ICG-001

Enhancement of E-cadherin expression and processing and driving of cancer cell metastasis by ARID1A deficiency

Jie Wang 1,6, Hai-Bo Yan1,6, Qian Zhang1, Wei-Yan Liu1, Ying-Hua Jiang1, Gang Peng2, Fei-Zhen Wu3, Xin Liu4, Peng-Yuan Yang 1,3,5 ✉ and Feng Liu 1,3 ✉
© The Author(s), under exclusive licence to Springer Nature Limited 2021

1Minhang Hospital, Fudan University, and Shanghai Key Laboratory of Medical Epigenetics, International Co-laboratory of Medical Epigenetics and Metabolism (Ministry of Science and Technology), Institutes of Biomedical of Sciences, Fudan University, Shanghai, China. 2Institutes of Brain Science, Fudan University, Shanghai, China. 3Department of Systems Biology for Medicine, School of Basic Medical Sciences, Fudan University, Shanghai, China. 4Department of Central Laboratory Medicine, Shanghai Municipal Hospital of
Traditional Chinese Medicine, Shanghai University of Traditional Chinese Medicine, Shanghai, China. 5Department of Chemistry, Fudan University, Shanghai, China. 6These authors contributed equally: Jie Wang, Hai-Bo Yan. ✉email: [email protected]; [email protected]
Received: 29 May 2020 Revised: 4 June 2021 Accepted: 28 June 2021

Abstract

The ARID1A gene, which encodes a subunit of the SWI/SNF chromatin remodeling complex, has been found to be frequently mutated in many human cancer types. However, the function and mechanism of ARID1A in cancer metastasis are still unclear. Here, we show that knockdown of ARID1A increases the ability of breast cancer cells to proliferate, migrate, invade, and metastasize in vivo. The ARID1A-related SWI/SNF complex binds to the second exon of CDH1 and negatively modulates the expression of E- cadherin/CDH1 by recruiting the transcriptional repressor ZEB2 to the CDH1 promoter and excluding the presence of RNA polymerase II. The silencing of CDH1 attenuated the migration, invasion, and metastasis of breast cancer cells in which ARID1A was silenced. ARID1A depletion increased the intracellular enzymatic processing of E-cadherin and the production of C-terminal fragment 2 (CTF2) of E-cadherin, which stabilized β-catenin by competing for binding to the phosphorylation and degradation complex of β-catenin. The matrix metalloproteinase inhibitor GM6001 inhibited the production of CTF2. In zebrafish and nude mice, ARID1A silencing or CTF2 overexpression activated β-catenin signaling and promoted migration/invasion and metastasis of cancer cells in vivo. The inhibitors GM6001, BB94, and ICG-001 suppressed the migration and invasion of cancer cells with ARID1A- deficiency. Our findings provide novel insights into the mechanism of ARID1A metastasis and offer a scientific basis for targeted therapy of ARID1A-deficient cancer cells.

INTRODUCTION

The AT-rich interactive domain-containing protein 1 A (ARID1A) encodes BRG1-associated factor 250a (BAF250a), a non-catalytic subunit of the SWItch/Sucrose Non-Fermentable (SWI/SNF) chromatin-remodeling complex [1]. The SWI/SNF complex plays an important role in many cellular processes, and defects in its components are related to various abnormalities including tumorigenesis [2]. The abnormality of ARID1A has beenconfirmed to be associated with human diseases, such as degenerative diseases [3], tissue regeneration [4], and congenital disorders [5]. ARID1A has been found to be frequently mutated in a variety of human cancers, particularly in ovarian clear cell carcinoma (OCCC) [6] and endometrioid carcinoma [7, 8]. Many ARID1A mutations are insertions and deletions, truncations and missense mutations, which may deactivate ARID1A. The mole- cular mechanisms of ARID1A in oncogenic transformation, cell proliferation, and angiogenesis have been studied in several cancer types. ARID1A and PIK3CA synergistically mutate and promote tumor growth [9]. ARID1A deficiency sensitizes tumor cells to synthetic lethal therapies using an inhibitor of ataxia–telangiectasia and RAD3-related protein (ATR) (a DNA damage checkpoint kinase) [10], or PARP inhibitors [11]. Loss of ARID1A activates annexin A1, which is required for drug resistance [12]. ARID1A deficiency increases angiopoietin-2- dependent angiogenesis and promotes hepatocellular carci- noma [13]. ARID1A and ARID1B are mutually exclusive, with ARID1B being specific to the vulnerability in ARID1A-mutant cancers [14]. Despite all these findings, the functional and molecular mechanisms of ARID1A deficiency in cell migration, invasion, and cancer metastasis have not been well characterized.
ARID1A is mutated in 3% to 17% of breast cancer (BC) [15–18], with a reduction of ARID1A in 40% to 70% of BC [19, 20]. E- cadherin (E-cad) is an intercellular adhesion molecule, typically a tumor suppressor in certain types of cancer [21]. Previously, we found that ARID1A deficiency downregulated E-cad in gastric cancer (GC) cells and induced an enhanced metastatic phenotype in GC cells [22]. In the current study, we found that ARID1A regulates E-cad in BC cells in a negative manner. ARID1A depletion can increase E-cad/CDH1 expression and protein processing, which leads to enhanced migration, invasion, and metastasis of BC cells. Our findings provide novel insights into the function of ARID1A as an epigenetic factor and the versatile roles of E-cad in BC metastasis.

