeded in 12-well plates at a concentration of 0.3 × 106/ml (1 ml per well). After 3 days, a half volume of MCSF medium was added, and the BMDMs were fully differentiated and ready for use by day 7. The animal procedures were approved by the Institutional Animal Care and Use Committees of Sun Yat-sen University.
Construction of apoptotic tumor cells
In the study, cisplatin (Med Chem Express, HY-17,394) was used to trigger apoptosis in CT26 and MC38 cells. After the tumor cells reached 60-70% confluence, they were exposed to 0–45 µM cisplatin for a period of 48 h. To confirm the presence of apoptosis, the tumor cells were then stained using the FITC-Annexin V/APC-PI Apoptosis Detection Kit (YEASEN, 40302ES60). Once the apoptosis rate reached more than 80%, the cells were deemed suitable for use in experiments. Therefore, a routine dose of 45 µM cisplatin was used for 48 h to induce apoptosis in the tumor cells.
To facilitate experimental observation, we constructed CT26 and MC38 cells stably expressing green fluorescent protein (GFP-CT26 and GFP-MC38). Briefly, the cells were infected with GFP-containing lentiviruses, and after 48 h, a single-cell clone was selected based on fluorescence microscopy and amplified in culture. The morphology and growth of the GFP cells were found to be identical to those of the wild-type cells, so the same amount of cisplatin was used to construct apoptotic GFP cells for further analysis.
Extracellular vesicle isolation and characterization
The isolation of EVs from CT26 and MC38 cells was performed using multi-step ultracentrifugation [35]. The procedure involved growing the cells to 60–70% confluency, replacing the medium with serum-free DMEM for 24 h, and collecting the culture medium. The medium was then centrifuged at 3000 × g for 15 min at 4 °C to remove cellular debris, followed by another centrifugation at 10,000 × g for 30 min to remove larger microvesicles and apoptotic bodies. The supernatant was then subjected to ultra-centrifugation at 100,000 × g for 3 h at 4 °C to obtain the EV pellets. The EV pellets were resuspended in PBS and used for further analysis. The EV identity was confirmed through various methods including electron microscopy, western blot, and nano-flow cytometry. Electron microscopy was used to observe the morphology of the EVs, while western blot was used to detect EV marker proteins such as CD9, CD81, and TSG101. Nano-flow cytometry was used to measure the size and concentration of the EVs. The quantity of EVs was also measured using the BCA Protein Assay Kit (Solarbio, PC0020).
Western blot
The cells underwent lysis using RIPA buffer (25 mM Tris-Cl, pH 7.4, 150 mM NaCl, 1 mM EDTA, 5% glycerol, 1% NP-40) supplemented with protease inhibitor cocktail and PMSF. Protein concentrations were determined using a BCA protein assay kit. Equal amounts of protein from each sample were loaded onto a 10% SDS-PAGE gel and separated. The proteins were then transferred from the gel to a PVDF membrane using electrotransfer in a transfer buffer (25 mM Tris, 192 mM glycine, 20% methanol). After blocking with 5% nonfat milk for 1 h at room temperature, the membrane was incubated overnight at 4 °C with primary antibodies targeting CD9 (Santa Cruz Biotechnology, sc-13,118), CD63 (Santa Cruz Biotechnology, sc-5275), TSG101 (Santa Cruz Biotechnology, sc-7964), Mitofilin (Proteintech, 10179-1-AP), MFGE8 (Santa Cruz Biotechnology, sc-271,574), p-Src (Cell Signaling Technology, 6943 S), t-Src (Cell Signaling Technology, 2109 S), p-FAK (Cell Signaling Technology, 3283 S), t-FAK (Cell Signaling Technology, 3285 S), p-STAT3 (Cell Signaling Technology, 9145), t-STAT3 (Cell Signaling Technology, 9139), and GAPDH (Abbkine, ABL1025). Following washing in TBST (TBS with 0.1% Tween-20), the membrane was incubated with appropriate HRP-conjugated secondary antibodies for 1 h. Protein bands were visualized using a ChemiDoc Imaging System from Bio-Rad and quantified using ImageJ version 1.50i. All uncropped Western Blot images can be found in the supplementary file “Uncropped Western Blot”.
Mass spectrometry-based proteomic analysis
The CT26-EVs samples were extracted through the multi-step ultracentrifugation method. These samples were then processed for label-free mass spectrometry analysis using the EasyPep™ MS Sample Prep Kits (ThermoFisher Scientific, A40006). The steps involved in the preparation of the samples included dilution of the EV samples in Lysis Solution, determination of protein concentration using the BCA kit, addition of Reduction Solution and Alkylation Solution to the samples, incubation of the samples at 95 °C for 10 min to reduce and alkalize the protein, addition of reconstituted enzyme solution to digest the protein, and a “clean-up peptides” procedure. The resulting samples were sent for LC-MS/MS-based label-free quantitation detection (Agilent 6460 Triple Quadrupole LC/MS), and three biological replicates were performed. The proteins were identified by searching the human UniProt database using MaxQuant software, and the Label-Free Quantitation (LFQ) algorithm was used for quantitative analysis.