RESULTS

Promotion of cancer cell proliferation, migration, invasion, and in vivo metastasis by loss of ARID1A
Silencing ARID1A with small interfering RNA (siRNA) enhanced the growth and colony formation of cervical cancer cells HeLa and highly metastatic triple-negative BC (TNBC) cells MDA-MB-231 or BC cells T47D and MCF7, while ectopic expression of ARID1A suppressed cell proliferation and colony formation (Fig. S1A–E). In the xenograft mouse model, ARID1A silencing by short hairpin RNA (shRNA) increased cancer cell growth (Fig. S1F, S1G). ARID1A silencing promoted the Transwell migration of untransformed mammary epithelial cells MCF10A and HMEC and MDA-MB-231
Fig. 1 Loss of ARID1A promotes tumor cell migration, invasion, and metastasis. A Transwell migration analysis of cells with mock or sh- ARID1A transfection. Triple independent experiments. The middle panel shows the representative image of the Transwell cells. MDA-MB-231 and MCF10A cells stably silenced ARID1A were seeded into a Transwell plate for migration assay. After 24 h, the cells migrated to the opposite side of the membrane were stained and the absorbance at OD570 was measured. B Transwell migration and invasion analyses for ARID1A overexpression. MDA-MB-231 cells were transfected with pMCB3 or pMCB3-ARID1A and incubated for 24 h. The cells were then seeded into Transwell plate for migration assay. After 24 (migration) or 48 h (invasion), the cells migrated to the opposite side of the membrane were stained and the absorbance at OD570 was measured. C Wound healing assay for ARID1A silencing using shRNAs. HMEC cells stably silenced
ARID1A were seeded into a 6-well plate and incubated for 36 h. Scratching was performed when cells reached 80–90% confluence, and the culture medium was changed with serum-free medium. Wound closure was measured with time. The yellow curve lines illustrated cell-free regions. D Wound healing assay for ARID1A overexpression. MDA-MB-231 cells were transfected with pMCB3 or pMCB3-ARID1A and incubated for 24 h. Cells were seeded into a 6-well plate and incubated for 24 h. Wound closure experiment was performed as described above. The yellow curve lines illustrated cell-free regions. E, F Zebrafish metastasis analysis of the cells with ARID1A silencing. The white arrowheads indicate the distantly dispersed HMEC cells to the tail of the fish. The statistic was shown below the images. G Lung metastasis of MDA-MB-231 cells with (n = 12) or without (n = 12) ARID1A overexpression was analyzed using a mouse model by tail vein inoculation. The animal lungs were sliced and stained with hematoxylin-eosin. The numbers indicate the animal individuals. The proportion of the tumor region to the whole lung tissue was calculated using Image Pro Plus. IHC analyses of ARID1A, E-cad, and β-catenin of the lung metastasis tissue was displayed in Fig. S4D. All the statistical data are means ± SD using unpaired Student’s t test except where indicated specifically.
(Fig. 1A, Fig. S2A). ARID1A overexpression reduced the migration and invasion of MDA-MB-231 cells (Fig. 1B). ARID1A silencing accelerated gap closure (Fig. 1C, Fig. S2B), while ARID1A over- expression decreased gap closure (Fig. 1D). ARID1A silencing will increase cell proliferation, while proliferation might contribute to increased migration and/or invasion, especially at the late stage of the migration/invasion assay. To address this possibility, we performed a time-course growth assay with an 8-hour interval. We found that cell growth would remain quiescent at the first 72 h after transfection, whether it was silencing or overexpression (Fig. S2C). For silencing experiment, the proliferation of cells with si- ARID1A was significantly different from that of si-NC at 96 h post transfection, indicating that proliferation might affect migration/invasion results. While this effect would be attenuated by the re- seeding step before Transwell analysis, since re-seeding would use equal number of cells. Furthermore, after re-seeding, cells in Transwell would be in a growth quiescent status, the proliferation of different cells might have no difference. Moreover, the migration/invasion assay would be finished shortly after re- seeding (48 h). Upon treatment with mitomycin C (MMC), a proliferation inhibitor, cells with ARID1A silencing still showed enhanced migration and invasiveness compared to siNC (Fig. S2D–F), suggesting that the observed phenotypes may not be induced by proliferation. The zebrafish metastasis model has been used to analyze BC metastasis [23]. Compared to wild-type ARID1A (n = 47) (pLKO.1), ARID1A depletion (n = 52) resulted in more far- reaching dispersal (Fig. 1E, F, Fig. S2G). In the intravenously injected metastatic mouse model, ARID1A-depleted HeLa cells yielded more and larger metastatic tumor nodes in the lungs compared to ARID1A wild-type cells (Fig. S1H, S1I). ARID1A overexpression significantly reduced lung metastasis in athymic nude mice (n = 12) compared to wild-type ARID1A (n = 12) (Fig. 1G). Thus, ARID1A is a metastasis suppressor for BC cells.
ARID1A silencing stimulated PI3K signaling and C-MYC expres- sion, whereas ARID1A overexpression suppressed PI3K/AKT signaling and upregulated the cell cycle inhibitor p21, which is a transcriptional target of ARID1A/TP53 (Fig. 2A, B). These results may explain that ARID1A can modulate breast cancer cell proliferation just like that in other cancers [8, 24, 25].