Flow cytometry
Flow cytometry was performed to assess efferocytosis, as described in previous studies [36]. The procedure involved the pre-incubation of BMDMs with 10 µg/ml CT26-EVs or MC38-EVs for 24 h, while the control group was treated with PBS. Then, both the control and EVs-treated BMDMs were incubated with apoptotic tumor cells in a 1:3 ratio for 4 h. After being washed with PBS, the cells were collected and stained with APC-F4/80 antibody (Multi Sciences, AM048005) for 30 min to label the BMDMs. The APC and GFP double-positive BMDMs were then analyzed using flow cytometry. The percentage of GFP-positive cells within the APC-positive population was calculated using FlowJo v10.6.2 software.
Confocal immunofluorescence
The BMDMs were cultured in 12-well glass-bottomed dishes for 7 days. Prior to the efferocytosis assay, the BMDMs were pre-incubated for 24 h with 10 µg/ml of either CT26-EVs or MC38-EVs, while the control group was given PBS. Afterwards, the control and EVs-treated BMDMs were incubated with apoptotic tumor cells in a 1:3 ratio for 4 h. The cells were then washed three times with PBS and fixed with 4% paraformaldehyde for 15 min at room temperature. The cells were permeabilized with 0.3% Triton X-100 in PBS for 15 min, followed by blocking with 3% BSA in PBS for 0.5 h at room temperature. The BMDMs were then incubated with F4/80 antibody (Santa Cruz Biotechnology, sc-377,009) overnight at 4 °C and later with APC-conjugated secondary antibody (HuaAn Biotechnology, HA1127) for 2 h at room temperature. The cells were finally mounted with a mounting medium containing DAPI (Solarbio, S2110) and imaged using confocal fluorescence microscopy. The efferocytosis rate of apoptotic tumor cells in the BMDMs was quantified using Zen Pro and ImageJ software.
To confirm the internalization of the CRC-EVs into the BMDMs, the CT26-EVs and MC38-EVs were labeled with PKH67 Green Fluorescent Cell Linker Mini Kit (fluorescence, PKH67). The EVs were stained for 20 min as per the instructions and then added to the BMDMs for 30 min. The cells were permeabilized with 0.3% Triton X-100 in PBS for 15 min, followed by blocking with 3% BSA in PBS for 0.5 h. The BMDMs were incubated with the F4/80 antibody overnight at 4 °C, followed by incubation with APC-conjugated secondary antibody for 2 h at room temperature. Finally, the cells were mounted with a mounting medium containing DAPI and imaged using confocal fluorescence microscopy.
RNA extraction and quantitative real-time PCR
To extract RNA, the treated cells were lysed with Trlquick reagent (R1100, Solarbio), and total RNA was obtained through a series of centrifugations according to the specified protocol. The concentration of the extracted RNA was determined by measuring the spectrophotometric absorption at 260/280 nm. The RNA was then reverse-transcribed into cDNA using the 5 × Evo M-MLV RT Master Mix (AG11706, Accurate Biology), with reaction conditions of 37°C for 15 minutes and 85°C for 5 seconds. The resulting cDNA was diluted in water, and 10 ng was used for each quantitative RT-PCR (qRT-PCR) analysis. The qRT-PCR was carried out using a 2x Taq Pro Universal SYBR qPCR Master Mix (Q712-02, Vazyme) under the following conditions: 95°C for 30 seconds, followed by 95°C for 10 seconds and 60°C for 30 seconds, repeated for 40 cycles. The primers used for gene amplification were: MFGE8, forward 5’- AGATGCGGGTATCAGGTGTGA-3’ and reverse 5’- GGGGCTCAGAACATCCGTG-3’; and GAPDH, forward 5’- CATCACTGCCACCCAGAAGACTG-3’ and reverse 5’- ATGCCAGTGAGCTTCCCGTTCAG-3’. The fold change was calculated using the ΔΔ threshold cycle method, normalized to the control group.
CRISPR-Cas9 RNP nucleofection for Mfge8 knockout
In this study, we employed CRISPR-Cas9 ribonucleoprotein (RNP) nucleofection to knock out Mfge8 in CT26 and MC38 cells, following a previously established protocol [37]. To achieve this, we obtained two guide RNAs (gRNAs) from the GenScript Company (Nanjing, China), which were designed to target the mouse Mfge8 gene. The sequences for the gRNAs were Mfge8-gRNA1: TGGCTCGTCTGTACCGCACAGG, and Mfge8-gRNA2: TACCCTGTTTCGTGCCACCGCGG. Prior to nucleofection, 0.5 µl of gRNA1 and 0.5 µl of gRNA2 (3.2 µg/µl) were mixed with 0.5 µl of spCas9 protein (from Integrated DNA Technologies, Iowa, USA) and allowed to form an RNP complex at room temperature for 10 min (up to 1 h). A control group was included, in which the gRNA mixture was nucleofected without the spCas9 protein.
We utilized the P3 Primary Cell 4D-Nucleofector™ X Kit (Lonza, Switzerland) to perform nucleofection as per the manufacturer’s instructions. The cells were trypsinized, washed with PBS twice, and 200,000 cells were collected and suspended in 20 µl of Nucleofector™ Solution. The cell suspension was then mixed with the RNP complex. The nucleofection was carried out using the Lonza 4D-nucleofector, and the cells were transferred to a 12-well plate containing pre-warmed culture medium. All cells were harvested 48 hours after nucleofection for further analysis, which included DNA genotyping and qPCR. The primers used for Mfge8 genotyping after the knockout were Mfge8-scr-F: 5’-GATGGTCACTGTCTCCCTGC-3’ and Mfge8-scr-R: 5’-CATGGCAGACAGCACATAACTG-3’.
In vivo study of peritoneal macrophage efferocytosis
In this study, we measured the percentage of tumor cells phagocytosed by peritoneal macrophages in mice, following intraperitoneal injection of apoptotic CT26 or MC38 cells. The method used was previously described [38]. Mice of 12 weeks old were given intraperitoneal injections of CT26-EVs or MC38-EVs at a dose of 50 µg per mouse in 200 µl of PBS for a period of 24 h. The control group received injections of PBS without EVs. Later, 2 × 106 apoptotic CT26 or MC38 cells in 1 ml PBS were intraperitoneally injected into the mice. After 4 h, the mice were humanely euthanized, and a peritoneal lavage was performed using 50 ml of sterile PBS. The isolated cells were then stained with an APC-F4/80 antibody. The final step involved analysis of the percentage of peritoneal macrophage phagocytosis of the apoptotic tumor cells by flow cytometry. All animal procedures were approved by the Institutional Animal Care and Use Committees of Sun Yat-sen University.
Statistical analysis
The statistical analysis was conducted using GraphPad Prism v.8.0. The results were presented as the mean ± standard error of mean (SEM) from a specified number of experiments. Statistical comparison was carried out using a one-way analysis of variance (ANOVA) with Tukey post-hoc test or an unpaired two-tailed Student’s t-test, and a P-value less than 0.05 was considered statistically significant.
Results
Macrophage efferocytosis of cisplatin-induced apoptotic CRC cells
We exposed the colorectal cancer (CRC) cells including CT26 and MC38 cells to cisplatin doses ranging from 0 to 45 µM for 48 h, and as seen in Fig. 1A and B, cisplatin induced apoptosis in the CT26 and MC38 cells in a dose-dependent manner. When treated with 45 µM cisplatin, the apoptosis rate was approximately 83.3% and 84.8% for the CT26 and MC38 cells, respectively. To further investigate the efferocytotic rate, we established CT26 and MC38 cell lines with stable GFP expression. By selecting GFP-positive monoclonal cells for expansion culture, over 90% of GFP-CT26 and GFP-MC38 cells displayed green fluorescence as seen in Figures S1A and S1B. Flow cytometry showed that the green fluorescence percentage of GFP-CT26 and GFP-MC38 cells was about 90% (Fig. 1C and D). We found that the growth status of GFP cells was identical to that of wild-type cells, so we treated the GFP cells with 45 µM cisplatin for 48 h to construct apoptotic tumor cells for later experiments.
Previous studies have demonstrated that macrophages can engulf apoptotic tumor cells during co-culture [36]. In this study, we added apoptotic CT26 or MC38 cells to BMDMs for 4 h and then collected the cells for F4/80 staining and flow cytometry analysis. The gating strategy for cell population analysis is shown in Supplementary Figure S2A, in which the F4/80 positive population is represented as macrophages. As seen in Fig. 1E and F, BMDMs efferocytosis of approximately 28% of apoptotic GFP-CT26 or GFP-MC38 cells after 4 h of co-culture. This model effectively showed that macrophages have the capability to perform efferocytosis on cisplatin-induced apoptotic CRC cells.
CRC-EVs promoted macrophage efferocytosis
CRC cells including CT26 and MC38 -derived extracellular vesicles (represented as CT26-EVs and MC38-EVs) were isolated from the culture medium using multi-step ultracentrifugation. Electron microscopy images showed that the CT26 and MC38 EVs had the typical “cup-sharp” shape (Fig. 2A), and their diameters were 80.33 ± 7.87 nm and 73.67 ± 6.22 nm respectively (Fig. 2A). Additionally, nano-flow cytometry showed the diameters of CT26 and MC38 EVs to be 82.94 ± 3.21 nm and 83.08 ± 2.64 nm, with concentrations of 2.87 ± 0.59 × 1010/ml and 2.48 ± 0.12 × 1010/ml respectively (Fig. 2B). Western blot analysis demonstrated that CT26 and MC38 EVs were enriched with CD9, CD81, and TSG101 (small EV positive markers), but lacked Mitofilin (a small EV negative marker) (Fig. 2C). These results suggest that the CT26 and MC38 EVs isolated using multi-step ultracentrifugation were mainly small EVs, also known as exosomes.