Negative regulation of CDH1 expression by ARID1A
We performed gene expression microarray analysis and data mining of public RNA-seq data to examine the global gene expression changes induced by ARID1A silencing in HMEC and MCF10A cells. We identified 17 upregulated (≥2-fold change) and 13 downregulated (≤0.5-fold change) genes in both cell lines (Fig. S3A). Among the top five upregulated genes, the long non-coding RNA gene UCA1 ranked first and has been revealed to be a transcriptional target of ARID1A and promotes proliferation and migration of BC cells [26]. Interestingly, CDH1 (encoding E-cad) was the fourth upregulated gene. The interaction network analysis of these 30 genes using String indicates that CDH1 is the central node of the interaction network (Fig. S3B), which highlights an important role of CDH1 in cell migration and invasion under
ARID1A silencing. The gene microarray and RNA-seq results were verified and it was revealed that ARID1A depletion using shRNAs upregulated E-cad expression (Fig. 2A, Figs. S3C and S4A). ARID1A overexpression using different vectors consistently inhibited E-cad expression in all three cell lines (Fig. 2B, Fig. S4B). CDH1 mRNA or protein expression was increased by ARID1A knockdown (Fig. 2C), but decreased by ARID1A overexpression (Fig. 2D). ARID1A silencing increased E-cad expression in mouse lung metastatic tumors (Fig. S4C), while ARID1A overexpression decreased the level of E-cad and reduced metastasis of cancer cells in the mouse model (Fig. S4D). The expression of CDH1 mRNA or protein, which is upregulated by ARID1A depletion, was reduced by ARID1A restoration (Fig. 2E, F). Therefore, ARID1A negatively regulates CDH1 transcription and expression.
To locate the CDH1 promoter in breast cells, we analyzed the histone binding of CDH1 using the UCSC Genome Browser. The binding of H3K4me3 indicates that the CDH1 promoter in MCF10A cells is located in the region from the first exon to the second exon, whereas the binding of H3K27me3 indicates that the “traditional” promoter region (−1 ~ −1 kb upstream of the transcription start site (TSS)) may be deactivated (Fig. S5A). In GC cells, the CDH1 gene contains a potential additional promoter (H3K4me3) or enhancer (H3K4me1) site upstream of the first exon (Fig. S5B). We performed chromatin immunoprecipitation sequencing (ChIP-seq) analysis and found that ARID1A binding to the second exon of CDH1 was dramatically reduced in MCF10A cells with ARID1A knockdown.
Next, we performed a ChIP-qPCR analysis using an antibody against BRG1, a core subunit of the SWI/SNF complex, and measured the binding of four genomic regions of CDH1 (Fig. 2G). In MCF10A or HMEC cells, ARID1A silencing reduced the occupancy of the SWI/SNF complex in region A2 spanning exon 2 rather than the “typical” promoter region (Fig. 2H, Fig. S6A). ChIP using the antibody against Brahma (BRM, another SWI/SNF chromatin remodeling ATPase) and ARID1A revealed a similar binding pattern of the SWI/SNF complex to the CDH1 promoter (Fig. 2I, Fig. S6B). The luciferase reporter assay indicated that exon 2 promoter activity increased in response to ARID1A silencing, while the activity of the “traditional” promoter fragment remained unchanged (Fig. 2J).
We hypothesize that, similar to ARID1A’s inhibition of HDAC6 expression [27], the binding of ARID1A to the CDH1 promoter may exclude the occupancy of RNA polymerase II (Pol II) and thus reduce CDH1 transcription. We performed ChIP-qPCR analysis of the binding of Pol II to the A1, A2, A3, and A4 sites of CDH1 promoter using an antibody against Pol II. ARID1A silencing dramatically increased the binding of Pol II to A2, but not to A1, A3, and A4 (Fig. S6C). ChIP-qPCR results indicated that binding of the BAF complex or Pol II was mutually exclusive at the A2 site of CDH1 (Fig. S6D–S6F). Therefore, an ARID1A-associated SWI/SNF complex inhibits CDH1 transcription by excluding Pol II from the binding site of the CDH1 promoter.
Guo X et al. found ARID1A and the transcriptional repressor CEBPα synergistically inhibited UCA1 transcription in BC [26]. Our String network analysis revealed that among the interactors of CDH1, ZEB2 coincided with the transcriptional repressor of CDH1 [28], while the expression of ZEB2 was downregulated by ARID1A silencing in vitro and in vivo (Figs. S3B, S3C, S6G). We anticipated
Fig. 2 ARID1A-associated SWI/SNF complex regulates CDH1 (E-cadherin) transcription in a negative fashion. A ARID1A was silenced using shRNAs and the proteins were analyzed by immunoblot. B ARID1A overexpression decreased the expressions of E-cad, β–catenin, and p- AKTS473, but increased p-β-cateninS33/S37/T41 (p-β-cat*) and p21. C qPCR analyses of ARID1A and CDH1 expression in MCF10A cells with or without ARID1A knockdown. D qPCR analyses of ARID1A and CDH1 expression in MDA-MB-231 cells with or without ARID1A overexpression. E qPCR analyses of ARID1A and CDH1 expression in MCF10A cells with ARID1A knockdown or restoration (sh2-ARID1A-R). F ARID1A silencing in MCF10A cells upregulated E-cad expression, while restoration of ARID1A (sh2-ARID1A-R) suppressed E-cad expression. G The schematic diagram of the genomic structure of CDH1 promoter and its 5′ exons, the positions of qPCR amplicons, and the construction of reporter assays. The orange line indicates the genomic sequence and the dashed line indicates the omitted intron sequence. The first, second, and third exons are indicated as E1, E2, and E3, and their start and end positions are specified. The green bent arrow indicates the TSS, while the gray arrows indicate potential alternative TSSs. The opposite arrowheads specify the qPCR amplicons and the arrowheads represent the primer directions and positions. The amplified region of each amplicon is listed below. H ChIP-qPCR analyses of the binding of ARID1A- associated SWI/SNF complex to CDH1 promoter. The ChIP was performed using an antibody against Brahma-related gene-1 (BRG1), the core catalytic subunit of the SWI/SNF complex. The position information of CDH1 locus was retrieved from public databases USCS Genome Browser and Ensembl (http://www.ensemble.com). NS non-significant. Luc luciferase gene. I ChIP-qPCR analyses of the binding of ARID1A-associated SWI/SNF complex to CDH1 promoter. The ChIP was performed using an antibody against Brahma (BRM), another core catalytic subunit of the SWI/SNF complex. J Luciferase reporter assay of the promoter or 5′ exon regions of CDH1. ARID1A was silenced with shRNA or siRNA. NS non-significant. All the statistical data are means ± SD using unpaired Student’s t test. K qPCR assay was performed for the transcribed fragments illustrated in Fig. 2G after ARID1A was stably silenced with shRNAs. n = 3 independent experiments. NS non-significant. P value was calculated using the two-sided Student’s t test. Data are means ± SD.
that ZEB2 might be involved in the inhibition of ARID1A on CDH1 expression. Overexpression of ARID1A alone increased ZEB2 but suppressed CDH1, while silencing of ZEB2 alone greatly increased CDH1, and overexpression of ARID1A and silencing of ZEB2 simultaneously attenuated the expression of CDH1 (Fig. S6H, S6I). If ARID1A directly regulates the expression of CDH1, we would expect parallel changes in the expression of ZEB2 and CDH1 as a result of ARID1A silencing. If ARID1A regulates ZEB2 and then ZEB2 regulates CDH1 transcription, we can expect the expression of ZEB2 to change prior to CDH1. To address this issue, the ARID1A was silenced using siRNA in MCF7 and HeLa cells, and the expression of ARID1A, ZEB2, and E-cadherin was measured every 8 h or 12 h. We found that the decrease of ZEB2 and the increase of E-cadherin were synchronized in HeLa cells. That is, both the decrease in E-cadherin and the increase in ZEB2 obviously started at the same time point (16th hour) (Fig. S6J). In MCF7 cells, both the decrease in ZEB2 and the increase in E-cadherin began at the 24th hour. Therefore, ARID1A regulates the expression of CDH1 and ZEB2, respectively.
To further confirm the function of exon2, we analyzed binding activity in the luciferase reporter assay using different doses of siRNA. When the concentration of si-ARID1A was increased, the transcriptional activity of exon 2 increased in a dose-dependent manner (Fig. S6K), while the activity of the “traditional” promoter segment did not change significantly. The intron segment showed less activity in response to increased ARID1A silencing. Thus, loss of the BAF complex from the second exon of CDH1 is responsible for the upregulation of CDH1.
CDH1 can alternatively be transcribed from intron 1 or 2. These variant proteins can promote cell invasion and angiogenesis [29]. To address this possibility, we designed qPCR primers that allow amplification of amplicons that span introns and exons. Mature CDH1 transcripts contain normally spliced sequences spanning exons 1 (UTR), 2 and 3 (E2-E3), but not introns 1 (I1-E2, I1-E3) and 2 (I2-E3) (Fig. 2K). This observation excludes the possibility of an alternative intron-initiated transcription of CDH1 due to loss of ARID1A.