To observe the interaction between EVs and macrophages, we labeled the EVs with PKH67 and the macrophages with F4/80. Confocal fluorescence microscopy showed that the EVs were absorbed into the macrophages’ cytoplasm, indicating internalization (Fig. 2D). To assess the effect of CRC-EVs on macrophage efferocytosis, BMDMs were treated with 10 µg/ml of CT26-EVs for 24 h, and then co-cultured with apoptotic CT26 cells at a ratio of 1:3 for 4 h. As shown in Fig. 2E, the efferocytosis of apoptotic CT26 cells was significantly increased in the CT26-EVs treatment compared to the vehicle group. Similarly, MC38-EVs also increased the ability of BMDMs to efferocytosis of apoptotic MC38 cells (Fig. 2F). Confocal fluorescence microscopy revealed a significant increase in the number of apoptotic cells undergoing efferocytosis in the treatment groups (CT26-EVs and MC38-EVs), compared to the vehicle group where only a few apoptotic cells were observed to be undergoing efferocytosis (Fig. 2G and H). Calculating the percentage of macrophages involved in efferocytosis confirmed that both CT26-EVs and MC38-EVs significantly enhanced the macrophage efferocytosis ability (Fig. 2G and H). These results demonstrated that CRC-EVs can effectively enhance the macrophage efferocytosis of cisplatin-induced apoptotic CRC cells.
CRC-EVs carried MFGE8 to promote macrophage efferocytosis
To determine the presence of cargo proteins in CRC-EVs that promoted macrophage efferocytosis, we conducted mass spectrometry-based proteomic analysis of proteins isolated from CT26-EVs. The full list of proteins discovered in CT26-EVs can be found in the supplementary material “CT26-EVs MS Proteomic Data”. The top 30 most abundant proteins were displayed in Fig. 3A, and among them, we found that MFGE8 was the only molecule linked to efferocytosis. To verify the expression of MFGE8 in CRC-EVs, we performed a western blot analysis and found that MFGE8 was expressed not only in whole cell lysis but also in CT26-EVs and MC38-EVs (Fig. 3B and C). To further study the role of MFGE8 in CRC-EVs, we constructed MFGE8-knockout CT26 and MC38 cells (represented as CT26-MFGE8KO and MC38-MFGE8KO) using the CRISPR-Cas9 gene editing system. We then amplified the culture of monoclonal cells, which was confirmed by PCR (Fig. S3A). The mRNA and protein expression of MFGE8 were then determined using western blot and RT-qPCR, and as expected, MFGE8 was not detected in CT26-MFGE8KO and MC38-MFGE8KO cells (Fig. 3D and E, and S3B).
The EVs isolated from CT26-MFGE8KO and MC38-MFGE8KO cells were identified by nano-flow cytometry and western blot. The diameters of CT26-MFGE8KOEVs and MC38-MFGE8KOEVs were around 80 nm, and the concentrations of CT26-EVs and MC38-EVs were 3.03 ± 0.50 × 1010/ml and 3.67 ± 0.74 × 1010/ml, respectively (Fig. S3C). Both CT26-EVs and MC38-EVs were found to be enriched with CD9, CD81, and TSG101 (small EV positive markers), but not Mitofilin (a small EV negative marker), indicating that the MFGE8 knockout did not affect EV release in CT26 and MC38 cells.
To examine the impact of MFGE8-deficient EVs on macrophage efferocytosis, we exposed BMDMs to the same concentration (10 µg/ml) of CT26-EVs or CT26-MFGE8KOEVs for 24 h, followed by the addition of apoptotic CT26 cells for 4 h. The efferocytosis rate of apoptotic CT26 cells was significantly reduced in the CT26-MFGE8KOEVs treatment group compared to the CT26-EVs treatment group (Fig. 3F). The efferocytosis of apoptotic cells in the CT26-MFGE8KOEVs treatment group was also significantly lower than in the CT26-EVs treatment group, as demonstrated by immunofluorescence images (Fig. 3G). The same results were found for the efferocytosis of apoptotic MC38 cells, where MFGE8 knockout diminished MC38-EVs-mediated macrophage efferocytosis (Fig. 3H and I).
High expression of MFGE8 in CRC is associated with poor prognosis
The above data demonstrated that MFGE8 carried in CRC-EVs can participate in promoting macrophage efferocytosis of cisplatin-induced apoptotic CRC cells. Given that enhanced efferocytosis by macrophages is known to promote the progression of CRC, we sought to investigate whether the expression of MFGE8 in CRC is correlated with the clinical progression of CRC patients. Following an analysis of data from The Cancer Genome Atlas (TCGA) database (see Supplementary Materials - CRC patients MFGE8), we identified a total of 597 CRC patients, of which 473 (79.2%) had deceased, and 124 (20.8%) were alive (Fig. 4A). Among them, 275 were male (46.1%), and 322 were female (53.9%) (Fig. 4B). The best expression cutoff for FPKM (Fragments Per Kilobase of transcript per Million mapped reads) was determined to be 10.75, classifying patients with MFGE8 FPKM greater than 10.75 as high-expression CRC patients and those with MFGE8 FPKM less than 10.75 as low-expression CRC patients (Fig. 4C). The distribution of patients across different stages was represented in Fig. 4D, with the majority being in stage IIa. Survival analysis based on the relationship between MFGE8 expression and survival rates revealed that CRC patients with high expression of MFGE8 exhibited significantly lower survival rates, indicating a pronounced association with poor prognosis (Fig. 4E).