Attenuation of migration, invasion, and metastasis of ARID1A- deficient BC cells by silencing CDH1
What is the role of CDH1 in BC cells in the context of ARID1A deficiency? Overexpression of CDH1 alone did not alter the growth of cancer cells in the growth curve assay (Fig. S7A). In HeLa, MCF7, and MDA-MB-231 cells, silencing ARID1A increased the expression of E-cad and β-catenin, while additional silencing of CDH1 attenuated the expression of β-catenin (Fig. S7B). In the wound healing assay, knocking down ARID1A alone promoted gap closure and transwell migration/invasion, while CDH1 silencing alone inhibited gap closure and transwell migration/ invasion, compared to the control (Fig. S7C–S7E). Silencing ARID1A and CDH1 simultaneously reduced gap closure and transwell migration/invasion to an average level. In the
Zebrafish metastasis model, a single silencing of ARID1A greatly increased the long-distance metastasis of tumor cells, while a single silencing of CDH1 significantly reduced the metastasis of tumor cells (Fig. S7F–S7H). Additional silencing of CDH1 attenuated ARID1A silencing-induced tumor cell metastasis. Therefore, E-cad is essential for increasing cell migration and invasion of ARID1A-deficient cancer cells.

Relationship between loss of ARID1A and increased intracellular digestion of E-cad
As a membrane-anchored protein, E-cad can be cleaved by matrix metalloproteinases (MMPs), calpain, ADAM10, γ-secretase, or caspase 3 at the membrane–cytoplasm interface or the cytoplas- mic site. Enzymatic cleavage increases the N-terminal extracellular ectodomain and C-terminal fragments (CTFs) of E-cad (Fig. 3A) [30]. The soluble 80 kDa N-terminal E-cad fragment (sE-cad), released by plasmin, MMP3 or MMP7, can stimulate cancer cell invasion [31, 32]. E-cad overexpression promotes peritoneal metastasis in colon cancer and enhances the proteolytic effect of E-cad and its CTF production [33]. Thus, we assume that ARID1A knockdown may increase its expression and simultaneous processing of E-cad, while CTFs may be associated with BC cell metastasis.
We silenced ARID1A and measured all possible proteolytic fragments of E-cad using antibodies that recognize the C- or N- terminus of E-cad. E-cad and its CTFs were increased by ARID1A silencing, suggesting that part of the nascent E-cad has been cleaved (Fig. 3B, Fig. S8A). However, sE-cad did not change in the cell lysate or culture supernatant (Fig. 3C). In ARID1A- depleted BC tissues, E-cad CTFs (including 38 kDa CTF1 and 33 kDa CTF2) were increased in cancer tissues, while sE-cad was not visible (Fig. 3D), suggesting that CTFs, rather than NTF, may play a role in BC, where ARID1A is lacking. In MDA-MD-453 and MDA-MB-231 cells, ARID1A silencing increased E-cad, CTF1 and CTF2, while ARID1A overexpression reduced E-cad and CTFs, especially CTF2 (Fig. 3E, Fig. S8B). This observation was confirmed in T47D, MDA-MB-468, HeLa, and MCF7 (Fig. S8C, S8D). To achieve reproducibility, Western blot analysis was repeated three times in MCF7 cells (Fig. S8E), and band intensity calculations indicated that ARID1A silencing significantly increased CTF1 and CTF2, which were decreased by ARID1A overexpression (Fig. S8F).
Fig. 3 Loss of ARID1A associates with increased intracellular digestion of E-cad. A Schematic diagram of E-cad protein structure and its enzymatic digestion. The numbers in the brackets indicated aa positions. TM transmembrane domain. β–catenin BD (binding domain) is from aa 815 to 839 of E-cad. The arrowheads indicated the cleavage sites of different enzymes. MMP matrix metalloproteinase, sE-cad secreted ectodomain of E-cad, CTF C-terminal fragment, the number indicates the molecular weight kDa of CTF. B ARID1A was silenced with a siRNA and immunoblots were performed using antibodies against the C- or N-terminus of E-cad. SE/ME/LE, short, medium, or long exposure. The arrowhead indicates the position of either E-cad CTF1 or CTF2. E-cad/fl the full length of E-cad. C Immunoblot analysis of the 80 kDa sE-cad after ARID1A silencing. D The expression of E-cad and its enzymatic fragments in two BC samples. Cancer, cancerous tissue. Normal, paraneoplastic normal tissue. The arrowhead indicates the position of full-length E-cad (E-cad/fl) or E-cad CTFs. E Immunoblot of the indicated proteins in cells with ARID1A overexpression. The arrowhead indicates the position of full-length E-cad (E-cad/fl) or E-cad CTFs. F Immunoblot of MMPs and γ-secretase by ARID1A silencing. G MCF10A cells with or without ARID1A silencing were treated with GM6001, a pan-inhibitor of MMPs. The arrowhead indicates the position of full-length E-cad (E-cad/fl) or E-cad CTFs.
ARID1A silencing upregulates MMP2, MMP7 (matrilysin), MMP9, and γ–secretase (Fig. 3F, Fig. S8G). The upregulation of these enzymes may be responsible for the increase in multiple E-cad fragments. Treatments with enzyme inhibitors (γ–secretase inhibitor LY411575, and MMP inhibitors GM6001 and BB94) reduced the production of CTF1 and CTF2 in ARID1A- silenced cells (Fig. 3G, Fig. S8H). Under treatment with GM6001 and BB94, CTF1 and CTF2 were cooperatively changed, indicating that CTF2 generation may follow the processing of CTF1.
Fig. 4 Loss of ARID1A and expression of E-cad/CTFs increases β–catenin and epithelial to mesenchymal transition (EMT) markers. A The full-length E-cad (E-cad/fl), CTF1 and CTF2 fused with His-tag were overexpressed. The bands of CTFs were detected using the E-cad antibody or the antibody against His-tag. B Immunoblot analysis of overexpressed full-length E-cad (FL), CTF1, CTF2, CTF3, and CTF2-Δ25 which lacks the β-catenin-binding domain of E-cad from amino acid residue 815 to 839. The arrowheads indicate the positions of these fragments. NC negative control using empty vector pcDNA3.1. The asterisks indicate the exogenous E-cad. The antibody was reactive on the C-terminus of E-cad (Clone 24E10, Cell Signaling Technology (CST)). C Immunoblot analysis of overexpressed full-length E-cad (FL), CTF1, CTF2, CTF3, and CTF2-Δ25. E-cad and its C-terminal fragment were probed using the antibodies against the C- or the N-terminus of E-cad (Clone 32A8, CST). The arrow indicates the full-length protein of E-cad. The arrowheads indicate the positions of the major products of CTFs. NC negative control using empty vector pcDNA3.1. D EMT markers were analyzed in ARID1A-silenced cells. SE short exposure, LE long exposure. E Immunoblot analyses of EMT markers in cells with E-cad or CTFs overexpression. Mr molecular (weight) ratio.
Collectively, ARID1A deficiency increases C-terminal cleavage of E-cad, which may contribute to enhanced migration and invasion of BC cells lacking ARID1A.

Upregulation of β-catenin and epithelial–mesenchymal transition (EMT) markers due to loss of ARID1A and overexpression of E-cad/CTF2
As a structural component of the membrane, β−catenin was coupled to cadherin to form integral adhesion junctions, while as a cytoplasm–nucleus shuttle protein, β−catenin was coupled to T- cell factor/lymphoid enhancer factor (TCF/LEF) transcription factors to activate canonical WNT/β−catenin signaling [34]. β−catenin was found to increase by ARID1A depletion (Fig. 2A, Fig. S4A), but reduced by ARID1A overexpression (Fig. 2B, Fig. S4B). β−catenin was elevated in ARID1A-silenced metastatic tumors (Fig. S4C), but reduced in metastatic tumors overexpressing ARID1A (Fig. S4D). CDH1 overexpression did not alter the expression of ARID1A and p-AKTS473, but increased β−catenin in a dose- dependent manner (Fig. S9A). In contrast, CDH1 knockdown did not affect p-AKT, although it significantly reduced β−catenin (Fig. S9B, S9C).
Overexpression of CTF1 or CTF2, especially CTF2, did not alter E-cad expression but increased β-catenin (Fig. 4A). We generated CTF2-Δ25, a null mutant lacking the binding motif from amino acids (aa) 815 to 839 (Fig. 3A) [35–37]. Over- expression of CTF2 or CTF3 significantly increased β–catenin (Fig. 4B). However, CTF2-Δ25 had no positive effect on stabilizing β–catenin, regardless of whether it had visible expression (293 T and HeLa cells) or not (MCF10A and HMEC) (Fig. 4B, C, Fig. S9D).
ARID1A silencing upregulated EMT markers N-cadherin and Snail2 (Fig. 4D), whereas overexpression of CTF2 or CTF3 increased Snail1 and Snail2 (Fig. 4E), suggesting that Snail2 may be a downstream target of the ARID1A-CDH1 signaling pathway in BC.
ARID1A silencing reduced nuclear ARID1A protein and induced subcellular redistribution of E-cad (detected by the antibody that recognizes the C-terminal epitope) and β-catenin (Fig. S9E, S9F). The morphology of ARID1A-silenced cells was also altered to a
Fig. 5 E-cad/CTF2 stabilizes β−catenin by competitive binding with the phosphorylation and degradation complex of β−catenin. A, B Cells with or without ARID1A silencing were treated with (cycloheximide) CHX, an inhibitor of protein biosynthesis. The stability curve was generated based on band intensities of Western blot. C E-cad was overexpressed in Hela and the cells were treated with CHX for up to 12 h. D
E-cad and β-catenin were analyzed in HMEC cells where ARID1A was stably silenced with shRNA (left). HA-tagged ubiquitin (HA-Ub) and Flag- tagged β-catenin (Flag-β-cat) were overexpressed. The cells were treated with mg132, a proteasome inhibitor. Immunoprecipitation (IP) was performed using flag antibody and Western blot was performed using the HA antibody (right). E HA-tagged ubiquitin and Flag-tagged β-catenin were overexpressed in MCF10A cells. The cells were then treated with mg132. IP was performed with flag antibody and ubiquitination of β–catenin was analyzed using HA or ubiquitin antibody. F The full-length E-cad (E-cad/fl), CTF1, and CTF2 were ectopically expressed and immunoblot was performed using the antibody against β-catenin (β-cat) or the C-terminal domain of E-cad. G Overexpressed CTF2 reduced p-β-cateninS33/S37/T41. H HA-tagged ubiquitin and Flag-tagged β–catenin were expressed in HMEC cells. The cells were further transfected with vectors expressing full-length E-cad, CTF1, and CTF2. The cells were then treated with mg132. IP was performed using flag antibody and immunoblot was performed using HA, flag and β–catenin antibodies. SE short exposure, LE long exposure. I CTF2 or CTF2-Δ25 was co-expressed with Flag-tagged β–catenin. IP was performed using the anti-flag antibody. CTF2-Δ25 is a mutated version lacking the 25-aa (815–839) binding domain for β–catenin. J, K Flag-tagged β−catenin was co-overexpressed with E-cad or E-cad/CTFs. IP was performed using Flag antibody. GSK3β, Axin1, and CK1 are the components of the destruction complex of β-catenin. L Structure model of the competitive binding of Axin1 and E-cad/CTF2 to β-catenin. The complex structure was constructed based on the Protein Data Bank (PDB) structures 1QZ7 and 1I7W. The E-cad/CTF2 (blue) occupies the groove formed by the third and fourth armadillo repeats of β-catenin (green) and may preclude the binding of the β-catenin-binding domain of Axin (Axin-CBD, magenta) in this region. The 25-aa the β-catenin-binding domain of E-cad was colored in red.
mesenchymal phenotype. Therefore, loss of ARID1A upregulates CTF2, which promotes β-catenin signaling and EMT.