MFGE8 in CRC-EVs upregulated macrophage αvβ3 expression
The protein MFGE8 has been shown to bind to the integrin αvβ3, activating the STAT3 signaling pathway and leading to increased macrophage efferocytosis [39]. To determine if CRC-EVs modulated macrophage efferocytosis through the αvβ3, we pre-treated BMDMs with Cyclo(-RGDfK), a specific inhibitor of integrin αvβ3. The results showed that only Cyclo(-RGDfK) did not impact efferocytosis of apoptotic tumor cells by macrophages, but when combined with CT26-EVs or MC38-EVs, it reversed the efferocytosis effect induced by the CRC-EVs (including CT26-EVs and MC38-EVs) (Fig. 5A and B).
We then determined whether CRC-EVs could affect the expression of αvβ3 in macrophages. We found that CRC-EVs (including CT26-EVs and MC38-EVs) induced macrophages cell surface αvβ3 expression up-regulation (Fig. 5C and D). When knock-out of MFGE8 in CRC-EVs (including CT26-MFGE8KOEVs and MC38-MFGE8KOEVs), the expression of αvβ3 significantly down-regulation compared to CRC-EVs (Fig. 5C and D). We further utilized PKH67 labeling to trace CRC-EVs and investigated their co-localization with αvβ3. As shown in Fig. 5E and F, we found that CRC-EVs (CT26-EVs and MC38-EVs) induced an increase in the expression of αvβ3 and promoted co-localization of CRC-EVs with αvβ3 in macrophages. Furthermore, knock-out of MFGE8 in CRC-EVs (including CT26-MFGE8KOEVs and MC38-MFGE8KOEVs) led to a significant decrease in αvβ3 expression and reduced co-localization of CRC-EVs with αvβ3 in macrophages compared to wild-type CRC-EVs (Fig. 5E and F). Thus, we demonstrated that CRC-EVs have the capability to bind to αvβ3, while MFGE8-deficient CRC-EVs showed a marked decrease in their binding to αvβ3. It suggests that MFGE8 plays a role in facilitating CRC-EVs interaction with αvβ3.
MFGE8 promoted macrophage efferocytosis through activation of αvβ3-STAT3 signaling pathway
Previous studies have indicated that MFGE8 engages with macrophages by bridging integrin αvβ3 on their surface with phosphatidylserine (PS) present on apoptotic cells. This interaction leads to the phosphorylation and activation of Src and focal adhesion kinase (FAK). Activated FAK further triggers the activation of STAT3, facilitating cytoskeletal rearrangement, cell motility, and the formation of phagocytic vesicles, thereby completing the process of efferocytosis [39,40,41]. Therefore, we determined to investigate whether MFGE8 carried by CRC-EVs activates the Src-FAK-STAT3 signaling pathway through αvβ3 in macrophages. The results indicated that both CT26-EVs and MC38-EVs upregulated the phosphorylation of Src, FAK, and STAT3. Conversely, MFGE8-deficient EVs failed to induce phosphorylation of Src, FAK, and STAT3 (Fig. 6A and F). Additionally, treatment with Cyclo(-RGDfK), an inhibitor of αvβ3 integrin, effectively inhibited the phosphorylation and activation of Src, FAK, and STAT3 induced by CT26-EVs or MC38-EVs (Fig. 6A and F).
To confirm the role of STAT3 in mediating the efferocytosis effect of CRC-EVs on macrophages, we pre-treated BMDMs with Stattic, a phosphorylation inhibitor of STAT3, and found that it blocked the efferocytosis enhancement by CT26-EVs or MC38-EVs (Fig. 6G and H). To further confirm the role of STAT3 activation in promoting CRC-EVs-mediated macrophage efferocytosis, we treated MFGE8-knockout CRC-EVs (including CT26-MFGE8KOEVs and MC38-MFGE8KOEVs) with the STAT3 agonist Colivelin. As shown in Fig. 6I and J, there was a significant increase in the percentage of macrophage efferocytosis. These data suggest that MFGE8 in CRC-EVs activated the phosphorylation of STAT3 in macrophages through the αvβ3-Src-FAK signaling pathway.