Stabilization of β−catenin by CTF2 through competitive binding to the β−catenin’s phosphorylation and degradation complex
Is CTNNB1 (encoding β-catenin) a transcriptional target of ARID1A? In HeLa, MCF7 or MDA-MB-231 cells, ARID1A silencing did not alter the expression of CTNNB1 (Fig. S10A). In the luciferase reporter assay, ARID1A knockdown or overexpression did not significantly alter the transcriptional activity of the CTNNB1 promoter, suggesting that CTNNB1 is not regulated at the transcriptional level of ARID1A (Fig. S10B). ARID1A silencing increased β-catenin and decreased the N-terminal phosphorylation of β-catenin (p-β−cateninS33/S37/T41) (Fig. S8B), whereas ARID1A overexpression reduced β-catenin and upregulated p-β−cateninS33/S37/T41 (Figs. 2B and 3E). This observation suggests that ARID1A deficiency may modulate the stability of β-catenin, as N-terminal phosphorylation determines the ubiquitination and proteasome-dependent degra- dation of β-catenin.
Unsurprisingly, under treatment with cycloheximide (CHX), which is a chemical that inhibits protein synthesis, ARID1A depletion reduced the turnover rate of β−catenin (Fig. 5A, B). Overexpression of CDH1 also stabilized β−catenin (Fig. 5C). CTF2 overexpression stabilized β−catenin, while ARID1A silencing coupled with CTF2 overexpression greatly improved the stability of β−catenin (Fig. S10C–S10E). Under treatment with mg132 (a proteasome inhibitor), ARID1A depletion reduced proteasome- dependent ubiquitination of β−catenin (Fig. 5D, E). Thus, ARID1A depletion inhibits the phosphorylation and proteasome- dependent disruption of β−catenin [34, 38].
We hypothesize that CTFs may stabilize β−catenin by compet- ing with the β−catenin destruction complex. As expected, overexpression of E-cad, CTF1, or CTF2 increased β−catenin (Fig. 5F). The β−catenin destruction complex consists of glycogen synthase kinase 3β (GSK3β), CK1α, Axin1, and adenomatous polyposis coli (APC). The N-terminus of β−catenin was sequen- tially phosphorylated on CK1α and GSK3β. CTF2 overexpression reduced p-β−cateninS33/S37/T41 (Fig. 5G), suggesting that CTF2 may interfere with the binding of GSK3β to β−catenin. Consistently, compared to full-length E-cad or CTF1, overexpression of CTF2 significantly reduced the ubiquitination of β−catenin (Fig. 5H). Immunoprecipitation using a flag antibody (for Flag- tagged β−catenin) indicated that overexpression of CTF2 (but not CTF2-Δ25) significantly reduced the binding of GSK3β to β−catenin (Fig. 5I, J). CTF2 effectively inhibited the phosphorylation of β−catenin at S45 [39] (Fig. 5K). Furthermore, overexpression of CTF2, rather than E-cad, CTF1 or CTF2-Δ25, reduced the binding of Axin1 to β−catenin (Fig. 5K). In the superposition structure model, E-cad occupied the groove formed by the third and fourth armadillo repeats of β−catenin (Fig. 5L). Occupancy of E-cad in this region may exclude binding of the β−catenin-binding domain of Axin (Axin-CBD), because the binding site of the 25- aa β−catenin binding domain of E-cad is most proximal to the binding position of Axin-CBD. Therefore, ARID1A depletion upregulates CTF2, which competes with Axin1 for binding β−catenin and reduces its phosphoryla- tion, ubiquitination, and degradation.