MFGE8 in CRC-EVs enhanced peritoneal macrophage efferocytosis
The aforementioned in vitro experiments have provided comprehensive evidence that CRC-EVs containing MFGE8 enhance macrophage efferocytosis by activating the αvβ3-STAT3 signaling pathway. To further substantiate these findings, we conducted the in vivo animal experiments. Initially, we administered CRC-EVs (including CT26-EVs and MC38-EVs) via intraperitoneal injection to ascertain whether they could prompt activation of the macrophage αvβ3-STAT3 signaling pathway in vivo. As shown in Fig. 7A and D, we found that intraperitoneal injection of CRC-EVs led to an increase in the expression of αvβ3 (as indicated by the percentage of APC-αvβ3-positive population within FITC-F4/80-positive population analyzed through flow cytometry, Fig. 7A and B) and elevated phosphorylation levels of STAT3 (measured by the immunofluorescence intensity of p-STAT3 in F4/80 staining using confocal microscopy, Fig. 7C and D) in peritoneal macrophages of mice. Conversely, administration of CRC-MFGE8KOEVs (both CT26-MFGE8KOEVs and MC38-MFGE8KOEVs) failed to induce upregulation of αvβ3 and p-STAT3 levels. This consistent evidence suggests that in vivo, CRC-EVs containing MFGE8 activate the macrophage αvβ3-STAT3 signaling pathway (Fig. 7A and D). To further confirm the pro-efferocytosis effect of CRC-EVs in vivo, the mice were given an intraperitoneal injection of either CRC-EVs or PBS (Vehicle) for 24 h, followed by an intraperitoneal injection of apoptotic CRC cells for 4 h (Fig. 7E). We then collected peritoneal lavage cells and stained them with APC-F4/80 to identify the peritoneal macrophage population (Fig. 7E). As seen in Fig. 7F, compared to the Vehicle group, the administration of CT26-EVs significantly increased the efferocytosis of cisplatin-induced apoptotic CT26 cells by peritoneal macrophages. In addition, the efferocytosis percentage of apoptotic cells in the CT26-MFGE8KOEVs treatment group was significantly lower compared to the CT26-EVs treatment group (Fig. 7F). The same result was found in the treatment of MC38-EVs, where the peritoneal macrophage efferocytosis of cisplatin-induced apoptotic cells was enhanced, but the effect was diminished in the absence of MFGE8 in MC38-EVs (Fig. 7G). These results suggest that CRC-EVs enhance the efferocytotic ability of peritoneal macrophages in vivo and that the pro-efferocytosis effect is due to the presence of MFGE8 in CRC-EVs. These in vivo results are consistent with our in vitro findings.
Discussion
It is well known that the cytotoxic effects of chemotherapy induce apoptosis in CRC cells, leading to the release of a significant amount of pro-inflammatory factors. Macrophages play a crucial role in engulfing apoptotic cells and maintaining tissue balance [42]. These approaching macrophages recognize the chemoattractants, such as lipids, proteins, and peptides, that are released by apoptotic cells [43]. The “eat-me” signals in apoptotic cells are identified by the efferocytosis-related receptors on macrophages, enabling them to carry out their phagocytic function [43]. This leads to cytoskeletal rearrangement in phagocytes, cell mobilization, and the formation of phagosomes to complete the phagocytic process [44]. Efferocytosis is accompanied by the secretion of anti-inflammatory cytokines such as TGF-β, IL-10, and PGE2, while the production of pro-inflammatory cytokines such as IL-1β, TNF-α, and IL-12 is suppressed [19]. It is worth noting that efferocytosis promotes the polarization of macrophages towards the tumor-promoting M2 phenotype [36]. Efferocytosis-related receptors, such as MerTK and AXL, have been found to play a role in promoting tumor progression. Such as Yan et al. discovered that MerTK activation was responsible for osimertinib resistance in EGFR-mutant non-small cell lung cancer [45]. Lin et al. reported that MerTK-mediated efferocytosis promoted immune tolerance and tumor progression in osteosarcoma by enhancing M2 polarization and PD-L1 expression [25]. Zdżalik-Bielecka et al. found that the GAS6-AXL signaling pathway triggered actin remodeling that drove membrane ruffling, macropinocytosis, and cancer-cell invasion [46]. In conclusion, efferocytosis dampens chemotherapy-induced inflammatory responses, hastens injury healing, and promotes tumor progression.
In the tumor microenvironment (TME), macrophages constitute one of the most abundant immune cell types. Within solid tumors, cell death is a prevalent occurrence that escalates with cytotoxic treatments like cisplatin. The process of macrophages engulfing and clearing dead cells, known as efferocytosis, exerts an immunosuppressive influence. Conversely, the uncleared apoptotic cells can promote anti-tumor immunity [47]. As efferocytosis progresses, macrophages adopt an M2-like phenotype [48]. This transition prompts the production of immunosuppressive cytokines such as IL-4, IL-10, IL-13, and TGF-β, which recruit FOXP3 + regulatory T cells, effectively suppressing the effector functions of CD4 + and CD8 + T cells within the TME [49]. Consequently, efferocytosis contributes to immune tolerance in the TME, thus facilitating tumor progression. However, the role of macrophages in tumors may exhibit dual characteristics. Studies have shown that M1 polarization in CRC promotes the expression of galectin-3, enhancing macrophage infiltration and sensitizing immune responses against tumor cells [50]. Furthermore, M1 macrophage polarization induces the production of pro-inflammatory cytokines such as TNF, IFN, and IL-1 in the TME of CRC, recruiting cytotoxic immune cells like CD8 + T cells and natural killer cells, thereby exerting anti-tumor effects [51]. Recently, we have known that extracellular vesicles (EVs) as a crucial intercellular communicator in TME [52]. Despite macrophages primarily assuming an immunosuppressive role, EVs derived from macrophages exhibit similar anti-tumor properties to their parent cells. For instance, CRC-EVs carrying miRNA induce macrophage M2 polarization via activation of the PI3K/Akt signaling pathway [53]. Moreover, CRC-EVs induce programmed death-ligand 1 (PD-L1) expression in tumor-associated macrophages, facilitating tumor evasion [54]. Additionally, EVs from CRC stem cells promote tumor initiation by upregulating IL-1β expression to enhance neutrophil survival [55]. These findings underscore the regulatory impact of CRC-EVs on immune cells within the TEM, thereby exerting pro-tumorigenic effects.