Activation of downstream signaling of β−catenin by ARID1A deficiency and CTF2 upregulation
Previous reports have shown that CTFs of E-cad inhibit down-stream β-catenin-mediated transactivation in colon cancer cells [40, 41]. However, we found that ARID1A silencing or CTF2 overexpression can stimulate β-catenin-mediated signaling in BC. CTNNB1 knockdown did not change the expression of ARID1A or E-cad, suggesting that neither of these two proteins is a downstream target of CTNNB1 signaling (Fig. S11A). TOPFlash
TCF/LEF reporter assays revealed that ARID1A silencing signifi- cantly increased β-catenin activity (Fig. 6A, Fig. S11B). In contrast, ARID1A overexpression decreased β-catenin activity (Fig. 6B). ARID1A silencing upregulated many β−catenin pathway genes (Fig. 6C, D, Fig. S11C). However, ARID1A overexpression inhibited the expression of these genes (Fig. 6E). Silencing ARID1A alone increased the expressions of CD44 and MYC, while silencing CTNNB1 alone reduced the expressions of CD44 and MYC, and silencing both genes restored the expressions of CD44 and MYC (Fig. S11D, S11E). Overexpression of CTF1 or CTF2 upregulated the expression of BMP4, CCND1, C-MYC, LEF1, MMP7, SOX17, and SOX9 (Fig. 6G). However, CTF2-Δ25 had only traces of activity. Treatment of MCF7 cells with β-catenin signaling inhibitor (ICG-001) or CTF2 generation (GM-6001) significantly reduced the expressions of CD44 and c-MYC (Fig. S11F). Thus, ARID1A silencing stimulates β−catenin signaling through CTF2.
The C-terminus of the ARID1A protein contains a Gln-rich domain, a HIC-interacting domain and a glucocorticoid receptor (GR)-binding domain, which are important in protein–protein interactions and transcriptional regulation [1]. Previously, we generated a series of recombinant vectors expressing truncated mutants of the ARID1A protein (Fig. S11G) [24]. Overexpression of these mutants reduced the expression of β−catenin pathway genes (Fig. 6F, G), indicating that the smallest C-terminus of ARID1A retains transcriptional remodel- ing activity.
ARID1A silencing increased cell migration and invasion, while additional silencing of CTNNB1 eliminated this effect (Fig. 6H, S11H). In the zebrafish metastasis model, silencing ARID1A alone promoted cancer cell metastasis, while silencing CTNNB1 alone reduced metastasis. Silencing both genes attenuated cancer cell metastasis (Fig. S11I–S11K). Therefore, β–catenin is essential for upregulating the migration/invasion of BC cells with ARID1A deficiency.
Fig. 6 ARID1A-deficiency and upregulation of E-cad/CTF2 activate β–catenin downstream signaling. A, B TOPflash assay for ARID1A silencing or ARID1A ectopic expression. C, D qPCR analyses of WNT/β–catenin pathway genes in ARID1A-silencing cells. E qPCR analyses of β–catenin pathway genes in MCF10A cells with ARID1A overexpression. F Immunoblot analysis of the expression of different truncation mutation constructs of ARID1A using the Flag antibody. The fragments were cloned into pCMV-tag2A vector and fused with flag tag. G The full length or C-terminus of ARID1A or E-cad were overexpressed in MDA-MB-231 and Hela cells. β–catenin pathway genes were measured using qPCR. The mean qPCR expression value of each gene was normalized against the negative control (NC) and was Log2 transformed. The heat map was generated using Cluster and Treeview. H Transwell-migration assay of Hela cells with silencing of ARID1A and/or CTNNB1. Hela cells stably silenced ARID1A were transfected with siNC and si-CTNNB1 and incubated for 24 h. The cells were seeded into a Transwell plate for migration assay. After 24 (migration) or 48 h (invasion), the cells migrated to the opposite side of the membrane were stained and the absorbance at OD570 was measured. siNC negative control using a scrambled siRNA. All the statistical data are means ± SD using unpaired Student’s t test. *p < 0.05. **p < 0.01. ***p < 0.001. Thus, ARID1A depletion or E-cad/CTF2 expression stimulates β−catenin activity in BC cells. Enhanced migration, invasion, and metastasis of ARID1A- deficient cells by upregulated CTF2 In the zebrafish metastasis model, overexpression of ARID1A alone suppressed metastasis of cancer cells, while overexpression of CTF2 alone greatly enhanced metastasis, and simultaneously, overexpression of ARID1A and CTF2 attenuated metastasis of cancer cells (Fig. 7A, B). Treatment of MCF7 cells (wild-type ARID1A) with the MMP inhibitor GM6001 reduced the production of CTF1 or CTF2, and both CTF1 and CTF2 were increased by ARID1A silencing, but reduced by additional GM6001 treatment (Fig. 7C). In the zebrafish metastasis model, CTF2 overexpression increased distant metastasis compared to E-cad or CTF2-Δ25 (Fig. 7D). In the cancer metastasis model (mouse), overexpression of CTF2 (n = 9) produced significantly more lung metastases compared to control (n = 9), E-cad (n = 10), or CTF2-Δ25 (n = 10) (Fig. 7E). Therefore, CTF2 plays a crucial role in the metastasis ofARID1A-deficient cancer cells. Suppression of migration, invasion, and in vivo metastasis of ARID1A-deficient cancer cells by MMP and β-catenin inhibitors We attempted to identify enzyme inhibitors that could efficiently inhibit the migration or invasion of ARID1A-deficient BC cells. We treated cancer cells with DMSO (control), γ-secretase inhibitors RO4929097 and YO-01027, MMP inhibitors GM6001 and BB94, WNT/β-catenin inhibitors ICG-001 and Wnt-C59, and caspase inhibitors Z-DEVD-FMK and Ac-DEVD. GM6001, BB94, and ICG-001 significantly suppressed the migration and invasion of ARID1A-deficient cancer cells (Fig. S12A–D). In another independent experiment, compared to wild-type ARID1A, ICG-001 inhibited migration and invasion of ARID1A-silenced HeLa cells to a greater extent (Fig. S12E, S12F). In the zebrafish model, 20 µM GM-6001 effectively reduced cancer cell metastasis through ARID1A depletion using clustered regularly interspaced short palindromic repeats (CRISPR) technology (Fig. S12G–S12J). ICG-001 inhibited VEGF (a downstream molecule of catenin signaling) in a dose- dependent manner (Fig. S12K). ICG-001 greatly reduced the expression of cyclin D1 and VEGF in ARID1A-silenced cells (Fig. S12L). In summary, ARID1A deficiency in BC cells upregulates E-cad expression and processing, while E-cad/CTF2 stabilizes β−catenin and stimulates β−catenin signaling. The migration/invasion/metastasis of BC cells is