An increasing number of studies are showing that EVs have pro-efferocytosis and anti-inflammatory effects in various diseases. For instance, Mentkowski et al. found that EVs from cardiosphere-derived cells enhanced efferocytosis and stimulated Arg1-dependent angiogenesis, making them an immunomodulatory and cardioprotective factor in cardiovascular disease [56]. Similarly, Gomez-Ferrer et al. found that EVs from HIF-overexpressed mesenchymal stem cells increased efferocytotic capacity in Crohn’s disease [57]. Zhang et al. demonstrated that exosomal miR-16 and miR-21 from bone marrow-derived mesenchymal stem cells helped alleviate systemic lupus erythematosus by promoting efferocytosis [58]. However, there is limited study focused on how tumor-derived EVs affect macrophage efferocytosis and then consequently influence tumor progression. Wolf-Dennen et al. reported that EVs from metastatic osteosarcoma decreased efferocytosis in alveolar macrophages [59]. Our previous study has shown that CRC-EVs containing HSP70 enhance macrophage phagocytosis by upregulating MARCO expression [60]. In this study, we found that EVs isolated from CRC (including CT26 and MC38) cells enhanced macrophage efferocytosis, which is different from the findings of Wolf-Dennen et al. This discrepancy might be attributed to variations in the tumor type and the conditions under which the EVs were isolated.
Efferocytosis, the process of engulfing and clearing apoptotic cells, relies on the recognition of “eat me” signals by engulfing receptors or through bridging molecules such as MFGE8 [61]. MFGE8 serves as a crucial link between apoptotic cells and phagocytes, as demonstrated in a study by Kranich et al. where MFGE8 secreted by follicular dendritic cells promoted macrophage clearance of apoptotic B cells, while MFGE8 deletion resulted in impaired clearance of apoptotic cells and accumulation of apoptotic cell debris in germinal centers [62]. Another study by Fens et al. showed that MFGE8 induced angiogenic endothelial cells in tumors to phagocytose apoptotic melanoma cells [63]. Soki et al. reported that MFGE8 from prostate cancer promoted macrophage efferocytosis and also induced an up-regulation of MFGE8 in macrophages undergoing efferocytosis [36]. Additionally, a recent study on myocardial infarction revealed that exosomal delivery of MFGE8 from mesenchymal stem cells played an opsonizing effect on apoptotic cells and enhanced the efferocytotic activity of macrophages [38]. Zhao et al. have demonstrated that poorer prognosis in colorectal cancer patients with high MFGE8 expression. Additionally, the effect of MFGE8 on colorectal cancer cell migration, invasion, and epithelial-to-mesenchymal transition was found to be partially dependent on the PI3K/AKT signaling pathway [33]. Another study by Jia et al. indicated a significant increase in MFGE8 expression in colorectal cancer compared to normal mucosa tissues, with patients exhibiting high levels of MFGE8 protein showing shortened overall survival [32]. Both clinical studies underscored the upregulation of MFGE8 expression in colorectal cancer tumor tissues, and patients with high MFGE8 expression had poorer prognoses. This is consistent with the findings of our study, which further suggests that MFGE8 carried in CRC-EVs may exacerbate the prognosis of CRC by enhancing cisplatin resistance through macrophage efferocytosis.
In our study, we conducted a mass spectrometry-based proteomic analysis of CT26-EVs and found that MFGE8 had a high abundance. This finding was confirmed by immunoblotting, which showed high expression of MFGE8 in CRC-EVs. We then used the CRISPR-Cas9 system to create MFGE8-knockout CRC (CT26 and MC38) cells, resulting in MFGE8-deficient CRC-EVs. Compared to wild-type CRC-EVs, the MFGE8-deficient CRC-EVs did not effectively activate BMDMs to efferocytosis of apoptotic tumor cells, a result that was replicated in vivo. MFGE8 knockout significantly reduced CRC-EVs-mediated efferocytosis in peritoneal macrophages. To understand the molecular mechanism behind CRC-EVs regulation of macrophage efferocytosis, we focused on the αvβ3-STAT3 signaling pathway. Ren et al. reported that the αvβ3-FAK-STAT3 pathway was responsible for activating efferocytosis in acute pancreatitis [39]. In our study, we found that MFGE8 carried within CRC-EVs up-regulated the expression of cell surface αvβ3 on macrophages. Subsequent blockade of the αvβ3 receptor on macrophages using Cyclo(-RGDfK) effectively inhibited CRC-EVs-induced phosphorylation of Src, FAK, and STAT3 in macrophages. This inhibition further prevented CRC-EVs-induced efferocytosis in macrophages. The application of Stattic, a specific inhibitor of STAT3 phosphorylation, also hindered the promotion of macrophage efferocytosis by CRC-EVs, indicating that phosphorylated STAT3 mediates this efferocytic process. In addition, CRC-EVs lacking MFGE8 failed to activate the αvβ3-Src-FAK-STAT3 signaling pathway in macrophages. However, treatment with Colivelin, a STAT3 activator, restored the efferocytic function of macrophages, highlighting the pivotal role of phosphorylated STAT3 in mediating efferocytosis.
It is widely recognized that cisplatin, a type of chemotherapy drug, can cause tumor cell death through DNA damage [64]. Cisplatin also has anti-tumor immune effects, such as increasing the expression of MHC Class I molecules, reducing Treg lymphocytes, and attracting immune cells [64]. Although cisplatin has proven successful in treating various tumor entities, CRC has been shown to be unresponsive to cisplatin, limiting the success of treatment [65]. Resistance to cisplatin is frequently observed in tumor cells, and this resistance may be intrinsic to certain tumors, such as pancreatic and colorectal cancer, or it may develop during the course of treatment, as seen in ovarian cancer [65]. The presence of cisplatin resistance poses a significant challenge in achieving therapeutic success in CRC. Understanding the mechanisms underlying this resistance is crucial for developing strategies to overcome or circumvent it, thereby improving the efficacy of cisplatin-based treatments in CRC. In this study, we elucidated a novel molecular mechanism of cisplatin resistance in CRC. This mechanism involves non-apoptotic CRC cells delivering MFGE8 through EVs to macrophages. Subsequently, this process activates macrophage efferocytosis, leading to the clearance of apoptotic tumor cells induced by cisplatin. Therefore, this study has revealed a novel mechanism by which CRC exhibits resistance to cisplatin treatment through the secretion of EVs.
Conclusions
In conclusion, our study highlights the pro-efferocytosis role of MFGE8 in CRC-EVs and demonstrates that MFGE8 facilitates macrophage efferocytosis through the αvβ3-Src-FAK-STAT3 signaling pathway (Fig. 8). This provides new insight into the regulation of macrophage function during cisplatin chemotherapy by CRC-EVs. The combination of chemotherapy and efferocytotic inhibition may be a promising approach for CRC treatment.
Data availability
The data that support the findings of this study are available from the corresponding author upon reasonable request.
Abbreviations
- CRC:
-
Colorectal cancer
- EVs:
-
Extracellular vesicles
- TME:
-
Tumor microenvironment
- TAMs:
-
Tumor-associated macrophages
- BMDMs:
-
Bone marrow-derived macrophages
- MFGE8:
-
Milk fat globule-epidermal growth factor-factor 8
- GFP:
-
Green fluorescent protein
- CRC-EVs:
-
Colorectal cancer-derived EVs
- CT26-EVs:
-
CT26 cells-derived EVs
- CT26-MFGE8KOEVs:
-
EVs derived from MFGE8-knockout CT26 cells
- GFP-CT26:
-
CT26 cells stably expressing green fluorescent protein
- MC38-EVs:
-
MC38 cells-derived EVs
- MC38-MFGE8KOEVs:
-
EVs derived from MFGE8-knockout MC38 cells
- GFP-MC38:
-
MC38 cells stably expressing green fluorescent protein
- FAK:
-
Focal adhesion kinase
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Acknowledgements
We would like to acknowledge the technical support from Biochemistry Core in Shenzhen Bay Laboratory.
Funding
This work was supported by the Shenzhen Science and Technology Innovation Program (JCYJ20230807110316034 and JCYJ20210324134612035 to Z.L.); National Natural Science Foundation of China (32200638 to Z.L.); Basic and Applied Basic Research Fund of Guangdong Province (2023A1515010090 and 2021A1515110512 to Z.L.); Research Start-up Fund of the Seventh Affiliated Hospital, Sun Yat-sen University (ZSQYBRJH0021 to Z.L.).
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Z.L. planned the project and conceived the experiments. Z.M., Y.S., W.X., Y.Y., and X.X. performed the experimental works and analyzed the data. Z.M., Y.S., Z.X., T.Z., and Z.L. conceived the data and wrote the manuscript. All authors approved the final version of the manuscript.
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Ma, Z., Sun, Y., Yu, Y. et al. Extracellular vesicles containing MFGE8 from colorectal cancer facilitate macrophage efferocytosis. Cell Commun Signal 22, 295 (2024). https://doi.org/10.1186/s12964-024-01669-9
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DOI: https://doi.org/10.1186/s12964-024-01669-9