enhanced by such ARID1A/E-cad/CTF/β−catenin signaling (Fig. S12M). DISCUSSION The function and mechanism of ARID1A in metastasis remain to be elucidated. Here, we found that silencing ARID1A promoted the proliferation, migration, invasion, and metastasis of BC cells. As an adhesion molecule and a typical metastasis suppressor, E-cad is usually mutated in cancer [42]. Previous findings have shown that ARID1A positively regulates CDH1 transcription in GC and neuroblastoma cells [22, 43]. However, in BC and other types of cancer cells, we found that ARID1A negatively regulates the expression of CDH1. This finding was supported by RNAseq data as reported by Xu G et al. [44]. Reanalysis of their data showed that ARID1A knockout increased CDH1 expression in MCF7 and MCF10A cells. Therefore, the epigenetic remodeling activity of the ARID1A-associated SWI/SNF complex may depend on the context in different cell types, even for the same target gene [45]. In different cell types, the active region of the CDH1 promoter may differ, as shown by the H3K4me3 binding. In BC and GC cells, the CDH1 promoter spans from the first exon to the second exon. In GC cells, the promoter region of CDH1 extends upstream of the TSS. Whereas in BC cells, the “traditional” promoter region is silenced, as shown by the H3K27me3 binding. In BC cells, the ARID1A-associated SWI/SNF complex inhibits CDH1 transcription by recruiting the transcriptional repressor ZEB2 to the CDH1 promoter and excluding the binding of RNA polymerase II. ARID1A silencing enhances the enzymatic processing of E-cad in BC. E-cad processing was observed in more types of cancer, including colorectal cancer [33], BC [32], and prostate cancer [36]. CTF1 and CTF2 were common in BC tissues with low ARID1A and in BC cell lines with ARID1A silencing, suggesting that they are important in ARID1A-deficient BC cells. MMPs may cleave larger fragments (>40 kDa) in the extracellular part, while smaller fragments (<40 kDa) may be generated by enzymes such as γ- secretase, calpain, and other enzymes in the cytoplasmic part of the E-cad. Although sE-cad is known to be oncogenic in other cancers [31], it may not play an essential role in the oncogenic process in BC cells with ARID1A deficiency. ARID1A silencing increases MMPs and γ-secretase, which promotes enzymatic shedding or cytoplasmic cleavage of membrane E-cad. Since MMP7 and MMP9 are downstream targets of β−catenin signaling, there may be a positive feedback loop between E-cad processing and β−catenin activation. The γ-secretase inhibitor LY411575 and the MMP inhibitors GM6001 and BB94 reduce the production of CTF1 and CTF2 in ARID1A-silenced cells. These inhibitors may be new therapeutic agents for ARID1A-deficient cancers. The function of E-cad/CTFs is to stabilize β-catenin in ARID1Areduced BC cells. Furthermore, CTF2 stimulates β−catenin signaling and enhances mobility, EMT, and metastasis in vivo. Silencing ARID1A or overexpression of full-length E-cad, CTF1, CTF2, and CTF3 increases the expression of β-catenin and decreased the phosphor- ylation of β-catenin. Unlike previous reports on colon cancer cells [46], E-cad expression had no effect on the growth of BC cells, but stabilized β-catenin in a dose-dependent manner. CTF2 and CTF3 stabilized β−catenin more effectively than E-cad and CTF1. In 293 T and HeLa cells with low endogenous E-cad, overexpression of E-cad stabilized β-catenin better than CTF1. CTF1 had less β-catenin stabilizing activity, which may be due to aberrant processing of CTF1 to generate short fragments with defective β-catenin-binding domains. CTF2 stabilized β−catenin by excluding NC ARID1A CTF2 ARID1A+CTF2 No dispersion 9 17 10 11 Tail dispersion 13 6 16 11 Total 22 23 26 22 Tail 2 1 9 3 Head 3 2 6 2 Yolk gland 2 1 8 0 All 7 4 23 5 Fig. 7 CTF2 promotes migration, invasion, and metastasis of BC cells with ARID1A-deficiency. A Zebrafish metastasis assay of MDA-MB-231 cells overexpressing ARID1A or CTF2 or both. The photos were taken at 0 or 36 h after inoculation. The yellow boxes indicate the area enlarged below. The metastatic cancer cells were indicated with white arrowheads. B The statistics of Fig. 7A show the fish counts (top) or metastatic cell counts (bottom). p value was calculated using unpaired and two-sided Student’s t test. C ARID1A was silenced in MCF7 cells and the cells were treated with the MMP inhibitor GM6001. Silencing of ARID1A significantly increased CTF1 and CTF2, while GM6001 treatment reduced the generation of CTF1 and CTF2. The arrowheads indicate the bands of CTF1 and CTF2. D Zebrafish metastasis assay of Hela cells with full-length E-cad (E-cad/fl), CTF2, or CTF2-Δ25 overexpression. The white arrowheads indicate the dispersed Hela cells. E Mouse metastasis assay of Hela cells with mock transfection (n = 9) or overexpression of full-length E-cad (n = 10), CTF2 (n = 9), and CTF2-Δ25 (n = 10). The cells were inoculated into the tail vein and the mice were executed 50 days after inoculation when the animal body weight decreased significantly. The animal lung was sliced and stained with hematoxylin-eosin. The proportion of cancer foci against the total tissue area analyzed was calculated. The area was measured using Image Pro Plus v6.0. the occupancy of GSK3β and AXIN1 on β-catenin, thereby reducing phosphorylation, ubiquitination, and degradation of β-catenin. These results highlight the important role of CTF2 in ARID1A- deficient BC cells. 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ACKNOWLEDGEMENTS
We acknowledge Yi-Yuan Ren, Jia-Hui Li, and Xiao-Qiang Chai for their helps in experiments. The work was supported by the National Natural Science Foundation of China (NSFC) (81572833, 22074020), Chinese National Key Program on Basic Research Grant (2011CB910702, 2013CB911202), and the Natural Science Foundation of Shanghai (14ZR1402100).

AUTHOR CONTRIBUTIONS
FL and PYY conceived the study. JW, HBY, QZ, XL, GP, FZW, and YHJ performed the experiments. WYL contributed to the clinical samples. FL wrote the manuscript. All authors reviewed and approved the manuscript for publication.

COMPETING INTERESTS
The authors declare no competing interests.

ADDITIONAL INFORMATION
Supplementary information The online version contains supplementary material available at https://doi.org/10.1038/s41388-021-01930-2.

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